#ifndef WUFFS_INCLUDE_GUARD #define WUFFS_INCLUDE_GUARD // Wuffs ships as a "single file C library" or "header file library" as per // https://github.com/nothings/stb/blob/master/docs/stb_howto.txt // // To use that single file as a "foo.c"-like implementation, instead of a // "foo.h"-like header, #define WUFFS_IMPLEMENTATION before #include'ing or // compiling it. // Wuffs' C code is generated automatically, not hand-written. These warnings' // costs outweigh the benefits. // // The "elif defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wimplicit-fallthrough" #pragma GCC diagnostic ignored "-Wmissing-field-initializers" #pragma GCC diagnostic ignored "-Wunreachable-code" #pragma GCC diagnostic ignored "-Wunused-function" #pragma GCC diagnostic ignored "-Wunused-parameter" #if defined(__cplusplus) #pragma GCC diagnostic ignored "-Wold-style-cast" #endif #elif defined(__clang__) #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wimplicit-fallthrough" #pragma clang diagnostic ignored "-Wmissing-field-initializers" #pragma clang diagnostic ignored "-Wunreachable-code" #pragma clang diagnostic ignored "-Wunused-function" #pragma clang diagnostic ignored "-Wunused-parameter" #if defined(__cplusplus) #pragma clang diagnostic ignored "-Wold-style-cast" #endif #endif // Copyright 2017 The Wuffs Authors. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // // SPDX-License-Identifier: Apache-2.0 OR MIT #include #include #include #include #ifdef __cplusplus #if (__cplusplus >= 201103L) || defined(_MSC_VER) #include #define WUFFS_BASE__HAVE_EQ_DELETE #define WUFFS_BASE__HAVE_UNIQUE_PTR // The "defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #elif defined(__GNUC__) || defined(__clang__) #warning "Wuffs' C++ code expects -std=c++11 or later" #endif extern "C" { #endif // ---------------- Version // WUFFS_VERSION is the major.minor.patch version, as per https://semver.org/, // as a uint64_t. The major number is the high 32 bits. The minor number is the // middle 16 bits. The patch number is the low 16 bits. The pre-release label // and build metadata are part of the string representation (such as // "1.2.3-beta+456.20181231") but not the uint64_t representation. // // WUFFS_VERSION_PRE_RELEASE_LABEL (such as "", "beta" or "rc.1") being // non-empty denotes a developer preview, not a release version, and has no // backwards or forwards compatibility guarantees. // // WUFFS_VERSION_BUILD_METADATA_XXX, if non-zero, are the number of commits and // the last commit date in the repository used to build this library. Within // each major.minor branch, the commit count should increase monotonically. // // WUFFS_VERSION was overridden by "wuffs gen -version" based on revision // 5d69840f8e7ca481551b02c7e8d4c5fb69521bb9 committed on 2024-08-12. #define WUFFS_VERSION 0x000040000 #define WUFFS_VERSION_MAJOR 0 #define WUFFS_VERSION_MINOR 4 #define WUFFS_VERSION_PATCH 0 #define WUFFS_VERSION_PRE_RELEASE_LABEL "alpha.8" #define WUFFS_VERSION_BUILD_METADATA_COMMIT_COUNT 3796 #define WUFFS_VERSION_BUILD_METADATA_COMMIT_DATE 20240812 #define WUFFS_VERSION_STRING "0.4.0-alpha.8+3796.20240812" // ---------------- Private Implementation Macros Re-definition Check // Users (those who #include the "wuffs-vM.N.c" file) should not define any // WUFFS_PRIVATE_IMPL__ETC macros, only WUFFS_CONFIG__ETC macros (and // WUFFS_IMPLEMENTATION). Mucking about with the private implementation macros // is not supported and may break when upgrading to newer Wuffs versions. #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) || \ defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) || \ defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) || \ defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) || \ defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) || \ defined(WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) || \ defined(WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) || \ defined(WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL) || \ defined(WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U16) || \ defined(WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32) || \ defined(WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64) || \ defined(WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U8) #if defined(__GNUC__) || defined(__clang__) #warning "Defining WUFFS_PRIVATE_IMPL__ETC yourself is not supported" #elif defined(_MSC_VER) #pragma message("Defining WUFFS_PRIVATE_IMPL__ETC yourself is not supported") #endif #endif // ---------------- Configuration // Define WUFFS_CONFIG__AVOID_CPU_ARCH to avoid any code tied to a specific CPU // architecture, such as SSE SIMD for the x86 CPU family. #if defined(WUFFS_CONFIG__AVOID_CPU_ARCH) // (#if-chain ref AVOID_CPU_ARCH_0) // No-op. #else // (#if-chain ref AVOID_CPU_ARCH_0) // The "defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #if defined(__GNUC__) || defined(__clang__) #define WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET(arg) __attribute__((target(arg))) #else #define WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET(arg) #endif // defined(__GNUC__) || defined(__clang__) #if defined(__GNUC__) // (#if-chain ref AVOID_CPU_ARCH_1) // To simplify Wuffs code, "cpu_arch >= arm_xxx" requires xxx but also // unaligned little-endian load/stores. #if defined(__ARM_FEATURE_UNALIGNED) && !defined(__native_client__) && \ defined(__BYTE_ORDER__) && (__BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__) // Not all gcc versions define __ARM_ACLE, even if they support crc32 // intrinsics. Look for __ARM_FEATURE_CRC32 instead. #if defined(__ARM_FEATURE_CRC32) #include #define WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32 #endif // defined(__ARM_FEATURE_CRC32) #if defined(__ARM_NEON) #include #define WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON #endif // defined(__ARM_NEON) #endif // defined(__ARM_FEATURE_UNALIGNED) etc // Similarly, "cpu_arch >= x86_sse42" requires SSE4.2 but also PCLMUL and // POPCNT. This is checked at runtime via cpuid, not at compile time. // // Likewise, "cpu_arch >= x86_avx2" also requires PCLMUL, POPCNT and SSE4.2. // // ---- // // Technically, we could use the SSE family on 32-bit x86, not just 64-bit x86. // But some intrinsics don't compile in 32-bit mode. It's not worth the hassle. // https://github.com/google/wuffs/issues/145 #if defined(__x86_64__) #if !defined(__native_client__) #include #include #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64 #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2 #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3 #endif // !defined(__native_client__) #endif // defined(__x86_64__) #elif defined(_MSC_VER) // (#if-chain ref AVOID_CPU_ARCH_1) #if defined(_M_X64) // On X86_64, Microsoft Visual C/C++ (MSVC) only supports SSE2 by default. // There are /arch:SSE2, /arch:AVX and /arch:AVX2 compiler flags (the AVX2 one // is roughly equivalent to X86_64_V3), but there is no /arch:SSE42 compiler // flag that's equivalent to X86_64_V2. // // For getting maximum performance with X86_64 MSVC and Wuffs, pass /arch:AVX2 // (and then test on the oldest hardware you intend to support). // // Absent that compiler flag, either define one of the three macros listed // below or else the X86_64 SIMD code will be disabled and you'll get a #pragma // message stating this library "performs best with /arch:AVX2". This message // is harmless and ignorable, in that the non-SIMD code is still correct and // reasonably performant, but is a reminder that when combining Wuffs and MSVC, // some compiler configuration is required for maximum performance. // // - WUFFS_CONFIG__DISABLE_MSVC_CPU_ARCH__X86_64_FAMILY // - WUFFS_CONFIG__ENABLE_MSVC_CPU_ARCH__X86_64_V2 (enables SSE4.2 and below) // - WUFFS_CONFIG__ENABLE_MSVC_CPU_ARCH__X86_64_V3 (enables AVX2 and below) // // Defining the first one (WUFFS_CONFIG__DISABLE_MSVC_CPU_ARCH__X86_64_FAMILY) // or defining none of those three (the default state) are equivalent (in that // both disable the SIMD code paths), other than that pragma message. // // When defining these WUFFS_CONFIG__ENABLE_ETC macros with MSVC, be aware that // some users report it leading to ICEs (Internal Compiler Errors), but other // users report no problems at all (and improved performance). It's unclear // exactly what combination of SIMD code and MSVC configuration lead to ICEs. // Do your own testing with your own MSVC version and configuration. // // https://github.com/google/wuffs/issues/148 // https://github.com/google/wuffs/issues/151 // https://developercommunity.visualstudio.com/t/fatal--error-C1001:-Internal-compiler-er/10703305 // // Clang (including clang-cl) and GCC don't need this WUFFS_CONFIG__ETC macro // machinery, or having the Wuffs-the-library user to fiddle with compiler // flags, because they support "__attribute__((target(arg)))". #if defined(__AVX2__) || defined(__clang__) || \ defined(WUFFS_CONFIG__ENABLE_MSVC_CPU_ARCH__X86_64_V3) #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64 #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2 #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3 #elif defined(WUFFS_CONFIG__ENABLE_MSVC_CPU_ARCH__X86_64_V2) #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64 #define WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2 #elif !defined(WUFFS_CONFIG__DISABLE_MSVC_CPU_ARCH__X86_64_FAMILY) #pragma message("Wuffs with MSVC+X64 performs best with /arch:AVX2") #endif // defined(__AVX2__) || defined(__clang__) || etc #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) #if defined(WUFFS_CONFIG__DISABLE_MSVC_CPU_ARCH__X86_64_FAMILY) #error "MSVC_CPU_ARCH simultaneously enabled and disabled" #endif #include // intrin.h isn't enough for X64 SIMD, with clang-cl, if we want to use // "__attribute__((target(arg)))" without e.g. "/arch:AVX". // // Some web pages suggest that is all you need, as it pulls in // the earlier SIMD families like SSE4.2, but that doesn't seem to work in // practice, possibly for the same reason that just doesn't work. #include // AVX, AVX2, FMA, POPCNT #include // SSE4.2 #include // AES, PCLMUL #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) #endif // defined(_M_X64) #endif // (#if-chain ref AVOID_CPU_ARCH_1) #endif // (#if-chain ref AVOID_CPU_ARCH_0) // -------- // Define WUFFS_CONFIG__STATIC_FUNCTIONS (combined with WUFFS_IMPLEMENTATION) // to make all of Wuffs' functions have static storage. // // This can help the compiler ignore or discard unused code, which can produce // faster compiles and smaller binaries. Other motivations are discussed in the // "ALLOW STATIC IMPLEMENTATION" section of // https://raw.githubusercontent.com/nothings/stb/master/docs/stb_howto.txt #if defined(WUFFS_CONFIG__STATIC_FUNCTIONS) #define WUFFS_BASE__MAYBE_STATIC static #else #define WUFFS_BASE__MAYBE_STATIC #endif // defined(WUFFS_CONFIG__STATIC_FUNCTIONS) // ---------------- CPU Architecture static inline bool // wuffs_base__cpu_arch__have_arm_crc32(void) { #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) return true; #else return false; #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) } static inline bool // wuffs_base__cpu_arch__have_arm_neon(void) { #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) return true; #else return false; #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) } static inline bool // wuffs_base__cpu_arch__have_x86_avx2(void) { #if defined(__PCLMUL__) && defined(__POPCNT__) && defined(__SSE4_2__) && \ defined(__AVX2__) return true; #else #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) // GCC defines these macros but MSVC does not. // - bit_AVX2 = (1 << 5) const unsigned int avx2_ebx7 = 0x00000020; // GCC defines these macros but MSVC does not. // - bit_PCLMUL = (1 << 1) // - bit_POPCNT = (1 << 23) // - bit_SSE4_2 = (1 << 20) const unsigned int avx2_ecx1 = 0x00900002; // clang defines __GNUC__ and clang-cl defines _MSC_VER (but not __GNUC__). #if defined(__GNUC__) unsigned int eax7 = 0; unsigned int ebx7 = 0; unsigned int ecx7 = 0; unsigned int edx7 = 0; if (__get_cpuid_count(7, 0, &eax7, &ebx7, &ecx7, &edx7) && ((ebx7 & avx2_ebx7) == avx2_ebx7)) { unsigned int eax1 = 0; unsigned int ebx1 = 0; unsigned int ecx1 = 0; unsigned int edx1 = 0; if (__get_cpuid(1, &eax1, &ebx1, &ecx1, &edx1) && ((ecx1 & avx2_ecx1) == avx2_ecx1)) { return true; } } #elif defined(_MSC_VER) // defined(__GNUC__) int x7[4]; __cpuidex(x7, 7, 0); if ((((unsigned int)(x7[1])) & avx2_ebx7) == avx2_ebx7) { int x1[4]; __cpuid(x1, 1); if ((((unsigned int)(x1[2])) & avx2_ecx1) == avx2_ecx1) { return true; } } #else #error "WUFFS_PRIVATE_IMPL__CPU_ARCH__ETC combined with an unsupported compiler" #endif // defined(__GNUC__); defined(_MSC_VER) #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) return false; #endif // defined(__PCLMUL__) && defined(__POPCNT__) && defined(__SSE4_2__) && // defined(__AVX2__) } static inline bool // wuffs_base__cpu_arch__have_x86_bmi2(void) { #if defined(__BMI2__) return true; #else #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) // GCC defines these macros but MSVC does not. // - bit_BMI2 = (1 << 8) const unsigned int bmi2_ebx7 = 0x00000100; // clang defines __GNUC__ and clang-cl defines _MSC_VER (but not __GNUC__). #if defined(__GNUC__) unsigned int eax7 = 0; unsigned int ebx7 = 0; unsigned int ecx7 = 0; unsigned int edx7 = 0; if (__get_cpuid_count(7, 0, &eax7, &ebx7, &ecx7, &edx7) && ((ebx7 & bmi2_ebx7) == bmi2_ebx7)) { return true; } #elif defined(_MSC_VER) // defined(__GNUC__) int x7[4]; __cpuidex(x7, 7, 0); if ((((unsigned int)(x7[1])) & bmi2_ebx7) == bmi2_ebx7) { return true; } #else #error "WUFFS_PRIVATE_IMPL__CPU_ARCH__ETC combined with an unsupported compiler" #endif // defined(__GNUC__); defined(_MSC_VER) #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) return false; #endif // defined(__BMI2__) } static inline bool // wuffs_base__cpu_arch__have_x86_sse42(void) { #if defined(__PCLMUL__) && defined(__POPCNT__) && defined(__SSE4_2__) return true; #else #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) // GCC defines these macros but MSVC does not. // - bit_PCLMUL = (1 << 1) // - bit_POPCNT = (1 << 23) // - bit_SSE4_2 = (1 << 20) const unsigned int sse42_ecx1 = 0x00900002; // clang defines __GNUC__ and clang-cl defines _MSC_VER (but not __GNUC__). #if defined(__GNUC__) unsigned int eax1 = 0; unsigned int ebx1 = 0; unsigned int ecx1 = 0; unsigned int edx1 = 0; if (__get_cpuid(1, &eax1, &ebx1, &ecx1, &edx1) && ((ecx1 & sse42_ecx1) == sse42_ecx1)) { return true; } #elif defined(_MSC_VER) // defined(__GNUC__) int x1[4]; __cpuid(x1, 1); if ((((unsigned int)(x1[2])) & sse42_ecx1) == sse42_ecx1) { return true; } #else #error "WUFFS_PRIVATE_IMPL__CPU_ARCH__ETC combined with an unsupported compiler" #endif // defined(__GNUC__); defined(_MSC_VER) #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64) return false; #endif // defined(__PCLMUL__) && defined(__POPCNT__) && defined(__SSE4_2__) } // ---------------- Fundamentals // Wuffs assumes that: // - converting a uint32_t to a size_t will never overflow. // - converting a size_t to a uint64_t will never overflow. #if defined(__WORDSIZE) #if (__WORDSIZE != 32) && (__WORDSIZE != 64) #error "Wuffs requires a word size of either 32 or 64 bits" #endif #endif // The "defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #if defined(__GNUC__) || defined(__clang__) #define WUFFS_BASE__FORCE_INLINE __attribute__((__always_inline__)) #define WUFFS_BASE__POTENTIALLY_UNUSED __attribute__((unused)) #define WUFFS_BASE__WARN_UNUSED_RESULT __attribute__((warn_unused_result)) #elif defined(_MSC_VER) #define WUFFS_BASE__FORCE_INLINE __forceinline #define WUFFS_BASE__POTENTIALLY_UNUSED #define WUFFS_BASE__WARN_UNUSED_RESULT #else #define WUFFS_BASE__FORCE_INLINE #define WUFFS_BASE__POTENTIALLY_UNUSED #define WUFFS_BASE__WARN_UNUSED_RESULT #endif // Clang's "-fsanitize=integer" checks for "unsigned-integer-overflow" even // though, for *unsigned* integers, it is *not* undefined behavior. The check // is still made because unsigned integer overflow "is often unintentional". // https://clang.llvm.org/docs/UndefinedBehaviorSanitizer.html // // However, for Wuffs' generated C code, unsigned overflow is intentional. The // programmer has to use "~mod+" instead of a plain "+" operator in Wuffs code. // Further runtime checks for unsigned integer overflow can add performance // overhead (fuzzers can then time out) and can raise false negatives, without // generating much benefits. We disable the "unsigned-integer-overflow" check. #if defined(__has_feature) #if __has_feature(undefined_behavior_sanitizer) #define WUFFS_BASE__GENERATED_C_CODE \ __attribute__((no_sanitize("unsigned-integer-overflow"))) #endif #endif #if !defined(WUFFS_BASE__GENERATED_C_CODE) #define WUFFS_BASE__GENERATED_C_CODE #endif // -------- // Options (bitwise or'ed together) for wuffs_foo__bar__initialize functions. #define WUFFS_INITIALIZE__DEFAULT_OPTIONS ((uint32_t)0x00000000) // WUFFS_INITIALIZE__ALREADY_ZEROED means that the "self" receiver struct value // has already been set to all zeroes. #define WUFFS_INITIALIZE__ALREADY_ZEROED ((uint32_t)0x00000001) // WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED means that, absent // WUFFS_INITIALIZE__ALREADY_ZEROED, only some of the "self" receiver struct // value will be set to all zeroes. Internal buffers, which tend to be a large // proportion of the struct's size, will be left uninitialized. Internal means // that the buffer is contained by the receiver struct, as opposed to being // passed as a separately allocated "work buffer". // // For more detail, see: // https://github.com/google/wuffs/blob/main/doc/note/initialization.md #define WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED \ ((uint32_t)0x00000002) // -------- #ifdef __cplusplus // Wuffs structs are just data, not resources (in the RAII sense). They don't // subclass anything. They don't have virtual destructors. They don't contain // pointers to dynamically allocated memory. They don't contain file // descriptors. And so on. Destroying such a struct (e.g. via a // wuffs_foo__bar::unique_ptr) can just call free, especially as // sizeof(wuffs_foo__bar) isn't supposed to be part of the public (stable) API. struct wuffs_unique_ptr_deleter { void operator()(void* p) { free(p); } }; #endif // __cplusplus // -------- #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wcast-qual" #endif static inline uint8_t* // wuffs_base__strip_const_from_u8_ptr(const uint8_t* ptr) { return (uint8_t*)ptr; } static inline uint16_t* // wuffs_base__strip_const_from_u16_ptr(const uint16_t* ptr) { return (uint16_t*)ptr; } static inline uint32_t* // wuffs_base__strip_const_from_u32_ptr(const uint32_t* ptr) { return (uint32_t*)ptr; } static inline uint64_t* // wuffs_base__strip_const_from_u64_ptr(const uint64_t* ptr) { return (uint64_t*)ptr; } #if defined(__GNUC__) #pragma GCC diagnostic pop #endif // -------- // wuffs_base__empty_struct is used when a Wuffs function returns an empty // struct. In C, if a function f returns void, you can't say "x = f()", but in // Wuffs, if a function g returns empty, you can say "y = g()". typedef struct wuffs_base__empty_struct__struct { // private_impl is a placeholder field. It isn't explicitly used, except that // without it, the sizeof a struct with no fields can differ across C/C++ // compilers, and it is undefined behavior in C99. For example, gcc says that // the sizeof an empty struct is 0, and g++ says that it is 1. This leads to // ABI incompatibility if a Wuffs .c file is processed by one compiler and // its .h file with another compiler. // // Instead, we explicitly insert an otherwise unused field, so that the // sizeof this struct is always 1. uint8_t private_impl; } wuffs_base__empty_struct; static inline wuffs_base__empty_struct // wuffs_base__make_empty_struct(void) { wuffs_base__empty_struct ret; ret.private_impl = 0; return ret; } // wuffs_base__utility is a placeholder receiver type. It enables what Java // calls static methods, as opposed to regular methods. typedef struct wuffs_base__utility__struct { // private_impl is a placeholder field. It isn't explicitly used, except that // without it, the sizeof a struct with no fields can differ across C/C++ // compilers, and it is undefined behavior in C99. For example, gcc says that // the sizeof an empty struct is 0, and g++ says that it is 1. This leads to // ABI incompatibility if a Wuffs .c file is processed by one compiler and // its .h file with another compiler. // // Instead, we explicitly insert an otherwise unused field, so that the // sizeof this struct is always 1. uint8_t private_impl; } wuffs_base__utility; typedef struct wuffs_base__vtable__struct { const char* vtable_name; const void* function_pointers; } wuffs_base__vtable; // -------- // See https://github.com/google/wuffs/blob/main/doc/note/statuses.md typedef struct wuffs_base__status__struct { const char* repr; #ifdef __cplusplus inline bool is_complete() const; inline bool is_error() const; inline bool is_note() const; inline bool is_ok() const; inline bool is_suspension() const; inline bool is_truncated_input_error() const; inline const char* message() const; #endif // __cplusplus } wuffs_base__status; extern const char wuffs_base__note__i_o_redirect[]; extern const char wuffs_base__note__end_of_data[]; extern const char wuffs_base__note__metadata_reported[]; extern const char wuffs_base__suspension__even_more_information[]; extern const char wuffs_base__suspension__mispositioned_read[]; extern const char wuffs_base__suspension__mispositioned_write[]; extern const char wuffs_base__suspension__short_read[]; extern const char wuffs_base__suspension__short_workbuf[]; extern const char wuffs_base__suspension__short_write[]; extern const char wuffs_base__error__bad_i_o_position[]; extern const char wuffs_base__error__bad_argument_length_too_short[]; extern const char wuffs_base__error__bad_argument[]; extern const char wuffs_base__error__bad_call_sequence[]; extern const char wuffs_base__error__bad_data[]; extern const char wuffs_base__error__bad_receiver[]; extern const char wuffs_base__error__bad_restart[]; extern const char wuffs_base__error__bad_sizeof_receiver[]; extern const char wuffs_base__error__bad_vtable[]; extern const char wuffs_base__error__bad_workbuf_length[]; extern const char wuffs_base__error__bad_wuffs_version[]; extern const char wuffs_base__error__cannot_return_a_suspension[]; extern const char wuffs_base__error__disabled_by_wuffs_config_dst_pixel_format_enable_allowlist[]; extern const char wuffs_base__error__disabled_by_previous_error[]; extern const char wuffs_base__error__initialize_falsely_claimed_already_zeroed[]; extern const char wuffs_base__error__initialize_not_called[]; extern const char wuffs_base__error__insufficient_history[]; extern const char wuffs_base__error__interleaved_coroutine_calls[]; extern const char wuffs_base__error__no_more_information[]; extern const char wuffs_base__error__not_enough_data[]; extern const char wuffs_base__error__out_of_bounds[]; extern const char wuffs_base__error__unsupported_image_dimension[]; extern const char wuffs_base__error__unsupported_method[]; extern const char wuffs_base__error__unsupported_option[]; extern const char wuffs_base__error__unsupported_pixel_swizzler_option[]; extern const char wuffs_base__error__too_much_data[]; static inline wuffs_base__status // wuffs_base__make_status(const char* repr) { wuffs_base__status z; z.repr = repr; return z; } static inline bool // wuffs_base__status__is_complete(const wuffs_base__status* z) { return (z->repr == NULL) || ((*z->repr != '$') && (*z->repr != '#')); } static inline bool // wuffs_base__status__is_error(const wuffs_base__status* z) { return z->repr && (*z->repr == '#'); } static inline bool // wuffs_base__status__is_note(const wuffs_base__status* z) { return z->repr && (*z->repr != '$') && (*z->repr != '#'); } static inline bool // wuffs_base__status__is_ok(const wuffs_base__status* z) { return z->repr == NULL; } static inline bool // wuffs_base__status__is_suspension(const wuffs_base__status* z) { return z->repr && (*z->repr == '$'); } static inline bool // wuffs_base__status__is_truncated_input_error(const wuffs_base__status* z) { const char* p = z->repr; if (!p || (*p != '#')) { return false; } p++; while (1) { if (*p == 0) { return false; } else if (*p++ == ':') { break; } } return strcmp(p, " truncated input") == 0; } // wuffs_base__status__message strips the leading '$', '#' or '@'. static inline const char* // wuffs_base__status__message(const wuffs_base__status* z) { if (z->repr) { if ((*z->repr == '$') || (*z->repr == '#') || (*z->repr == '@')) { return z->repr + 1; } } return z->repr; } #ifdef __cplusplus inline bool // wuffs_base__status::is_complete() const { return wuffs_base__status__is_complete(this); } inline bool // wuffs_base__status::is_error() const { return wuffs_base__status__is_error(this); } inline bool // wuffs_base__status::is_note() const { return wuffs_base__status__is_note(this); } inline bool // wuffs_base__status::is_ok() const { return wuffs_base__status__is_ok(this); } inline bool // wuffs_base__status::is_suspension() const { return wuffs_base__status__is_suspension(this); } inline bool // wuffs_base__status::is_truncated_input_error() const { return wuffs_base__status__is_truncated_input_error(this); } inline const char* // wuffs_base__status::message() const { return wuffs_base__status__message(this); } #endif // __cplusplus // -------- // WUFFS_BASE__RESULT is a result type: either a status (an error) or a value. // // A result with all fields NULL or zero is as valid as a zero-valued T. #define WUFFS_BASE__RESULT(T) \ struct { \ wuffs_base__status status; \ T value; \ } typedef WUFFS_BASE__RESULT(double) wuffs_base__result_f64; typedef WUFFS_BASE__RESULT(int64_t) wuffs_base__result_i64; typedef WUFFS_BASE__RESULT(uint64_t) wuffs_base__result_u64; // -------- // wuffs_base__transform__output is the result of transforming from a src slice // to a dst slice. typedef struct wuffs_base__transform__output__struct { wuffs_base__status status; size_t num_dst; size_t num_src; } wuffs_base__transform__output; // -------- // FourCC constants. Four Character Codes are literally four ASCII characters // (sometimes padded with ' ' spaces) that pack neatly into a signed or // unsigned 32-bit integer. ASCII letters are conventionally upper case. // // They are often used to identify video codecs (e.g. "H265") and pixel formats // (e.g. "YV12"). Wuffs uses them for that but also generally for naming // various things: compression formats (e.g. "BZ2 "), image metadata (e.g. // "EXIF"), file formats (e.g. "HTML"), etc. // // Wuffs' u32 values are big-endian ("JPEG" is 0x4A504547 not 0x4745504A) to // preserve ordering: "JPEG" < "MP3 " and 0x4A504547 < 0x4D503320. // Background Color. #define WUFFS_BASE__FOURCC__BGCL 0x4247434C // Bitmap. #define WUFFS_BASE__FOURCC__BMP 0x424D5020 // Brotli. #define WUFFS_BASE__FOURCC__BRTL 0x4252544C // Bzip2. #define WUFFS_BASE__FOURCC__BZ2 0x425A3220 // Concise Binary Object Representation. #define WUFFS_BASE__FOURCC__CBOR 0x43424F52 // Primary Chromaticities and White Point. #define WUFFS_BASE__FOURCC__CHRM 0x4348524D // Cascading Style Sheets. #define WUFFS_BASE__FOURCC__CSS 0x43535320 // Encapsulated PostScript. #define WUFFS_BASE__FOURCC__EPS 0x45505320 // Exchangeable Image File Format. #define WUFFS_BASE__FOURCC__EXIF 0x45584946 // Free Lossless Audio Codec. #define WUFFS_BASE__FOURCC__FLAC 0x464C4143 // Gamma Correction. #define WUFFS_BASE__FOURCC__GAMA 0x47414D41 // Graphics Interchange Format. #define WUFFS_BASE__FOURCC__GIF 0x47494620 // GNU Zip. #define WUFFS_BASE__FOURCC__GZ 0x475A2020 // High Efficiency Image File. #define WUFFS_BASE__FOURCC__HEIF 0x48454946 // Hypertext Markup Language. #define WUFFS_BASE__FOURCC__HTML 0x48544D4C // International Color Consortium Profile. #define WUFFS_BASE__FOURCC__ICCP 0x49434350 // Icon. #define WUFFS_BASE__FOURCC__ICO 0x49434F20 // Icon Vector Graphics. #define WUFFS_BASE__FOURCC__ICVG 0x49435647 // Initialization. #define WUFFS_BASE__FOURCC__INI 0x494E4920 // Joint Photographic Experts Group. #define WUFFS_BASE__FOURCC__JPEG 0x4A504547 // JavaScript. #define WUFFS_BASE__FOURCC__JS 0x4A532020 // JavaScript Object Notation. #define WUFFS_BASE__FOURCC__JSON 0x4A534F4E // JSON With Commas and Comments. #define WUFFS_BASE__FOURCC__JWCC 0x4A574343 // Key-Value Pair. #define WUFFS_BASE__FOURCC__KVP 0x4B565020 // Key-Value Pair (Key). #define WUFFS_BASE__FOURCC__KVPK 0x4B56504B // Key-Value Pair (Value). #define WUFFS_BASE__FOURCC__KVPV 0x4B565056 // Lempel–Ziv 4. #define WUFFS_BASE__FOURCC__LZ4 0x4C5A3420 // Lzip. #define WUFFS_BASE__FOURCC__LZIP 0x4C5A4950 // Lempel–Ziv Markov-chain Algorithm. #define WUFFS_BASE__FOURCC__LZMA 0x4C5A4D41 // Markdown. #define WUFFS_BASE__FOURCC__MD 0x4D442020 // Modification Time. #define WUFFS_BASE__FOURCC__MTIM 0x4D54494D // MPEG-1 Audio Layer III. #define WUFFS_BASE__FOURCC__MP3 0x4D503320 // Naive Image. #define WUFFS_BASE__FOURCC__NIE 0x4E494520 // Netpbm (Portable Anymap). #define WUFFS_BASE__FOURCC__NPBM 0x4E50424D // Offset (2-Dimensional). #define WUFFS_BASE__FOURCC__OFS2 0x4F465332 // Open Type Format. #define WUFFS_BASE__FOURCC__OTF 0x4F544620 // Portable Document Format. #define WUFFS_BASE__FOURCC__PDF 0x50444620 // Physical Dimensions. #define WUFFS_BASE__FOURCC__PHYD 0x50485944 // Portable Network Graphics. #define WUFFS_BASE__FOURCC__PNG 0x504E4720 // PostScript. #define WUFFS_BASE__FOURCC__PS 0x50532020 // Quite OK Image. #define WUFFS_BASE__FOURCC__QOI 0x514F4920 // Random Access Compression. #define WUFFS_BASE__FOURCC__RAC 0x52414320 // Raw. #define WUFFS_BASE__FOURCC__RAW 0x52415720 // Resource Interchange File Format. #define WUFFS_BASE__FOURCC__RIFF 0x52494646 // Riegeli Records. #define WUFFS_BASE__FOURCC__RIGL 0x5249474C // Snappy. #define WUFFS_BASE__FOURCC__SNPY 0x534E5059 // Standard Red Green Blue (Rendering Intent). #define WUFFS_BASE__FOURCC__SRGB 0x53524742 // Scalable Vector Graphics. #define WUFFS_BASE__FOURCC__SVG 0x53564720 // Tape Archive. #define WUFFS_BASE__FOURCC__TAR 0x54415220 // Text. #define WUFFS_BASE__FOURCC__TEXT 0x54455854 // Truevision Advanced Raster Graphics Adapter. #define WUFFS_BASE__FOURCC__TGA 0x54474120 // Tagged Image File Format. #define WUFFS_BASE__FOURCC__TIFF 0x54494646 // Tom's Obvious Minimal Language. #define WUFFS_BASE__FOURCC__TOML 0x544F4D4C // Waveform. #define WUFFS_BASE__FOURCC__WAVE 0x57415645 // Wireless Bitmap. #define WUFFS_BASE__FOURCC__WBMP 0x57424D50 // Web Picture. #define WUFFS_BASE__FOURCC__WEBP 0x57454250 // Web Open Font Format. #define WUFFS_BASE__FOURCC__WOFF 0x574F4646 // Extensible Markup Language. #define WUFFS_BASE__FOURCC__XML 0x584D4C20 // Extensible Metadata Platform. #define WUFFS_BASE__FOURCC__XMP 0x584D5020 // Xz. #define WUFFS_BASE__FOURCC__XZ 0x585A2020 // Zip. #define WUFFS_BASE__FOURCC__ZIP 0x5A495020 // Zlib. #define WUFFS_BASE__FOURCC__ZLIB 0x5A4C4942 // Zstandard. #define WUFFS_BASE__FOURCC__ZSTD 0x5A535444 // -------- // Quirks. #define WUFFS_BASE__QUIRK_IGNORE_CHECKSUM 1 #define WUFFS_BASE__QUIRK_QUALITY 2 // -------- // Flicks are a unit of time. One flick (frame-tick) is 1 / 705_600_000 of a // second. See https://github.com/OculusVR/Flicks typedef int64_t wuffs_base__flicks; #define WUFFS_BASE__FLICKS_PER_SECOND ((uint64_t)705600000) #define WUFFS_BASE__FLICKS_PER_MILLISECOND ((uint64_t)705600) // ---------------- Numeric Types // The helpers below are functions, instead of macros, because their arguments // can be an expression that we shouldn't evaluate more than once. // // They are static, so that linking multiple wuffs .o files won't complain about // duplicate function definitions. // // They are explicitly marked inline, even if modern compilers don't use the // inline attribute to guide optimizations such as inlining, to avoid the // -Wunused-function warning, and we like to compile with -Wall -Werror. static inline int8_t // wuffs_base__i8__min(int8_t x, int8_t y) { return x < y ? x : y; } static inline int8_t // wuffs_base__i8__max(int8_t x, int8_t y) { return x > y ? x : y; } static inline int16_t // wuffs_base__i16__min(int16_t x, int16_t y) { return x < y ? x : y; } static inline int16_t // wuffs_base__i16__max(int16_t x, int16_t y) { return x > y ? x : y; } static inline int32_t // wuffs_base__i32__min(int32_t x, int32_t y) { return x < y ? x : y; } static inline int32_t // wuffs_base__i32__max(int32_t x, int32_t y) { return x > y ? x : y; } static inline int64_t // wuffs_base__i64__min(int64_t x, int64_t y) { return x < y ? x : y; } static inline int64_t // wuffs_base__i64__max(int64_t x, int64_t y) { return x > y ? x : y; } static inline uint8_t // wuffs_base__u8__min(uint8_t x, uint8_t y) { return x < y ? x : y; } static inline uint8_t // wuffs_base__u8__max(uint8_t x, uint8_t y) { return x > y ? x : y; } static inline uint16_t // wuffs_base__u16__min(uint16_t x, uint16_t y) { return x < y ? x : y; } static inline uint16_t // wuffs_base__u16__max(uint16_t x, uint16_t y) { return x > y ? x : y; } static inline uint32_t // wuffs_base__u32__min(uint32_t x, uint32_t y) { return x < y ? x : y; } static inline uint32_t // wuffs_base__u32__max(uint32_t x, uint32_t y) { return x > y ? x : y; } static inline uint64_t // wuffs_base__u64__min(uint64_t x, uint64_t y) { return x < y ? x : y; } static inline uint64_t // wuffs_base__u64__max(uint64_t x, uint64_t y) { return x > y ? x : y; } // -------- static inline uint8_t // wuffs_base__u8__rotate_left(uint8_t x, uint32_t n) { n &= 7; return ((uint8_t)(x << n)) | ((uint8_t)(x >> (8 - n))); } static inline uint8_t // wuffs_base__u8__rotate_right(uint8_t x, uint32_t n) { n &= 7; return ((uint8_t)(x >> n)) | ((uint8_t)(x << (8 - n))); } static inline uint16_t // wuffs_base__u16__rotate_left(uint16_t x, uint32_t n) { n &= 15; return ((uint16_t)(x << n)) | ((uint16_t)(x >> (16 - n))); } static inline uint16_t // wuffs_base__u16__rotate_right(uint16_t x, uint32_t n) { n &= 15; return ((uint16_t)(x >> n)) | ((uint16_t)(x << (16 - n))); } static inline uint32_t // wuffs_base__u32__rotate_left(uint32_t x, uint32_t n) { n &= 31; return ((uint32_t)(x << n)) | ((uint32_t)(x >> (32 - n))); } static inline uint32_t // wuffs_base__u32__rotate_right(uint32_t x, uint32_t n) { n &= 31; return ((uint32_t)(x >> n)) | ((uint32_t)(x << (32 - n))); } static inline uint64_t // wuffs_base__u64__rotate_left(uint64_t x, uint32_t n) { n &= 63; return ((uint64_t)(x << n)) | ((uint64_t)(x >> (64 - n))); } static inline uint64_t // wuffs_base__u64__rotate_right(uint64_t x, uint32_t n) { n &= 63; return ((uint64_t)(x >> n)) | ((uint64_t)(x << (64 - n))); } // -------- // Saturating arithmetic (sat_add, sat_sub) branchless bit-twiddling algorithms // are per https://locklessinc.com/articles/sat_arithmetic/ // // It is important that the underlying types are unsigned integers, as signed // integer arithmetic overflow is undefined behavior in C. static inline uint8_t // wuffs_base__u8__sat_add(uint8_t x, uint8_t y) { uint8_t res = (uint8_t)(x + y); res |= (uint8_t)(-(res < x)); return res; } static inline uint8_t // wuffs_base__u8__sat_sub(uint8_t x, uint8_t y) { uint8_t res = (uint8_t)(x - y); res &= (uint8_t)(-(res <= x)); return res; } static inline uint16_t // wuffs_base__u16__sat_add(uint16_t x, uint16_t y) { uint16_t res = (uint16_t)(x + y); res |= (uint16_t)(-(res < x)); return res; } static inline uint16_t // wuffs_base__u16__sat_sub(uint16_t x, uint16_t y) { uint16_t res = (uint16_t)(x - y); res &= (uint16_t)(-(res <= x)); return res; } static inline uint32_t // wuffs_base__u32__sat_add(uint32_t x, uint32_t y) { uint32_t res = (uint32_t)(x + y); res |= (uint32_t)(-(res < x)); return res; } static inline uint32_t // wuffs_base__u32__sat_sub(uint32_t x, uint32_t y) { uint32_t res = (uint32_t)(x - y); res &= (uint32_t)(-(res <= x)); return res; } static inline uint64_t // wuffs_base__u64__sat_add(uint64_t x, uint64_t y) { uint64_t res = (uint64_t)(x + y); res |= (uint64_t)(-(res < x)); return res; } static inline uint64_t // wuffs_base__u64__sat_sub(uint64_t x, uint64_t y) { uint64_t res = (uint64_t)(x - y); res &= (uint64_t)(-(res <= x)); return res; } // -------- typedef struct wuffs_base__multiply_u64__output__struct { uint64_t lo; uint64_t hi; } wuffs_base__multiply_u64__output; // wuffs_base__multiply_u64 returns x*y as a 128-bit value. // // The maximum inclusive output hi_lo is 0xFFFFFFFFFFFFFFFE_0000000000000001. static inline wuffs_base__multiply_u64__output // wuffs_base__multiply_u64(uint64_t x, uint64_t y) { #if defined(__SIZEOF_INT128__) __uint128_t z = ((__uint128_t)x) * ((__uint128_t)y); wuffs_base__multiply_u64__output o; o.lo = ((uint64_t)(z)); o.hi = ((uint64_t)(z >> 64)); return o; #else // TODO: consider using the _mul128 intrinsic if defined(_MSC_VER). uint64_t x0 = x & 0xFFFFFFFF; uint64_t x1 = x >> 32; uint64_t y0 = y & 0xFFFFFFFF; uint64_t y1 = y >> 32; uint64_t w0 = x0 * y0; uint64_t t = (x1 * y0) + (w0 >> 32); uint64_t w1 = t & 0xFFFFFFFF; uint64_t w2 = t >> 32; w1 += x0 * y1; wuffs_base__multiply_u64__output o; o.lo = x * y; o.hi = (x1 * y1) + w2 + (w1 >> 32); return o; #endif } // -------- typedef struct wuffs_base__bitvec256__struct { // elements_u64[0] holds the LSBs (least significant bits) and // elements_u64[3] holds the MSBs (most significant bits). uint64_t elements_u64[4]; } wuffs_base__bitvec256; static inline wuffs_base__bitvec256 // wuffs_base__make_bitvec256(uint64_t e00, uint64_t e01, uint64_t e02, uint64_t e03) { wuffs_base__bitvec256 res; res.elements_u64[0] = e00; res.elements_u64[1] = e01; res.elements_u64[2] = e02; res.elements_u64[3] = e03; return res; } static inline uint64_t // wuffs_base__bitvec256__get_u64(const wuffs_base__bitvec256* b, uint32_t i) { return b->elements_u64[i & 3]; } // -------- // wuffs_base__optional_u63 is like a std::optional, but for C (not // just C++) and the value can only hold 63 bits (not 64). // // Do not manipulate repr directly; it is a private implementation detail. typedef struct wuffs_base__optional_u63__struct { uint64_t repr; #ifdef __cplusplus inline bool has_value() const; inline uint64_t value() const; inline uint64_t value_or(uint64_t default_value) const; #endif // __cplusplus } wuffs_base__optional_u63; // wuffs_base__make_optional_u63 ignores value when has_value is false. // // Preconditions: // - value < (1 << 63). static inline wuffs_base__optional_u63 // wuffs_base__make_optional_u63(bool has_value, uint64_t value) { wuffs_base__optional_u63 res; res.repr = has_value ? ((value << 1u) | 1u) : 0u; return res; } static inline bool // wuffs_base__optional_u63__has_value(const wuffs_base__optional_u63* o) { return o->repr; } // wuffs_base__optional_u63__value returns zero when o does not have a value. static inline uint64_t // wuffs_base__optional_u63__value(const wuffs_base__optional_u63* o) { return o->repr >> 1u; } static inline uint64_t // wuffs_base__optional_u63__value_or(const wuffs_base__optional_u63* o, uint64_t default_value) { return o->repr ? (o->repr >> 1u) : default_value; } #ifdef __cplusplus inline bool // wuffs_base__optional_u63::has_value() const { return wuffs_base__optional_u63__has_value(this); } inline uint64_t // wuffs_base__optional_u63::value() const { return wuffs_base__optional_u63__value(this); } inline uint64_t // wuffs_base__optional_u63::value_or(uint64_t default_value) const { return wuffs_base__optional_u63__value_or(this, default_value); } #endif // __cplusplus // -------- // The "defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #if (defined(__GNUC__) || defined(__clang__)) && (__SIZEOF_LONG__ == 8) static inline uint32_t // wuffs_base__count_leading_zeroes_u64(uint64_t u) { return u ? ((uint32_t)(__builtin_clzl(u))) : 64u; } #else // TODO: consider using the _BitScanReverse intrinsic if defined(_MSC_VER). static inline uint32_t // wuffs_base__count_leading_zeroes_u64(uint64_t u) { if (u == 0) { return 64; } uint32_t n = 0; if ((u >> 32) == 0) { n |= 32; u <<= 32; } if ((u >> 48) == 0) { n |= 16; u <<= 16; } if ((u >> 56) == 0) { n |= 8; u <<= 8; } if ((u >> 60) == 0) { n |= 4; u <<= 4; } if ((u >> 62) == 0) { n |= 2; u <<= 2; } if ((u >> 63) == 0) { n |= 1; u <<= 1; } return n; } #endif // (defined(__GNUC__) || defined(__clang__)) && (__SIZEOF_LONG__ == 8) // -------- // Normally, the wuffs_base__peek_etc and wuffs_base__poke_etc implementations // are both (1) correct regardless of CPU endianness and (2) very fast (e.g. an // inlined wuffs_base__peek_u32le__no_bounds_check call, in an optimized clang // or gcc build, is a single MOV instruction on x86_64). // // However, the endian-agnostic implementations are slow on Microsoft's C // compiler (MSC). Alternative memcpy-based implementations restore speed, but // they are only correct on little-endian CPU architectures. Defining // WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE opts in to these implementations. // // https://godbolt.org/z/q4MfjzTPh #if defined(_MSC_VER) && !defined(__clang__) && \ (defined(_M_ARM64) || defined(_M_X64)) #define WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE #endif #define wuffs_base__peek_u8be__no_bounds_check \ wuffs_base__peek_u8__no_bounds_check #define wuffs_base__peek_u8le__no_bounds_check \ wuffs_base__peek_u8__no_bounds_check static inline uint8_t // wuffs_base__peek_u8__no_bounds_check(const uint8_t* p) { return p[0]; } static inline uint16_t // wuffs_base__peek_u16be__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint16_t x; memcpy(&x, p, 2); return _byteswap_ushort(x); #else return (uint16_t)(((uint16_t)(p[0]) << 8) | ((uint16_t)(p[1]) << 0)); #endif } static inline uint16_t // wuffs_base__peek_u16le__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint16_t x; memcpy(&x, p, 2); return x; #else return (uint16_t)(((uint16_t)(p[0]) << 0) | ((uint16_t)(p[1]) << 8)); #endif } static inline uint32_t // wuffs_base__peek_u24be__no_bounds_check(const uint8_t* p) { return ((uint32_t)(p[0]) << 16) | ((uint32_t)(p[1]) << 8) | ((uint32_t)(p[2]) << 0); } static inline uint32_t // wuffs_base__peek_u24le__no_bounds_check(const uint8_t* p) { return ((uint32_t)(p[0]) << 0) | ((uint32_t)(p[1]) << 8) | ((uint32_t)(p[2]) << 16); } static inline uint32_t // wuffs_base__peek_u32be__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint32_t x; memcpy(&x, p, 4); return _byteswap_ulong(x); #else return ((uint32_t)(p[0]) << 24) | ((uint32_t)(p[1]) << 16) | ((uint32_t)(p[2]) << 8) | ((uint32_t)(p[3]) << 0); #endif } static inline uint32_t // wuffs_base__peek_u32le__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint32_t x; memcpy(&x, p, 4); return x; #else return ((uint32_t)(p[0]) << 0) | ((uint32_t)(p[1]) << 8) | ((uint32_t)(p[2]) << 16) | ((uint32_t)(p[3]) << 24); #endif } static inline uint64_t // wuffs_base__peek_u40be__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 32) | ((uint64_t)(p[1]) << 24) | ((uint64_t)(p[2]) << 16) | ((uint64_t)(p[3]) << 8) | ((uint64_t)(p[4]) << 0); } static inline uint64_t // wuffs_base__peek_u40le__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 0) | ((uint64_t)(p[1]) << 8) | ((uint64_t)(p[2]) << 16) | ((uint64_t)(p[3]) << 24) | ((uint64_t)(p[4]) << 32); } static inline uint64_t // wuffs_base__peek_u48be__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 40) | ((uint64_t)(p[1]) << 32) | ((uint64_t)(p[2]) << 24) | ((uint64_t)(p[3]) << 16) | ((uint64_t)(p[4]) << 8) | ((uint64_t)(p[5]) << 0); } static inline uint64_t // wuffs_base__peek_u48le__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 0) | ((uint64_t)(p[1]) << 8) | ((uint64_t)(p[2]) << 16) | ((uint64_t)(p[3]) << 24) | ((uint64_t)(p[4]) << 32) | ((uint64_t)(p[5]) << 40); } static inline uint64_t // wuffs_base__peek_u56be__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 48) | ((uint64_t)(p[1]) << 40) | ((uint64_t)(p[2]) << 32) | ((uint64_t)(p[3]) << 24) | ((uint64_t)(p[4]) << 16) | ((uint64_t)(p[5]) << 8) | ((uint64_t)(p[6]) << 0); } static inline uint64_t // wuffs_base__peek_u56le__no_bounds_check(const uint8_t* p) { return ((uint64_t)(p[0]) << 0) | ((uint64_t)(p[1]) << 8) | ((uint64_t)(p[2]) << 16) | ((uint64_t)(p[3]) << 24) | ((uint64_t)(p[4]) << 32) | ((uint64_t)(p[5]) << 40) | ((uint64_t)(p[6]) << 48); } static inline uint64_t // wuffs_base__peek_u64be__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint64_t x; memcpy(&x, p, 8); return _byteswap_uint64(x); #else return ((uint64_t)(p[0]) << 56) | ((uint64_t)(p[1]) << 48) | ((uint64_t)(p[2]) << 40) | ((uint64_t)(p[3]) << 32) | ((uint64_t)(p[4]) << 24) | ((uint64_t)(p[5]) << 16) | ((uint64_t)(p[6]) << 8) | ((uint64_t)(p[7]) << 0); #endif } static inline uint64_t // wuffs_base__peek_u64le__no_bounds_check(const uint8_t* p) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) uint64_t x; memcpy(&x, p, 8); return x; #else return ((uint64_t)(p[0]) << 0) | ((uint64_t)(p[1]) << 8) | ((uint64_t)(p[2]) << 16) | ((uint64_t)(p[3]) << 24) | ((uint64_t)(p[4]) << 32) | ((uint64_t)(p[5]) << 40) | ((uint64_t)(p[6]) << 48) | ((uint64_t)(p[7]) << 56); #endif } // -------- #define wuffs_base__poke_u8be__no_bounds_check \ wuffs_base__poke_u8__no_bounds_check #define wuffs_base__poke_u8le__no_bounds_check \ wuffs_base__poke_u8__no_bounds_check static inline void // wuffs_base__poke_u8__no_bounds_check(uint8_t* p, uint8_t x) { p[0] = x; } static inline void // wuffs_base__poke_u16be__no_bounds_check(uint8_t* p, uint16_t x) { p[0] = (uint8_t)(x >> 8); p[1] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u16le__no_bounds_check(uint8_t* p, uint16_t x) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) || \ (defined(__GNUC__) && !defined(__clang__) && defined(__x86_64__)) // This seems to perform better on gcc 10 (but not clang 9). Clang also // defines "__GNUC__". memcpy(p, &x, 2); #else p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); #endif } static inline void // wuffs_base__poke_u24be__no_bounds_check(uint8_t* p, uint32_t x) { p[0] = (uint8_t)(x >> 16); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u24le__no_bounds_check(uint8_t* p, uint32_t x) { p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); } static inline void // wuffs_base__poke_u32be__no_bounds_check(uint8_t* p, uint32_t x) { p[0] = (uint8_t)(x >> 24); p[1] = (uint8_t)(x >> 16); p[2] = (uint8_t)(x >> 8); p[3] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u32le__no_bounds_check(uint8_t* p, uint32_t x) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) || \ (defined(__GNUC__) && !defined(__clang__) && defined(__x86_64__)) // This seems to perform better on gcc 10 (but not clang 9). Clang also // defines "__GNUC__". memcpy(p, &x, 4); #else p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 24); #endif } static inline void // wuffs_base__poke_u40be__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 32); p[1] = (uint8_t)(x >> 24); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 8); p[4] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u40le__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 24); p[4] = (uint8_t)(x >> 32); } static inline void // wuffs_base__poke_u48be__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 40); p[1] = (uint8_t)(x >> 32); p[2] = (uint8_t)(x >> 24); p[3] = (uint8_t)(x >> 16); p[4] = (uint8_t)(x >> 8); p[5] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u48le__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 24); p[4] = (uint8_t)(x >> 32); p[5] = (uint8_t)(x >> 40); } static inline void // wuffs_base__poke_u56be__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 48); p[1] = (uint8_t)(x >> 40); p[2] = (uint8_t)(x >> 32); p[3] = (uint8_t)(x >> 24); p[4] = (uint8_t)(x >> 16); p[5] = (uint8_t)(x >> 8); p[6] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u56le__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 24); p[4] = (uint8_t)(x >> 32); p[5] = (uint8_t)(x >> 40); p[6] = (uint8_t)(x >> 48); } static inline void // wuffs_base__poke_u64be__no_bounds_check(uint8_t* p, uint64_t x) { p[0] = (uint8_t)(x >> 56); p[1] = (uint8_t)(x >> 48); p[2] = (uint8_t)(x >> 40); p[3] = (uint8_t)(x >> 32); p[4] = (uint8_t)(x >> 24); p[5] = (uint8_t)(x >> 16); p[6] = (uint8_t)(x >> 8); p[7] = (uint8_t)(x >> 0); } static inline void // wuffs_base__poke_u64le__no_bounds_check(uint8_t* p, uint64_t x) { #if defined(WUFFS_BASE__USE_MEMCPY_LE_PEEK_POKE) || \ (defined(__GNUC__) && !defined(__clang__) && defined(__x86_64__)) // This seems to perform better on gcc 10 (but not clang 9). Clang also // defines "__GNUC__". memcpy(p, &x, 8); #else p[0] = (uint8_t)(x >> 0); p[1] = (uint8_t)(x >> 8); p[2] = (uint8_t)(x >> 16); p[3] = (uint8_t)(x >> 24); p[4] = (uint8_t)(x >> 32); p[5] = (uint8_t)(x >> 40); p[6] = (uint8_t)(x >> 48); p[7] = (uint8_t)(x >> 56); #endif } // ---------------- Slices and Tables // WUFFS_BASE__SLICE is a 1-dimensional buffer. // // len measures a number of elements, not necessarily a size in bytes. // // A value with all fields NULL or zero is a valid, empty slice. #define WUFFS_BASE__SLICE(T) \ struct { \ T* ptr; \ size_t len; \ } // WUFFS_BASE__TABLE is a 2-dimensional buffer. // // width, height and stride measure a number of elements, not necessarily a // size in bytes. // // A value with all fields NULL or zero is a valid, empty table. #define WUFFS_BASE__TABLE(T) \ struct { \ T* ptr; \ size_t width; \ size_t height; \ size_t stride; \ } typedef WUFFS_BASE__SLICE(uint8_t) wuffs_base__slice_u8; typedef WUFFS_BASE__SLICE(uint16_t) wuffs_base__slice_u16; typedef WUFFS_BASE__SLICE(uint32_t) wuffs_base__slice_u32; typedef WUFFS_BASE__SLICE(uint64_t) wuffs_base__slice_u64; typedef WUFFS_BASE__TABLE(uint8_t) wuffs_base__table_u8; typedef WUFFS_BASE__TABLE(uint16_t) wuffs_base__table_u16; typedef WUFFS_BASE__TABLE(uint32_t) wuffs_base__table_u32; typedef WUFFS_BASE__TABLE(uint64_t) wuffs_base__table_u64; static inline wuffs_base__slice_u8 // wuffs_base__make_slice_u8(uint8_t* ptr, size_t len) { wuffs_base__slice_u8 ret; ret.ptr = ptr; ret.len = len; return ret; } static inline wuffs_base__slice_u16 // wuffs_base__make_slice_u16(uint16_t* ptr, size_t len) { wuffs_base__slice_u16 ret; ret.ptr = ptr; ret.len = len; return ret; } static inline wuffs_base__slice_u32 // wuffs_base__make_slice_u32(uint32_t* ptr, size_t len) { wuffs_base__slice_u32 ret; ret.ptr = ptr; ret.len = len; return ret; } static inline wuffs_base__slice_u64 // wuffs_base__make_slice_u64(uint64_t* ptr, size_t len) { wuffs_base__slice_u64 ret; ret.ptr = ptr; ret.len = len; return ret; } static inline wuffs_base__slice_u8 // wuffs_base__make_slice_u8_ij(uint8_t* ptr, size_t i, size_t j) { wuffs_base__slice_u8 ret; ret.ptr = ptr ? (ptr + i) : NULL; ret.len = (j >= i) ? (j - i) : 0; return ret; } static inline wuffs_base__slice_u16 // wuffs_base__make_slice_u16_ij(uint16_t* ptr, size_t i, size_t j) { wuffs_base__slice_u16 ret; ret.ptr = ptr ? (ptr + i) : NULL; ret.len = (j >= i) ? (j - i) : 0; return ret; } static inline wuffs_base__slice_u32 // wuffs_base__make_slice_u32_ij(uint32_t* ptr, size_t i, size_t j) { wuffs_base__slice_u32 ret; ret.ptr = ptr ? (ptr + i) : NULL; ret.len = (j >= i) ? (j - i) : 0; return ret; } static inline wuffs_base__slice_u64 // wuffs_base__make_slice_u64_ij(uint64_t* ptr, size_t i, size_t j) { wuffs_base__slice_u64 ret; ret.ptr = ptr ? (ptr + i) : NULL; ret.len = (j >= i) ? (j - i) : 0; return ret; } static inline wuffs_base__slice_u8 // wuffs_base__empty_slice_u8(void) { wuffs_base__slice_u8 ret; ret.ptr = NULL; ret.len = 0; return ret; } static inline wuffs_base__slice_u16 // wuffs_base__empty_slice_u16(void) { wuffs_base__slice_u16 ret; ret.ptr = NULL; ret.len = 0; return ret; } static inline wuffs_base__slice_u32 // wuffs_base__empty_slice_u32(void) { wuffs_base__slice_u32 ret; ret.ptr = NULL; ret.len = 0; return ret; } static inline wuffs_base__slice_u64 // wuffs_base__empty_slice_u64(void) { wuffs_base__slice_u64 ret; ret.ptr = NULL; ret.len = 0; return ret; } static inline wuffs_base__table_u8 // wuffs_base__make_table_u8(uint8_t* ptr, size_t width, size_t height, size_t stride) { wuffs_base__table_u8 ret; ret.ptr = ptr; ret.width = width; ret.height = height; ret.stride = stride; return ret; } static inline wuffs_base__table_u16 // wuffs_base__make_table_u16(uint16_t* ptr, size_t width, size_t height, size_t stride) { wuffs_base__table_u16 ret; ret.ptr = ptr; ret.width = width; ret.height = height; ret.stride = stride; return ret; } static inline wuffs_base__table_u32 // wuffs_base__make_table_u32(uint32_t* ptr, size_t width, size_t height, size_t stride) { wuffs_base__table_u32 ret; ret.ptr = ptr; ret.width = width; ret.height = height; ret.stride = stride; return ret; } static inline wuffs_base__table_u64 // wuffs_base__make_table_u64(uint64_t* ptr, size_t width, size_t height, size_t stride) { wuffs_base__table_u64 ret; ret.ptr = ptr; ret.width = width; ret.height = height; ret.stride = stride; return ret; } static inline wuffs_base__table_u8 // wuffs_base__empty_table_u8(void) { wuffs_base__table_u8 ret; ret.ptr = NULL; ret.width = 0; ret.height = 0; ret.stride = 0; return ret; } static inline wuffs_base__table_u16 // wuffs_base__empty_table_u16(void) { wuffs_base__table_u16 ret; ret.ptr = NULL; ret.width = 0; ret.height = 0; ret.stride = 0; return ret; } static inline wuffs_base__table_u32 // wuffs_base__empty_table_u32(void) { wuffs_base__table_u32 ret; ret.ptr = NULL; ret.width = 0; ret.height = 0; ret.stride = 0; return ret; } static inline wuffs_base__table_u64 // wuffs_base__empty_table_u64(void) { wuffs_base__table_u64 ret; ret.ptr = NULL; ret.width = 0; ret.height = 0; ret.stride = 0; return ret; } static inline bool // wuffs_base__slice_u8__overlaps(wuffs_base__slice_u8 s, wuffs_base__slice_u8 t) { return ((s.ptr <= t.ptr) && (t.ptr < (s.ptr + s.len))) || ((t.ptr <= s.ptr) && (s.ptr < (t.ptr + t.len))); } // wuffs_base__slice_u8__subslice_i returns s[i:]. // // It returns an empty slice if i is out of bounds. static inline wuffs_base__slice_u8 // wuffs_base__slice_u8__subslice_i(wuffs_base__slice_u8 s, uint64_t i) { if ((i <= SIZE_MAX) && (i <= s.len)) { return wuffs_base__make_slice_u8(s.ptr + i, ((size_t)(s.len - i))); } return wuffs_base__empty_slice_u8(); } // wuffs_base__slice_u8__subslice_j returns s[:j]. // // It returns an empty slice if j is out of bounds. static inline wuffs_base__slice_u8 // wuffs_base__slice_u8__subslice_j(wuffs_base__slice_u8 s, uint64_t j) { if ((j <= SIZE_MAX) && (j <= s.len)) { return wuffs_base__make_slice_u8(s.ptr, ((size_t)j)); } return wuffs_base__empty_slice_u8(); } // wuffs_base__slice_u8__subslice_ij returns s[i:j]. // // It returns an empty slice if i or j is out of bounds. static inline wuffs_base__slice_u8 // wuffs_base__slice_u8__subslice_ij(wuffs_base__slice_u8 s, uint64_t i, uint64_t j) { if ((i <= j) && (j <= SIZE_MAX) && (j <= s.len)) { return wuffs_base__make_slice_u8(s.ptr + i, ((size_t)(j - i))); } return wuffs_base__empty_slice_u8(); } // wuffs_base__table_u8__subtable_ij returns t[ix:jx, iy:jy]. // // It returns an empty table if i or j is out of bounds. static inline wuffs_base__table_u8 // wuffs_base__table_u8__subtable_ij(wuffs_base__table_u8 t, uint64_t ix, uint64_t iy, uint64_t jx, uint64_t jy) { if ((ix <= jx) && (jx <= SIZE_MAX) && (jx <= t.width) && // (iy <= jy) && (jy <= SIZE_MAX) && (jy <= t.height)) { return wuffs_base__make_table_u8(t.ptr + ix + (iy * t.stride), // ((size_t)(jx - ix)), // ((size_t)(jy - iy)), // t.stride); // } return wuffs_base__make_table_u8(NULL, 0, 0, 0); } // wuffs_base__table__flattened_length returns the number of elements covered // by the 1-dimensional span that backs a 2-dimensional table. This counts the // elements inside the table and, when width != stride, the elements outside // the table but between its rows. // // For example, consider a width 10, height 4, stride 10 table. Mark its first // and last (inclusive) elements with 'a' and 'z'. This function returns 40. // // a123456789 // 0123456789 // 0123456789 // 012345678z // // Now consider the sub-table of that from (2, 1) inclusive to (8, 4) exclusive. // // a123456789 // 01iiiiiioo // ooiiiiiioo // ooiiiiii8z // // This function (called with width 6, height 3, stride 10) returns 26: 18 'i' // inside elements plus 8 'o' outside elements. Note that 26 is less than a // naive (height * stride = 30) computation. Indeed, advancing 29 elements from // the first 'i' would venture past 'z', out of bounds of the original table. // // It does not check for overflow, but if the arguments come from a table that // exists in memory and each element occupies a positive number of bytes then // the result should be bounded by the amount of allocatable memory (which // shouldn't overflow SIZE_MAX). static inline size_t // wuffs_base__table__flattened_length(size_t width, size_t height, size_t stride) { if (height == 0) { return 0; } return ((height - 1) * stride) + width; } // ---------------- Magic Numbers // wuffs_base__magic_number_guess_fourcc guesses the file format of some data, // given its starting bytes (the prefix_data argument) and whether or not there // may be further bytes (the prefix_closed argument; true means that // prefix_data is the entire data). // // It returns a positive FourCC value on success. // // It returns zero if nothing matches its hard-coded list of 'magic numbers'. // // It returns a negative value if prefix_closed is false and a longer prefix is // required for a conclusive result. For example, a single 'B' byte (without // further data) is not enough to discriminate the BMP and BPG image file // formats. Similarly, a single '\xFF' byte might be the start of JPEG data or // it might be the start of some other binary data. // // It does not do a full validity check. Like any guess made from a short // prefix of the data, it may return false positives. Data that starts with 99 // bytes of valid JPEG followed by corruption or truncation is an invalid JPEG // image overall, but this function will still return WUFFS_BASE__FOURCC__JPEG. // // Another source of false positives is that some 'magic numbers' are valid // ASCII data. A file starting with "GIF87a and GIF89a are the two versions of // GIF" will match GIF's 'magic number' even if it's plain text, not an image. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__MAGIC sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC int32_t // wuffs_base__magic_number_guess_fourcc(wuffs_base__slice_u8 prefix_data, bool prefix_closed); // ---------------- Quirk Values // These constants are the value half of a key-value pair, where the key is // WUFFS_BASE__QUIRK_QUALITY. // // In the Wuffs API, set_quirk takes a u64 value. These macro definitions are // likewise unsigned values (uint64_t) but for this particular key, they are // best interpreted as signed values (int64_t). "Lower-than-default quality" // and "higher-than-default quality", as signed values, are -1 and +1. // // See doc/note/quirks.md for some more discussion about trade-offs. #define WUFFS_BASE__QUIRK_QUALITY__VALUE__LOWER_QUALITY UINT64_MAX #define WUFFS_BASE__QUIRK_QUALITY__VALUE__HIGHER_QUALITY ((uint64_t)1) // ---------------- Ranges and Rects // See https://github.com/google/wuffs/blob/main/doc/note/ranges-and-rects.md typedef struct wuffs_base__range_ii_u32__struct { uint32_t min_incl; uint32_t max_incl; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__range_ii_u32__struct s) const; inline wuffs_base__range_ii_u32__struct intersect( wuffs_base__range_ii_u32__struct s) const; inline wuffs_base__range_ii_u32__struct unite( wuffs_base__range_ii_u32__struct s) const; inline bool contains(uint32_t x) const; inline bool contains_range(wuffs_base__range_ii_u32__struct s) const; #endif // __cplusplus } wuffs_base__range_ii_u32; static inline wuffs_base__range_ii_u32 // wuffs_base__empty_range_ii_u32(void) { wuffs_base__range_ii_u32 ret; ret.min_incl = 0; ret.max_incl = 0; return ret; } static inline wuffs_base__range_ii_u32 // wuffs_base__make_range_ii_u32(uint32_t min_incl, uint32_t max_incl) { wuffs_base__range_ii_u32 ret; ret.min_incl = min_incl; ret.max_incl = max_incl; return ret; } static inline bool // wuffs_base__range_ii_u32__is_empty(const wuffs_base__range_ii_u32* r) { return r->min_incl > r->max_incl; } static inline bool // wuffs_base__range_ii_u32__equals(const wuffs_base__range_ii_u32* r, wuffs_base__range_ii_u32 s) { return (r->min_incl == s.min_incl && r->max_incl == s.max_incl) || (wuffs_base__range_ii_u32__is_empty(r) && wuffs_base__range_ii_u32__is_empty(&s)); } static inline wuffs_base__range_ii_u32 // wuffs_base__range_ii_u32__intersect(const wuffs_base__range_ii_u32* r, wuffs_base__range_ii_u32 s) { wuffs_base__range_ii_u32 t; t.min_incl = wuffs_base__u32__max(r->min_incl, s.min_incl); t.max_incl = wuffs_base__u32__min(r->max_incl, s.max_incl); return t; } static inline wuffs_base__range_ii_u32 // wuffs_base__range_ii_u32__unite(const wuffs_base__range_ii_u32* r, wuffs_base__range_ii_u32 s) { if (wuffs_base__range_ii_u32__is_empty(r)) { return s; } if (wuffs_base__range_ii_u32__is_empty(&s)) { return *r; } wuffs_base__range_ii_u32 t; t.min_incl = wuffs_base__u32__min(r->min_incl, s.min_incl); t.max_incl = wuffs_base__u32__max(r->max_incl, s.max_incl); return t; } static inline bool // wuffs_base__range_ii_u32__contains(const wuffs_base__range_ii_u32* r, uint32_t x) { return (r->min_incl <= x) && (x <= r->max_incl); } static inline bool // wuffs_base__range_ii_u32__contains_range(const wuffs_base__range_ii_u32* r, wuffs_base__range_ii_u32 s) { return wuffs_base__range_ii_u32__equals( &s, wuffs_base__range_ii_u32__intersect(r, s)); } #ifdef __cplusplus inline bool // wuffs_base__range_ii_u32::is_empty() const { return wuffs_base__range_ii_u32__is_empty(this); } inline bool // wuffs_base__range_ii_u32::equals(wuffs_base__range_ii_u32 s) const { return wuffs_base__range_ii_u32__equals(this, s); } inline wuffs_base__range_ii_u32 // wuffs_base__range_ii_u32::intersect(wuffs_base__range_ii_u32 s) const { return wuffs_base__range_ii_u32__intersect(this, s); } inline wuffs_base__range_ii_u32 // wuffs_base__range_ii_u32::unite(wuffs_base__range_ii_u32 s) const { return wuffs_base__range_ii_u32__unite(this, s); } inline bool // wuffs_base__range_ii_u32::contains(uint32_t x) const { return wuffs_base__range_ii_u32__contains(this, x); } inline bool // wuffs_base__range_ii_u32::contains_range(wuffs_base__range_ii_u32 s) const { return wuffs_base__range_ii_u32__contains_range(this, s); } #endif // __cplusplus // -------- typedef struct wuffs_base__range_ie_u32__struct { uint32_t min_incl; uint32_t max_excl; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__range_ie_u32__struct s) const; inline wuffs_base__range_ie_u32__struct intersect( wuffs_base__range_ie_u32__struct s) const; inline wuffs_base__range_ie_u32__struct unite( wuffs_base__range_ie_u32__struct s) const; inline bool contains(uint32_t x) const; inline bool contains_range(wuffs_base__range_ie_u32__struct s) const; inline uint32_t length() const; #endif // __cplusplus } wuffs_base__range_ie_u32; static inline wuffs_base__range_ie_u32 // wuffs_base__empty_range_ie_u32(void) { wuffs_base__range_ie_u32 ret; ret.min_incl = 0; ret.max_excl = 0; return ret; } static inline wuffs_base__range_ie_u32 // wuffs_base__make_range_ie_u32(uint32_t min_incl, uint32_t max_excl) { wuffs_base__range_ie_u32 ret; ret.min_incl = min_incl; ret.max_excl = max_excl; return ret; } static inline bool // wuffs_base__range_ie_u32__is_empty(const wuffs_base__range_ie_u32* r) { return r->min_incl >= r->max_excl; } static inline bool // wuffs_base__range_ie_u32__equals(const wuffs_base__range_ie_u32* r, wuffs_base__range_ie_u32 s) { return (r->min_incl == s.min_incl && r->max_excl == s.max_excl) || (wuffs_base__range_ie_u32__is_empty(r) && wuffs_base__range_ie_u32__is_empty(&s)); } static inline wuffs_base__range_ie_u32 // wuffs_base__range_ie_u32__intersect(const wuffs_base__range_ie_u32* r, wuffs_base__range_ie_u32 s) { wuffs_base__range_ie_u32 t; t.min_incl = wuffs_base__u32__max(r->min_incl, s.min_incl); t.max_excl = wuffs_base__u32__min(r->max_excl, s.max_excl); return t; } static inline wuffs_base__range_ie_u32 // wuffs_base__range_ie_u32__unite(const wuffs_base__range_ie_u32* r, wuffs_base__range_ie_u32 s) { if (wuffs_base__range_ie_u32__is_empty(r)) { return s; } if (wuffs_base__range_ie_u32__is_empty(&s)) { return *r; } wuffs_base__range_ie_u32 t; t.min_incl = wuffs_base__u32__min(r->min_incl, s.min_incl); t.max_excl = wuffs_base__u32__max(r->max_excl, s.max_excl); return t; } static inline bool // wuffs_base__range_ie_u32__contains(const wuffs_base__range_ie_u32* r, uint32_t x) { return (r->min_incl <= x) && (x < r->max_excl); } static inline bool // wuffs_base__range_ie_u32__contains_range(const wuffs_base__range_ie_u32* r, wuffs_base__range_ie_u32 s) { return wuffs_base__range_ie_u32__equals( &s, wuffs_base__range_ie_u32__intersect(r, s)); } static inline uint32_t // wuffs_base__range_ie_u32__length(const wuffs_base__range_ie_u32* r) { return wuffs_base__u32__sat_sub(r->max_excl, r->min_incl); } #ifdef __cplusplus inline bool // wuffs_base__range_ie_u32::is_empty() const { return wuffs_base__range_ie_u32__is_empty(this); } inline bool // wuffs_base__range_ie_u32::equals(wuffs_base__range_ie_u32 s) const { return wuffs_base__range_ie_u32__equals(this, s); } inline wuffs_base__range_ie_u32 // wuffs_base__range_ie_u32::intersect(wuffs_base__range_ie_u32 s) const { return wuffs_base__range_ie_u32__intersect(this, s); } inline wuffs_base__range_ie_u32 // wuffs_base__range_ie_u32::unite(wuffs_base__range_ie_u32 s) const { return wuffs_base__range_ie_u32__unite(this, s); } inline bool // wuffs_base__range_ie_u32::contains(uint32_t x) const { return wuffs_base__range_ie_u32__contains(this, x); } inline bool // wuffs_base__range_ie_u32::contains_range(wuffs_base__range_ie_u32 s) const { return wuffs_base__range_ie_u32__contains_range(this, s); } inline uint32_t // wuffs_base__range_ie_u32::length() const { return wuffs_base__range_ie_u32__length(this); } #endif // __cplusplus // -------- typedef struct wuffs_base__range_ii_u64__struct { uint64_t min_incl; uint64_t max_incl; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__range_ii_u64__struct s) const; inline wuffs_base__range_ii_u64__struct intersect( wuffs_base__range_ii_u64__struct s) const; inline wuffs_base__range_ii_u64__struct unite( wuffs_base__range_ii_u64__struct s) const; inline bool contains(uint64_t x) const; inline bool contains_range(wuffs_base__range_ii_u64__struct s) const; #endif // __cplusplus } wuffs_base__range_ii_u64; static inline wuffs_base__range_ii_u64 // wuffs_base__empty_range_ii_u64(void) { wuffs_base__range_ii_u64 ret; ret.min_incl = 0; ret.max_incl = 0; return ret; } static inline wuffs_base__range_ii_u64 // wuffs_base__make_range_ii_u64(uint64_t min_incl, uint64_t max_incl) { wuffs_base__range_ii_u64 ret; ret.min_incl = min_incl; ret.max_incl = max_incl; return ret; } static inline bool // wuffs_base__range_ii_u64__is_empty(const wuffs_base__range_ii_u64* r) { return r->min_incl > r->max_incl; } static inline bool // wuffs_base__range_ii_u64__equals(const wuffs_base__range_ii_u64* r, wuffs_base__range_ii_u64 s) { return (r->min_incl == s.min_incl && r->max_incl == s.max_incl) || (wuffs_base__range_ii_u64__is_empty(r) && wuffs_base__range_ii_u64__is_empty(&s)); } static inline wuffs_base__range_ii_u64 // wuffs_base__range_ii_u64__intersect(const wuffs_base__range_ii_u64* r, wuffs_base__range_ii_u64 s) { wuffs_base__range_ii_u64 t; t.min_incl = wuffs_base__u64__max(r->min_incl, s.min_incl); t.max_incl = wuffs_base__u64__min(r->max_incl, s.max_incl); return t; } static inline wuffs_base__range_ii_u64 // wuffs_base__range_ii_u64__unite(const wuffs_base__range_ii_u64* r, wuffs_base__range_ii_u64 s) { if (wuffs_base__range_ii_u64__is_empty(r)) { return s; } if (wuffs_base__range_ii_u64__is_empty(&s)) { return *r; } wuffs_base__range_ii_u64 t; t.min_incl = wuffs_base__u64__min(r->min_incl, s.min_incl); t.max_incl = wuffs_base__u64__max(r->max_incl, s.max_incl); return t; } static inline bool // wuffs_base__range_ii_u64__contains(const wuffs_base__range_ii_u64* r, uint64_t x) { return (r->min_incl <= x) && (x <= r->max_incl); } static inline bool // wuffs_base__range_ii_u64__contains_range(const wuffs_base__range_ii_u64* r, wuffs_base__range_ii_u64 s) { return wuffs_base__range_ii_u64__equals( &s, wuffs_base__range_ii_u64__intersect(r, s)); } #ifdef __cplusplus inline bool // wuffs_base__range_ii_u64::is_empty() const { return wuffs_base__range_ii_u64__is_empty(this); } inline bool // wuffs_base__range_ii_u64::equals(wuffs_base__range_ii_u64 s) const { return wuffs_base__range_ii_u64__equals(this, s); } inline wuffs_base__range_ii_u64 // wuffs_base__range_ii_u64::intersect(wuffs_base__range_ii_u64 s) const { return wuffs_base__range_ii_u64__intersect(this, s); } inline wuffs_base__range_ii_u64 // wuffs_base__range_ii_u64::unite(wuffs_base__range_ii_u64 s) const { return wuffs_base__range_ii_u64__unite(this, s); } inline bool // wuffs_base__range_ii_u64::contains(uint64_t x) const { return wuffs_base__range_ii_u64__contains(this, x); } inline bool // wuffs_base__range_ii_u64::contains_range(wuffs_base__range_ii_u64 s) const { return wuffs_base__range_ii_u64__contains_range(this, s); } #endif // __cplusplus // -------- typedef struct wuffs_base__range_ie_u64__struct { uint64_t min_incl; uint64_t max_excl; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__range_ie_u64__struct s) const; inline wuffs_base__range_ie_u64__struct intersect( wuffs_base__range_ie_u64__struct s) const; inline wuffs_base__range_ie_u64__struct unite( wuffs_base__range_ie_u64__struct s) const; inline bool contains(uint64_t x) const; inline bool contains_range(wuffs_base__range_ie_u64__struct s) const; inline uint64_t length() const; #endif // __cplusplus } wuffs_base__range_ie_u64; static inline wuffs_base__range_ie_u64 // wuffs_base__empty_range_ie_u64(void) { wuffs_base__range_ie_u64 ret; ret.min_incl = 0; ret.max_excl = 0; return ret; } static inline wuffs_base__range_ie_u64 // wuffs_base__make_range_ie_u64(uint64_t min_incl, uint64_t max_excl) { wuffs_base__range_ie_u64 ret; ret.min_incl = min_incl; ret.max_excl = max_excl; return ret; } static inline bool // wuffs_base__range_ie_u64__is_empty(const wuffs_base__range_ie_u64* r) { return r->min_incl >= r->max_excl; } static inline bool // wuffs_base__range_ie_u64__equals(const wuffs_base__range_ie_u64* r, wuffs_base__range_ie_u64 s) { return (r->min_incl == s.min_incl && r->max_excl == s.max_excl) || (wuffs_base__range_ie_u64__is_empty(r) && wuffs_base__range_ie_u64__is_empty(&s)); } static inline wuffs_base__range_ie_u64 // wuffs_base__range_ie_u64__intersect(const wuffs_base__range_ie_u64* r, wuffs_base__range_ie_u64 s) { wuffs_base__range_ie_u64 t; t.min_incl = wuffs_base__u64__max(r->min_incl, s.min_incl); t.max_excl = wuffs_base__u64__min(r->max_excl, s.max_excl); return t; } static inline wuffs_base__range_ie_u64 // wuffs_base__range_ie_u64__unite(const wuffs_base__range_ie_u64* r, wuffs_base__range_ie_u64 s) { if (wuffs_base__range_ie_u64__is_empty(r)) { return s; } if (wuffs_base__range_ie_u64__is_empty(&s)) { return *r; } wuffs_base__range_ie_u64 t; t.min_incl = wuffs_base__u64__min(r->min_incl, s.min_incl); t.max_excl = wuffs_base__u64__max(r->max_excl, s.max_excl); return t; } static inline bool // wuffs_base__range_ie_u64__contains(const wuffs_base__range_ie_u64* r, uint64_t x) { return (r->min_incl <= x) && (x < r->max_excl); } static inline bool // wuffs_base__range_ie_u64__contains_range(const wuffs_base__range_ie_u64* r, wuffs_base__range_ie_u64 s) { return wuffs_base__range_ie_u64__equals( &s, wuffs_base__range_ie_u64__intersect(r, s)); } static inline uint64_t // wuffs_base__range_ie_u64__length(const wuffs_base__range_ie_u64* r) { return wuffs_base__u64__sat_sub(r->max_excl, r->min_incl); } #ifdef __cplusplus inline bool // wuffs_base__range_ie_u64::is_empty() const { return wuffs_base__range_ie_u64__is_empty(this); } inline bool // wuffs_base__range_ie_u64::equals(wuffs_base__range_ie_u64 s) const { return wuffs_base__range_ie_u64__equals(this, s); } inline wuffs_base__range_ie_u64 // wuffs_base__range_ie_u64::intersect(wuffs_base__range_ie_u64 s) const { return wuffs_base__range_ie_u64__intersect(this, s); } inline wuffs_base__range_ie_u64 // wuffs_base__range_ie_u64::unite(wuffs_base__range_ie_u64 s) const { return wuffs_base__range_ie_u64__unite(this, s); } inline bool // wuffs_base__range_ie_u64::contains(uint64_t x) const { return wuffs_base__range_ie_u64__contains(this, x); } inline bool // wuffs_base__range_ie_u64::contains_range(wuffs_base__range_ie_u64 s) const { return wuffs_base__range_ie_u64__contains_range(this, s); } inline uint64_t // wuffs_base__range_ie_u64::length() const { return wuffs_base__range_ie_u64__length(this); } #endif // __cplusplus // -------- typedef struct wuffs_base__rect_ii_u32__struct { uint32_t min_incl_x; uint32_t min_incl_y; uint32_t max_incl_x; uint32_t max_incl_y; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__rect_ii_u32__struct s) const; inline wuffs_base__rect_ii_u32__struct intersect( wuffs_base__rect_ii_u32__struct s) const; inline wuffs_base__rect_ii_u32__struct unite( wuffs_base__rect_ii_u32__struct s) const; inline bool contains(uint32_t x, uint32_t y) const; inline bool contains_rect(wuffs_base__rect_ii_u32__struct s) const; #endif // __cplusplus } wuffs_base__rect_ii_u32; static inline wuffs_base__rect_ii_u32 // wuffs_base__empty_rect_ii_u32(void) { wuffs_base__rect_ii_u32 ret; ret.min_incl_x = 0; ret.min_incl_y = 0; ret.max_incl_x = 0; ret.max_incl_y = 0; return ret; } static inline wuffs_base__rect_ii_u32 // wuffs_base__make_rect_ii_u32(uint32_t min_incl_x, uint32_t min_incl_y, uint32_t max_incl_x, uint32_t max_incl_y) { wuffs_base__rect_ii_u32 ret; ret.min_incl_x = min_incl_x; ret.min_incl_y = min_incl_y; ret.max_incl_x = max_incl_x; ret.max_incl_y = max_incl_y; return ret; } static inline bool // wuffs_base__rect_ii_u32__is_empty(const wuffs_base__rect_ii_u32* r) { return (r->min_incl_x > r->max_incl_x) || (r->min_incl_y > r->max_incl_y); } static inline bool // wuffs_base__rect_ii_u32__equals(const wuffs_base__rect_ii_u32* r, wuffs_base__rect_ii_u32 s) { return (r->min_incl_x == s.min_incl_x && r->min_incl_y == s.min_incl_y && r->max_incl_x == s.max_incl_x && r->max_incl_y == s.max_incl_y) || (wuffs_base__rect_ii_u32__is_empty(r) && wuffs_base__rect_ii_u32__is_empty(&s)); } static inline wuffs_base__rect_ii_u32 // wuffs_base__rect_ii_u32__intersect(const wuffs_base__rect_ii_u32* r, wuffs_base__rect_ii_u32 s) { wuffs_base__rect_ii_u32 t; t.min_incl_x = wuffs_base__u32__max(r->min_incl_x, s.min_incl_x); t.min_incl_y = wuffs_base__u32__max(r->min_incl_y, s.min_incl_y); t.max_incl_x = wuffs_base__u32__min(r->max_incl_x, s.max_incl_x); t.max_incl_y = wuffs_base__u32__min(r->max_incl_y, s.max_incl_y); return t; } static inline wuffs_base__rect_ii_u32 // wuffs_base__rect_ii_u32__unite(const wuffs_base__rect_ii_u32* r, wuffs_base__rect_ii_u32 s) { if (wuffs_base__rect_ii_u32__is_empty(r)) { return s; } if (wuffs_base__rect_ii_u32__is_empty(&s)) { return *r; } wuffs_base__rect_ii_u32 t; t.min_incl_x = wuffs_base__u32__min(r->min_incl_x, s.min_incl_x); t.min_incl_y = wuffs_base__u32__min(r->min_incl_y, s.min_incl_y); t.max_incl_x = wuffs_base__u32__max(r->max_incl_x, s.max_incl_x); t.max_incl_y = wuffs_base__u32__max(r->max_incl_y, s.max_incl_y); return t; } static inline bool // wuffs_base__rect_ii_u32__contains(const wuffs_base__rect_ii_u32* r, uint32_t x, uint32_t y) { return (r->min_incl_x <= x) && (x <= r->max_incl_x) && (r->min_incl_y <= y) && (y <= r->max_incl_y); } static inline bool // wuffs_base__rect_ii_u32__contains_rect(const wuffs_base__rect_ii_u32* r, wuffs_base__rect_ii_u32 s) { return wuffs_base__rect_ii_u32__equals( &s, wuffs_base__rect_ii_u32__intersect(r, s)); } #ifdef __cplusplus inline bool // wuffs_base__rect_ii_u32::is_empty() const { return wuffs_base__rect_ii_u32__is_empty(this); } inline bool // wuffs_base__rect_ii_u32::equals(wuffs_base__rect_ii_u32 s) const { return wuffs_base__rect_ii_u32__equals(this, s); } inline wuffs_base__rect_ii_u32 // wuffs_base__rect_ii_u32::intersect(wuffs_base__rect_ii_u32 s) const { return wuffs_base__rect_ii_u32__intersect(this, s); } inline wuffs_base__rect_ii_u32 // wuffs_base__rect_ii_u32::unite(wuffs_base__rect_ii_u32 s) const { return wuffs_base__rect_ii_u32__unite(this, s); } inline bool // wuffs_base__rect_ii_u32::contains(uint32_t x, uint32_t y) const { return wuffs_base__rect_ii_u32__contains(this, x, y); } inline bool // wuffs_base__rect_ii_u32::contains_rect(wuffs_base__rect_ii_u32 s) const { return wuffs_base__rect_ii_u32__contains_rect(this, s); } #endif // __cplusplus // -------- typedef struct wuffs_base__rect_ie_u32__struct { uint32_t min_incl_x; uint32_t min_incl_y; uint32_t max_excl_x; uint32_t max_excl_y; #ifdef __cplusplus inline bool is_empty() const; inline bool equals(wuffs_base__rect_ie_u32__struct s) const; inline wuffs_base__rect_ie_u32__struct intersect( wuffs_base__rect_ie_u32__struct s) const; inline wuffs_base__rect_ie_u32__struct unite( wuffs_base__rect_ie_u32__struct s) const; inline bool contains(uint32_t x, uint32_t y) const; inline bool contains_rect(wuffs_base__rect_ie_u32__struct s) const; inline uint32_t width() const; inline uint32_t height() const; #endif // __cplusplus } wuffs_base__rect_ie_u32; static inline wuffs_base__rect_ie_u32 // wuffs_base__empty_rect_ie_u32(void) { wuffs_base__rect_ie_u32 ret; ret.min_incl_x = 0; ret.min_incl_y = 0; ret.max_excl_x = 0; ret.max_excl_y = 0; return ret; } static inline wuffs_base__rect_ie_u32 // wuffs_base__make_rect_ie_u32(uint32_t min_incl_x, uint32_t min_incl_y, uint32_t max_excl_x, uint32_t max_excl_y) { wuffs_base__rect_ie_u32 ret; ret.min_incl_x = min_incl_x; ret.min_incl_y = min_incl_y; ret.max_excl_x = max_excl_x; ret.max_excl_y = max_excl_y; return ret; } static inline bool // wuffs_base__rect_ie_u32__is_empty(const wuffs_base__rect_ie_u32* r) { return (r->min_incl_x >= r->max_excl_x) || (r->min_incl_y >= r->max_excl_y); } static inline bool // wuffs_base__rect_ie_u32__equals(const wuffs_base__rect_ie_u32* r, wuffs_base__rect_ie_u32 s) { return (r->min_incl_x == s.min_incl_x && r->min_incl_y == s.min_incl_y && r->max_excl_x == s.max_excl_x && r->max_excl_y == s.max_excl_y) || (wuffs_base__rect_ie_u32__is_empty(r) && wuffs_base__rect_ie_u32__is_empty(&s)); } static inline wuffs_base__rect_ie_u32 // wuffs_base__rect_ie_u32__intersect(const wuffs_base__rect_ie_u32* r, wuffs_base__rect_ie_u32 s) { wuffs_base__rect_ie_u32 t; t.min_incl_x = wuffs_base__u32__max(r->min_incl_x, s.min_incl_x); t.min_incl_y = wuffs_base__u32__max(r->min_incl_y, s.min_incl_y); t.max_excl_x = wuffs_base__u32__min(r->max_excl_x, s.max_excl_x); t.max_excl_y = wuffs_base__u32__min(r->max_excl_y, s.max_excl_y); return t; } static inline wuffs_base__rect_ie_u32 // wuffs_base__rect_ie_u32__unite(const wuffs_base__rect_ie_u32* r, wuffs_base__rect_ie_u32 s) { if (wuffs_base__rect_ie_u32__is_empty(r)) { return s; } if (wuffs_base__rect_ie_u32__is_empty(&s)) { return *r; } wuffs_base__rect_ie_u32 t; t.min_incl_x = wuffs_base__u32__min(r->min_incl_x, s.min_incl_x); t.min_incl_y = wuffs_base__u32__min(r->min_incl_y, s.min_incl_y); t.max_excl_x = wuffs_base__u32__max(r->max_excl_x, s.max_excl_x); t.max_excl_y = wuffs_base__u32__max(r->max_excl_y, s.max_excl_y); return t; } static inline bool // wuffs_base__rect_ie_u32__contains(const wuffs_base__rect_ie_u32* r, uint32_t x, uint32_t y) { return (r->min_incl_x <= x) && (x < r->max_excl_x) && (r->min_incl_y <= y) && (y < r->max_excl_y); } static inline bool // wuffs_base__rect_ie_u32__contains_rect(const wuffs_base__rect_ie_u32* r, wuffs_base__rect_ie_u32 s) { return wuffs_base__rect_ie_u32__equals( &s, wuffs_base__rect_ie_u32__intersect(r, s)); } static inline uint32_t // wuffs_base__rect_ie_u32__width(const wuffs_base__rect_ie_u32* r) { return wuffs_base__u32__sat_sub(r->max_excl_x, r->min_incl_x); } static inline uint32_t // wuffs_base__rect_ie_u32__height(const wuffs_base__rect_ie_u32* r) { return wuffs_base__u32__sat_sub(r->max_excl_y, r->min_incl_y); } #ifdef __cplusplus inline bool // wuffs_base__rect_ie_u32::is_empty() const { return wuffs_base__rect_ie_u32__is_empty(this); } inline bool // wuffs_base__rect_ie_u32::equals(wuffs_base__rect_ie_u32 s) const { return wuffs_base__rect_ie_u32__equals(this, s); } inline wuffs_base__rect_ie_u32 // wuffs_base__rect_ie_u32::intersect(wuffs_base__rect_ie_u32 s) const { return wuffs_base__rect_ie_u32__intersect(this, s); } inline wuffs_base__rect_ie_u32 // wuffs_base__rect_ie_u32::unite(wuffs_base__rect_ie_u32 s) const { return wuffs_base__rect_ie_u32__unite(this, s); } inline bool // wuffs_base__rect_ie_u32::contains(uint32_t x, uint32_t y) const { return wuffs_base__rect_ie_u32__contains(this, x, y); } inline bool // wuffs_base__rect_ie_u32::contains_rect(wuffs_base__rect_ie_u32 s) const { return wuffs_base__rect_ie_u32__contains_rect(this, s); } inline uint32_t // wuffs_base__rect_ie_u32::width() const { return wuffs_base__rect_ie_u32__width(this); } inline uint32_t // wuffs_base__rect_ie_u32::height() const { return wuffs_base__rect_ie_u32__height(this); } #endif // __cplusplus // ---------------- More Information // wuffs_base__more_information holds additional fields, typically when a Wuffs // method returns a [note status](/doc/note/statuses.md). // // The flavor field follows the base38 namespace // convention](/doc/note/base38-and-fourcc.md). The other fields' semantics // depends on the flavor. typedef struct wuffs_base__more_information__struct { uint32_t flavor; uint32_t w; uint64_t x; uint64_t y; uint64_t z; #ifdef __cplusplus inline void set(uint32_t flavor_arg, uint32_t w_arg, uint64_t x_arg, uint64_t y_arg, uint64_t z_arg); inline uint32_t io_redirect__fourcc() const; inline wuffs_base__range_ie_u64 io_redirect__range() const; inline uint64_t io_seek__position() const; inline uint32_t metadata__fourcc() const; inline wuffs_base__range_ie_u64 metadata_raw_passthrough__range() const; inline int32_t metadata_parsed__chrm(uint32_t component) const; inline uint32_t metadata_parsed__gama() const; inline uint32_t metadata_parsed__srgb() const; #endif // __cplusplus } wuffs_base__more_information; #define WUFFS_BASE__MORE_INFORMATION__FLAVOR__IO_REDIRECT 1 #define WUFFS_BASE__MORE_INFORMATION__FLAVOR__IO_SEEK 2 #define WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_RAW_PASSTHROUGH 3 #define WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_RAW_TRANSFORM 4 #define WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_PARSED 5 static inline wuffs_base__more_information // wuffs_base__empty_more_information(void) { wuffs_base__more_information ret; ret.flavor = 0; ret.w = 0; ret.x = 0; ret.y = 0; ret.z = 0; return ret; } static inline void // wuffs_base__more_information__set(wuffs_base__more_information* m, uint32_t flavor, uint32_t w, uint64_t x, uint64_t y, uint64_t z) { if (!m) { return; } m->flavor = flavor; m->w = w; m->x = x; m->y = y; m->z = z; } static inline uint32_t // wuffs_base__more_information__io_redirect__fourcc( const wuffs_base__more_information* m) { return m->w; } static inline wuffs_base__range_ie_u64 // wuffs_base__more_information__io_redirect__range( const wuffs_base__more_information* m) { wuffs_base__range_ie_u64 ret; ret.min_incl = m->y; ret.max_excl = m->z; return ret; } static inline uint64_t // wuffs_base__more_information__io_seek__position( const wuffs_base__more_information* m) { return m->x; } static inline uint32_t // wuffs_base__more_information__metadata__fourcc( const wuffs_base__more_information* m) { return m->w; } static inline wuffs_base__range_ie_u64 // wuffs_base__more_information__metadata_raw_passthrough__range( const wuffs_base__more_information* m) { wuffs_base__range_ie_u64 ret; ret.min_incl = m->y; ret.max_excl = m->z; return ret; } #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__WHITE_X 0 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__WHITE_Y 1 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__RED_X 2 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__RED_Y 3 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__GREEN_X 4 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__GREEN_Y 5 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__BLUE_X 6 #define WUFFS_BASE__MORE_INFORMATION__METADATA_PARSED__CHRM__BLUE_Y 7 // wuffs_base__more_information__metadata_parsed__chrm returns chromaticity // values (scaled by 100000) like the PNG "cHRM" chunk. For example, the sRGB // color space corresponds to: // - ETC__CHRM__WHITE_X 31270 // - ETC__CHRM__WHITE_Y 32900 // - ETC__CHRM__RED_X 64000 // - ETC__CHRM__RED_Y 33000 // - ETC__CHRM__GREEN_X 30000 // - ETC__CHRM__GREEN_Y 60000 // - ETC__CHRM__BLUE_X 15000 // - ETC__CHRM__BLUE_Y 6000 // // See // https://ciechanow.ski/color-spaces/#chromaticity-and-white-point-coordinates static inline int32_t // wuffs_base__more_information__metadata_parsed__chrm( const wuffs_base__more_information* m, uint32_t component) { // After the flavor and the w field (holding a FourCC), a // wuffs_base__more_information holds 24 bytes of data in three uint64_t // typed fields (x, y and z). We pack the eight chromaticity values (wx, wy, // rx, ..., by), basically int24_t values, into 24 bytes like this: // - LSB MSB // - x: wx wx wx wy wy wy rx rx // - y: rx ry ry ry gx gx gx gy // - z: gy gy bx bx bx by by by uint32_t u = 0; switch (component & 7) { case 0: u = ((uint32_t)(m->x >> 0)); break; case 1: u = ((uint32_t)(m->x >> 24)); break; case 2: u = ((uint32_t)((m->x >> 48) | (m->y << 16))); break; case 3: u = ((uint32_t)(m->y >> 8)); break; case 4: u = ((uint32_t)(m->y >> 32)); break; case 5: u = ((uint32_t)((m->y >> 56) | (m->z << 8))); break; case 6: u = ((uint32_t)(m->z >> 16)); break; case 7: u = ((uint32_t)(m->z >> 40)); break; } // The left-right shifts sign-extend from 24-bit to 32-bit integers. return ((int32_t)(u << 8)) >> 8; } // wuffs_base__more_information__metadata_parsed__gama returns inverse gamma // correction values (scaled by 100000) like the PNG "gAMA" chunk. For example, // for gamma = 2.2, this returns 45455 (approximating 100000 / 2.2). static inline uint32_t // wuffs_base__more_information__metadata_parsed__gama( const wuffs_base__more_information* m) { return ((uint32_t)(m->x)); } #define WUFFS_BASE__SRGB_RENDERING_INTENT__PERCEPTUAL 0 #define WUFFS_BASE__SRGB_RENDERING_INTENT__RELATIVE_COLORIMETRIC 1 #define WUFFS_BASE__SRGB_RENDERING_INTENT__SATURATION 2 #define WUFFS_BASE__SRGB_RENDERING_INTENT__ABSOLUTE_COLORIMETRIC 3 // wuffs_base__more_information__metadata_parsed__srgb returns the sRGB // rendering intent like the PNG "sRGB" chunk. static inline uint32_t // wuffs_base__more_information__metadata_parsed__srgb( const wuffs_base__more_information* m) { return m->x & 3; } #ifdef __cplusplus inline void // wuffs_base__more_information::set(uint32_t flavor_arg, uint32_t w_arg, uint64_t x_arg, uint64_t y_arg, uint64_t z_arg) { wuffs_base__more_information__set(this, flavor_arg, w_arg, x_arg, y_arg, z_arg); } inline uint32_t // wuffs_base__more_information::io_redirect__fourcc() const { return wuffs_base__more_information__io_redirect__fourcc(this); } inline wuffs_base__range_ie_u64 // wuffs_base__more_information::io_redirect__range() const { return wuffs_base__more_information__io_redirect__range(this); } inline uint64_t // wuffs_base__more_information::io_seek__position() const { return wuffs_base__more_information__io_seek__position(this); } inline uint32_t // wuffs_base__more_information::metadata__fourcc() const { return wuffs_base__more_information__metadata__fourcc(this); } inline wuffs_base__range_ie_u64 // wuffs_base__more_information::metadata_raw_passthrough__range() const { return wuffs_base__more_information__metadata_raw_passthrough__range(this); } inline int32_t // wuffs_base__more_information::metadata_parsed__chrm(uint32_t component) const { return wuffs_base__more_information__metadata_parsed__chrm(this, component); } inline uint32_t // wuffs_base__more_information::metadata_parsed__gama() const { return wuffs_base__more_information__metadata_parsed__gama(this); } inline uint32_t // wuffs_base__more_information::metadata_parsed__srgb() const { return wuffs_base__more_information__metadata_parsed__srgb(this); } #endif // __cplusplus // ---------------- I/O // // See (/doc/note/io-input-output.md). // wuffs_base__io_buffer_meta is the metadata for a wuffs_base__io_buffer's // data. typedef struct wuffs_base__io_buffer_meta__struct { size_t wi; // Write index. Invariant: wi <= len. size_t ri; // Read index. Invariant: ri <= wi. uint64_t pos; // Buffer position (relative to the start of stream). bool closed; // No further writes are expected. } wuffs_base__io_buffer_meta; // wuffs_base__io_buffer is a 1-dimensional buffer (a pointer and length) plus // additional metadata. // // A value with all fields zero is a valid, empty buffer. typedef struct wuffs_base__io_buffer__struct { wuffs_base__slice_u8 data; wuffs_base__io_buffer_meta meta; #ifdef __cplusplus inline bool is_valid() const; inline void compact(); inline void compact_retaining(uint64_t history_retain_length); inline size_t reader_length() const; inline uint8_t* reader_pointer() const; inline uint64_t reader_position() const; inline wuffs_base__slice_u8 reader_slice() const; inline size_t writer_length() const; inline uint8_t* writer_pointer() const; inline uint64_t writer_position() const; inline wuffs_base__slice_u8 writer_slice() const; #endif // __cplusplus } wuffs_base__io_buffer; static inline wuffs_base__io_buffer // wuffs_base__make_io_buffer(wuffs_base__slice_u8 data, wuffs_base__io_buffer_meta meta) { wuffs_base__io_buffer ret; ret.data = data; ret.meta = meta; return ret; } static inline wuffs_base__io_buffer_meta // wuffs_base__make_io_buffer_meta(size_t wi, size_t ri, uint64_t pos, bool closed) { wuffs_base__io_buffer_meta ret; ret.wi = wi; ret.ri = ri; ret.pos = pos; ret.closed = closed; return ret; } static inline wuffs_base__io_buffer // wuffs_base__ptr_u8__reader(uint8_t* ptr, size_t len, bool closed) { wuffs_base__io_buffer ret; ret.data.ptr = ptr; ret.data.len = len; ret.meta.wi = len; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = closed; return ret; } static inline wuffs_base__io_buffer // wuffs_base__ptr_u8__writer(uint8_t* ptr, size_t len) { wuffs_base__io_buffer ret; ret.data.ptr = ptr; ret.data.len = len; ret.meta.wi = 0; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = false; return ret; } static inline wuffs_base__io_buffer // wuffs_base__slice_u8__reader(wuffs_base__slice_u8 s, bool closed) { wuffs_base__io_buffer ret; ret.data.ptr = s.ptr; ret.data.len = s.len; ret.meta.wi = s.len; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = closed; return ret; } static inline wuffs_base__io_buffer // wuffs_base__slice_u8__writer(wuffs_base__slice_u8 s) { wuffs_base__io_buffer ret; ret.data.ptr = s.ptr; ret.data.len = s.len; ret.meta.wi = 0; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = false; return ret; } static inline wuffs_base__io_buffer // wuffs_base__empty_io_buffer(void) { wuffs_base__io_buffer ret; ret.data.ptr = NULL; ret.data.len = 0; ret.meta.wi = 0; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = false; return ret; } static inline wuffs_base__io_buffer_meta // wuffs_base__empty_io_buffer_meta(void) { wuffs_base__io_buffer_meta ret; ret.wi = 0; ret.ri = 0; ret.pos = 0; ret.closed = false; return ret; } static inline bool // wuffs_base__io_buffer__is_valid(const wuffs_base__io_buffer* buf) { if (buf) { if (buf->data.ptr) { return (buf->meta.ri <= buf->meta.wi) && (buf->meta.wi <= buf->data.len); } else { return (buf->meta.ri == 0) && (buf->meta.wi == 0) && (buf->data.len == 0); } } return false; } // wuffs_base__io_buffer__compact moves any written but unread bytes to the // start of the buffer. static inline void // wuffs_base__io_buffer__compact(wuffs_base__io_buffer* buf) { if (!buf || (buf->meta.ri == 0)) { return; } buf->meta.pos = wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.ri); size_t new_wi = buf->meta.wi - buf->meta.ri; if (new_wi != 0) { memmove(buf->data.ptr, buf->data.ptr + buf->meta.ri, new_wi); } buf->meta.wi = new_wi; buf->meta.ri = 0; } // wuffs_base__io_buffer__compact_retaining moves any written but unread bytes // closer to the start of the buffer. It retains H bytes of history (the most // recently read bytes), where H is min(buf->meta.ri, history_retain_length). // It is therefore a no-op if history_retain_length is UINT64_MAX. A // postcondition is that buf->meta.ri == H. // // wuffs_base__io_buffer__compact_retaining(0) is equivalent to // wuffs_base__io_buffer__compact(). // // For example, if buf started like this: // // +--- ri = 3 // v // abcdefgh?? len = 10, pos = 900 // ^ // +--- wi = 8 // // Then, depending on history_retain_length, the resultant buf would be: // // HRL = 0 defgh????? ri = 0 wi = 5 pos = 903 // HRL = 1 cdefgh???? ri = 1 wi = 6 pos = 902 // HRL = 2 bcdefgh??? ri = 2 wi = 7 pos = 901 // HRL = 3 abcdefgh?? ri = 3 wi = 8 pos = 900 // HRL = 4+ abcdefgh?? ri = 3 wi = 8 pos = 900 static inline void // wuffs_base__io_buffer__compact_retaining(wuffs_base__io_buffer* buf, uint64_t history_retain_length) { if (!buf || (buf->meta.ri == 0)) { return; } size_t old_ri = buf->meta.ri; size_t new_ri = (size_t)(wuffs_base__u64__min(old_ri, history_retain_length)); size_t memmove_start = old_ri - new_ri; buf->meta.pos = wuffs_base__u64__sat_add(buf->meta.pos, memmove_start); size_t new_wi = buf->meta.wi - memmove_start; if ((new_wi != 0) && (memmove_start != 0)) { memmove(buf->data.ptr, buf->data.ptr + memmove_start, new_wi); } buf->meta.wi = new_wi; buf->meta.ri = new_ri; } static inline size_t // wuffs_base__io_buffer__reader_length(const wuffs_base__io_buffer* buf) { return buf ? buf->meta.wi - buf->meta.ri : 0; } static inline uint8_t* // wuffs_base__io_buffer__reader_pointer(const wuffs_base__io_buffer* buf) { return (buf && buf->data.ptr) ? (buf->data.ptr + buf->meta.ri) : NULL; } static inline uint64_t // wuffs_base__io_buffer__reader_position(const wuffs_base__io_buffer* buf) { return buf ? wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.ri) : 0; } static inline wuffs_base__slice_u8 // wuffs_base__io_buffer__reader_slice(const wuffs_base__io_buffer* buf) { return (buf && buf->data.ptr) ? wuffs_base__make_slice_u8(buf->data.ptr + buf->meta.ri, buf->meta.wi - buf->meta.ri) : wuffs_base__empty_slice_u8(); } static inline size_t // wuffs_base__io_buffer__writer_length(const wuffs_base__io_buffer* buf) { return buf ? buf->data.len - buf->meta.wi : 0; } static inline uint8_t* // wuffs_base__io_buffer__writer_pointer(const wuffs_base__io_buffer* buf) { return (buf && buf->data.ptr) ? (buf->data.ptr + buf->meta.wi) : NULL; } static inline uint64_t // wuffs_base__io_buffer__writer_position(const wuffs_base__io_buffer* buf) { return buf ? wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.wi) : 0; } static inline wuffs_base__slice_u8 // wuffs_base__io_buffer__writer_slice(const wuffs_base__io_buffer* buf) { return (buf && buf->data.ptr) ? wuffs_base__make_slice_u8(buf->data.ptr + buf->meta.wi, buf->data.len - buf->meta.wi) : wuffs_base__empty_slice_u8(); } #ifdef __cplusplus inline bool // wuffs_base__io_buffer::is_valid() const { return wuffs_base__io_buffer__is_valid(this); } inline void // wuffs_base__io_buffer::compact() { wuffs_base__io_buffer__compact(this); } inline void // wuffs_base__io_buffer::compact_retaining(uint64_t history_retain_length) { wuffs_base__io_buffer__compact_retaining(this, history_retain_length); } inline size_t // wuffs_base__io_buffer::reader_length() const { return wuffs_base__io_buffer__reader_length(this); } inline uint8_t* // wuffs_base__io_buffer::reader_pointer() const { return wuffs_base__io_buffer__reader_pointer(this); } inline uint64_t // wuffs_base__io_buffer::reader_position() const { return wuffs_base__io_buffer__reader_position(this); } inline wuffs_base__slice_u8 // wuffs_base__io_buffer::reader_slice() const { return wuffs_base__io_buffer__reader_slice(this); } inline size_t // wuffs_base__io_buffer::writer_length() const { return wuffs_base__io_buffer__writer_length(this); } inline uint8_t* // wuffs_base__io_buffer::writer_pointer() const { return wuffs_base__io_buffer__writer_pointer(this); } inline uint64_t // wuffs_base__io_buffer::writer_position() const { return wuffs_base__io_buffer__writer_position(this); } inline wuffs_base__slice_u8 // wuffs_base__io_buffer::writer_slice() const { return wuffs_base__io_buffer__writer_slice(this); } #endif // __cplusplus // ---------------- Tokens // wuffs_base__token is an element of a byte stream's tokenization. // // See https://github.com/google/wuffs/blob/main/doc/note/tokens.md typedef struct wuffs_base__token__struct { uint64_t repr; #ifdef __cplusplus inline int64_t value() const; inline int64_t value_extension() const; inline int64_t value_major() const; inline int64_t value_base_category() const; inline uint64_t value_minor() const; inline uint64_t value_base_detail() const; inline int64_t value_base_detail__sign_extended() const; inline bool continued() const; inline uint64_t length() const; #endif // __cplusplus } wuffs_base__token; static inline wuffs_base__token // wuffs_base__make_token(uint64_t repr) { wuffs_base__token ret; ret.repr = repr; return ret; } // -------- // clang-format off // -------- #define WUFFS_BASE__TOKEN__LENGTH__MAX_INCL 0xFFFF #define WUFFS_BASE__TOKEN__VALUE__SHIFT 17 #define WUFFS_BASE__TOKEN__VALUE_EXTENSION__SHIFT 17 #define WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT 42 #define WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT 17 #define WUFFS_BASE__TOKEN__VALUE_BASE_CATEGORY__SHIFT 38 #define WUFFS_BASE__TOKEN__VALUE_BASE_DETAIL__SHIFT 17 #define WUFFS_BASE__TOKEN__CONTINUED__SHIFT 16 #define WUFFS_BASE__TOKEN__LENGTH__SHIFT 0 #define WUFFS_BASE__TOKEN__VALUE_EXTENSION__NUM_BITS 46 // -------- #define WUFFS_BASE__TOKEN__VBC__FILLER 0 #define WUFFS_BASE__TOKEN__VBC__STRUCTURE 1 #define WUFFS_BASE__TOKEN__VBC__STRING 2 #define WUFFS_BASE__TOKEN__VBC__UNICODE_CODE_POINT 3 #define WUFFS_BASE__TOKEN__VBC__LITERAL 4 #define WUFFS_BASE__TOKEN__VBC__NUMBER 5 #define WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_SIGNED 6 #define WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_UNSIGNED 7 // -------- #define WUFFS_BASE__TOKEN__VBD__FILLER__PUNCTUATION 0x00001 #define WUFFS_BASE__TOKEN__VBD__FILLER__COMMENT_BLOCK 0x00002 #define WUFFS_BASE__TOKEN__VBD__FILLER__COMMENT_LINE 0x00004 // COMMENT_ANY is a bit-wise or of COMMENT_BLOCK AND COMMENT_LINE. #define WUFFS_BASE__TOKEN__VBD__FILLER__COMMENT_ANY 0x00006 // -------- #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH 0x00001 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__POP 0x00002 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_NONE 0x00010 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_LIST 0x00020 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_DICT 0x00040 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_NONE 0x01000 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_LIST 0x02000 #define WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_DICT 0x04000 // -------- // DEFINITELY_FOO means that the destination bytes (and also the source bytes, // for 1_DST_1_SRC_COPY) are in the FOO format. Definitely means that the lack // of the bit means "maybe FOO". It does not necessarily mean "not FOO". // // CHAIN_ETC means that decoding the entire token chain forms a UTF-8 or ASCII // string, not just this current token. CHAIN_ETC_UTF_8 therefore distinguishes // Unicode (UTF-8) strings from byte strings. MUST means that the the token // producer (e.g. parser) must verify this. SHOULD means that the token // consumer (e.g. renderer) should verify this. // // When a CHAIN_ETC_UTF_8 bit is set, the parser must ensure that non-ASCII // code points (with multi-byte UTF-8 encodings) do not straddle token // boundaries. Checking UTF-8 validity can inspect each token separately. // // The lack of any particular bit is conservative: it is valid for all-ASCII // strings, in a single- or multi-token chain, to have none of these bits set. #define WUFFS_BASE__TOKEN__VBD__STRING__DEFINITELY_UTF_8 0x00001 #define WUFFS_BASE__TOKEN__VBD__STRING__CHAIN_MUST_BE_UTF_8 0x00002 #define WUFFS_BASE__TOKEN__VBD__STRING__CHAIN_SHOULD_BE_UTF_8 0x00004 #define WUFFS_BASE__TOKEN__VBD__STRING__DEFINITELY_ASCII 0x00010 #define WUFFS_BASE__TOKEN__VBD__STRING__CHAIN_MUST_BE_ASCII 0x00020 #define WUFFS_BASE__TOKEN__VBD__STRING__CHAIN_SHOULD_BE_ASCII 0x00040 // CONVERT_D_DST_S_SRC means that multiples of S source bytes (possibly padded) // produces multiples of D destination bytes. For example, // CONVERT_1_DST_4_SRC_BACKSLASH_X means a source like "\\x23\\x67\\xAB", where // 12 src bytes encode 3 dst bytes. // // Post-processing may further transform those D destination bytes (e.g. treat // "\\xFF" as the Unicode code point U+00FF instead of the byte 0xFF), but that // is out of scope of this VBD's semantics. // // When src is the empty string, multiple conversion algorithms are applicable // (so these bits are not necessarily mutually exclusive), all producing the // same empty dst string. #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_0_DST_1_SRC_DROP 0x00100 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_1_SRC_COPY 0x00200 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_2_SRC_HEXADECIMAL 0x00400 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_4_SRC_BACKSLASH_X 0x00800 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_3_DST_4_SRC_BASE_64_STD 0x01000 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_3_DST_4_SRC_BASE_64_URL 0x02000 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_4_DST_5_SRC_ASCII_85 0x04000 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_5_DST_8_SRC_BASE_32_HEX 0x08000 #define WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_5_DST_8_SRC_BASE_32_STD 0x10000 // -------- #define WUFFS_BASE__TOKEN__VBD__LITERAL__UNDEFINED 0x00001 #define WUFFS_BASE__TOKEN__VBD__LITERAL__NULL 0x00002 #define WUFFS_BASE__TOKEN__VBD__LITERAL__FALSE 0x00004 #define WUFFS_BASE__TOKEN__VBD__LITERAL__TRUE 0x00008 // -------- // For a source string of "123" or "0x9A", it is valid for a tokenizer to // return any combination of: // - WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_FLOATING_POINT. // - WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_INTEGER_SIGNED. // - WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_INTEGER_UNSIGNED. // // For a source string of "+123" or "-0x9A", only the first two are valid. // // For a source string of "123.", only the first one is valid. #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_FLOATING_POINT 0x00001 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_INTEGER_SIGNED 0x00002 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_INTEGER_UNSIGNED 0x00004 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_NEG_INF 0x00010 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_POS_INF 0x00020 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_NEG_NAN 0x00040 #define WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_POS_NAN 0x00080 // The number 300 might be represented as "\x01\x2C", "\x2C\x01\x00\x00" or // "300", which are big-endian, little-endian or text. For binary formats, the // token length (after adjusting for FORMAT_IGNORE_ETC) discriminates // e.g. u16 little-endian vs u32 little-endian. #define WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_BINARY_BIG_ENDIAN 0x00100 #define WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_BINARY_LITTLE_ENDIAN 0x00200 #define WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_TEXT 0x00400 #define WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_IGNORE_FIRST_BYTE 0x01000 // -------- // clang-format on // -------- // wuffs_base__token__value returns the token's high 46 bits, sign-extended. A // negative value means an extended token, non-negative means a simple token. static inline int64_t // wuffs_base__token__value(const wuffs_base__token* t) { return ((int64_t)(t->repr)) >> WUFFS_BASE__TOKEN__VALUE__SHIFT; } // wuffs_base__token__value_extension returns a negative value if the token was // not an extended token. static inline int64_t // wuffs_base__token__value_extension(const wuffs_base__token* t) { return (~(int64_t)(t->repr)) >> WUFFS_BASE__TOKEN__VALUE_EXTENSION__SHIFT; } // wuffs_base__token__value_major returns a negative value if the token was not // a simple token. static inline int64_t // wuffs_base__token__value_major(const wuffs_base__token* t) { return ((int64_t)(t->repr)) >> WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT; } // wuffs_base__token__value_base_category returns a negative value if the token // was not a simple token. static inline int64_t // wuffs_base__token__value_base_category(const wuffs_base__token* t) { return ((int64_t)(t->repr)) >> WUFFS_BASE__TOKEN__VALUE_BASE_CATEGORY__SHIFT; } static inline uint64_t // wuffs_base__token__value_minor(const wuffs_base__token* t) { return (t->repr >> WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) & 0x1FFFFFF; } static inline uint64_t // wuffs_base__token__value_base_detail(const wuffs_base__token* t) { return (t->repr >> WUFFS_BASE__TOKEN__VALUE_BASE_DETAIL__SHIFT) & 0x1FFFFF; } static inline int64_t // wuffs_base__token__value_base_detail__sign_extended( const wuffs_base__token* t) { // The VBD is 21 bits in the middle of t->repr. Left shift the high (64 - 21 // - ETC__SHIFT) bits off, then right shift (sign-extending) back down. uint64_t u = t->repr << (43 - WUFFS_BASE__TOKEN__VALUE_BASE_DETAIL__SHIFT); return ((int64_t)u) >> 43; } static inline bool // wuffs_base__token__continued(const wuffs_base__token* t) { return t->repr & 0x10000; } static inline uint64_t // wuffs_base__token__length(const wuffs_base__token* t) { return (t->repr >> WUFFS_BASE__TOKEN__LENGTH__SHIFT) & 0xFFFF; } #ifdef __cplusplus inline int64_t // wuffs_base__token::value() const { return wuffs_base__token__value(this); } inline int64_t // wuffs_base__token::value_extension() const { return wuffs_base__token__value_extension(this); } inline int64_t // wuffs_base__token::value_major() const { return wuffs_base__token__value_major(this); } inline int64_t // wuffs_base__token::value_base_category() const { return wuffs_base__token__value_base_category(this); } inline uint64_t // wuffs_base__token::value_minor() const { return wuffs_base__token__value_minor(this); } inline uint64_t // wuffs_base__token::value_base_detail() const { return wuffs_base__token__value_base_detail(this); } inline int64_t // wuffs_base__token::value_base_detail__sign_extended() const { return wuffs_base__token__value_base_detail__sign_extended(this); } inline bool // wuffs_base__token::continued() const { return wuffs_base__token__continued(this); } inline uint64_t // wuffs_base__token::length() const { return wuffs_base__token__length(this); } #endif // __cplusplus // -------- #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wcast-qual" #endif static inline wuffs_base__token* // wuffs_base__strip_const_from_token_ptr(const wuffs_base__token* ptr) { return (wuffs_base__token*)ptr; } #if defined(__GNUC__) #pragma GCC diagnostic pop #endif // -------- typedef WUFFS_BASE__SLICE(wuffs_base__token) wuffs_base__slice_token; static inline wuffs_base__slice_token // wuffs_base__make_slice_token(wuffs_base__token* ptr, size_t len) { wuffs_base__slice_token ret; ret.ptr = ptr; ret.len = len; return ret; } static inline wuffs_base__slice_token // wuffs_base__empty_slice_token(void) { wuffs_base__slice_token ret; ret.ptr = NULL; ret.len = 0; return ret; } // -------- // wuffs_base__token_buffer_meta is the metadata for a // wuffs_base__token_buffer's data. typedef struct wuffs_base__token_buffer_meta__struct { size_t wi; // Write index. Invariant: wi <= len. size_t ri; // Read index. Invariant: ri <= wi. uint64_t pos; // Position of the buffer start relative to the stream start. bool closed; // No further writes are expected. } wuffs_base__token_buffer_meta; // wuffs_base__token_buffer is a 1-dimensional buffer (a pointer and length) // plus additional metadata. // // A value with all fields zero is a valid, empty buffer. typedef struct wuffs_base__token_buffer__struct { wuffs_base__slice_token data; wuffs_base__token_buffer_meta meta; #ifdef __cplusplus inline bool is_valid() const; inline void compact(); inline void compact_retaining(uint64_t history_retain_length); inline uint64_t reader_length() const; inline wuffs_base__token* reader_pointer() const; inline wuffs_base__slice_token reader_slice() const; inline uint64_t reader_token_position() const; inline uint64_t writer_length() const; inline uint64_t writer_token_position() const; inline wuffs_base__token* writer_pointer() const; inline wuffs_base__slice_token writer_slice() const; #endif // __cplusplus } wuffs_base__token_buffer; static inline wuffs_base__token_buffer // wuffs_base__make_token_buffer(wuffs_base__slice_token data, wuffs_base__token_buffer_meta meta) { wuffs_base__token_buffer ret; ret.data = data; ret.meta = meta; return ret; } static inline wuffs_base__token_buffer_meta // wuffs_base__make_token_buffer_meta(size_t wi, size_t ri, uint64_t pos, bool closed) { wuffs_base__token_buffer_meta ret; ret.wi = wi; ret.ri = ri; ret.pos = pos; ret.closed = closed; return ret; } static inline wuffs_base__token_buffer // wuffs_base__slice_token__reader(wuffs_base__slice_token s, bool closed) { wuffs_base__token_buffer ret; ret.data.ptr = s.ptr; ret.data.len = s.len; ret.meta.wi = s.len; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = closed; return ret; } static inline wuffs_base__token_buffer // wuffs_base__slice_token__writer(wuffs_base__slice_token s) { wuffs_base__token_buffer ret; ret.data.ptr = s.ptr; ret.data.len = s.len; ret.meta.wi = 0; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = false; return ret; } static inline wuffs_base__token_buffer // wuffs_base__empty_token_buffer(void) { wuffs_base__token_buffer ret; ret.data.ptr = NULL; ret.data.len = 0; ret.meta.wi = 0; ret.meta.ri = 0; ret.meta.pos = 0; ret.meta.closed = false; return ret; } static inline wuffs_base__token_buffer_meta // wuffs_base__empty_token_buffer_meta(void) { wuffs_base__token_buffer_meta ret; ret.wi = 0; ret.ri = 0; ret.pos = 0; ret.closed = false; return ret; } static inline bool // wuffs_base__token_buffer__is_valid(const wuffs_base__token_buffer* buf) { if (buf) { if (buf->data.ptr) { return (buf->meta.ri <= buf->meta.wi) && (buf->meta.wi <= buf->data.len); } else { return (buf->meta.ri == 0) && (buf->meta.wi == 0) && (buf->data.len == 0); } } return false; } // wuffs_base__token_buffer__compact moves any written but unread tokens to the // start of the buffer. static inline void // wuffs_base__token_buffer__compact(wuffs_base__token_buffer* buf) { if (!buf || (buf->meta.ri == 0)) { return; } buf->meta.pos = wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.ri); size_t new_wi = buf->meta.wi - buf->meta.ri; if (new_wi != 0) { memmove(buf->data.ptr, buf->data.ptr + buf->meta.ri, new_wi * sizeof(wuffs_base__token)); } buf->meta.wi = new_wi; buf->meta.ri = 0; } // wuffs_base__token_buffer__compact_retaining moves any written but unread // tokens closer to the start of the buffer. It retains H tokens of history // (the most recently read tokens), where H is min(buf->meta.ri, // history_retain_length). It is therefore a no-op if history_retain_length is // UINT64_MAX. A postcondition is that buf->meta.ri == H. // // wuffs_base__token_buffer__compact_retaining(0) is equivalent to // wuffs_base__token_buffer__compact(). // // For example, if buf started like this: // // +--- ri = 3 // v // abcdefgh?? len = 10, pos = 900 // ^ // +--- wi = 8 // // Then, depending on history_retain_length, the resultant buf would be: // // HRL = 0 defgh????? ri = 0 wi = 5 pos = 903 // HRL = 1 cdefgh???? ri = 1 wi = 6 pos = 902 // HRL = 2 bcdefgh??? ri = 2 wi = 7 pos = 901 // HRL = 3 abcdefgh?? ri = 3 wi = 8 pos = 900 // HRL = 4+ abcdefgh?? ri = 3 wi = 8 pos = 900 static inline void // wuffs_base__token_buffer__compact_retaining(wuffs_base__token_buffer* buf, uint64_t history_retain_length) { if (!buf || (buf->meta.ri == 0)) { return; } size_t old_ri = buf->meta.ri; size_t new_ri = (size_t)(wuffs_base__u64__min(old_ri, history_retain_length)); size_t memmove_start = old_ri - new_ri; buf->meta.pos = wuffs_base__u64__sat_add(buf->meta.pos, memmove_start); size_t new_wi = buf->meta.wi - memmove_start; if ((new_wi != 0) && (memmove_start != 0)) { memmove(buf->data.ptr, buf->data.ptr + memmove_start, new_wi * sizeof(wuffs_base__token)); } buf->meta.wi = new_wi; buf->meta.ri = new_ri; } static inline uint64_t // wuffs_base__token_buffer__reader_length(const wuffs_base__token_buffer* buf) { return buf ? buf->meta.wi - buf->meta.ri : 0; } static inline wuffs_base__token* // wuffs_base__token_buffer__reader_pointer(const wuffs_base__token_buffer* buf) { return buf ? (buf->data.ptr + buf->meta.ri) : NULL; } static inline wuffs_base__slice_token // wuffs_base__token_buffer__reader_slice(const wuffs_base__token_buffer* buf) { return buf ? wuffs_base__make_slice_token(buf->data.ptr + buf->meta.ri, buf->meta.wi - buf->meta.ri) : wuffs_base__empty_slice_token(); } static inline uint64_t // wuffs_base__token_buffer__reader_token_position( const wuffs_base__token_buffer* buf) { return buf ? wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.ri) : 0; } static inline uint64_t // wuffs_base__token_buffer__writer_length(const wuffs_base__token_buffer* buf) { return buf ? buf->data.len - buf->meta.wi : 0; } static inline wuffs_base__token* // wuffs_base__token_buffer__writer_pointer(const wuffs_base__token_buffer* buf) { return buf ? (buf->data.ptr + buf->meta.wi) : NULL; } static inline wuffs_base__slice_token // wuffs_base__token_buffer__writer_slice(const wuffs_base__token_buffer* buf) { return buf ? wuffs_base__make_slice_token(buf->data.ptr + buf->meta.wi, buf->data.len - buf->meta.wi) : wuffs_base__empty_slice_token(); } static inline uint64_t // wuffs_base__token_buffer__writer_token_position( const wuffs_base__token_buffer* buf) { return buf ? wuffs_base__u64__sat_add(buf->meta.pos, buf->meta.wi) : 0; } #ifdef __cplusplus inline bool // wuffs_base__token_buffer::is_valid() const { return wuffs_base__token_buffer__is_valid(this); } inline void // wuffs_base__token_buffer::compact() { wuffs_base__token_buffer__compact(this); } inline void // wuffs_base__token_buffer::compact_retaining(uint64_t history_retain_length) { wuffs_base__token_buffer__compact_retaining(this, history_retain_length); } inline uint64_t // wuffs_base__token_buffer::reader_length() const { return wuffs_base__token_buffer__reader_length(this); } inline wuffs_base__token* // wuffs_base__token_buffer::reader_pointer() const { return wuffs_base__token_buffer__reader_pointer(this); } inline wuffs_base__slice_token // wuffs_base__token_buffer::reader_slice() const { return wuffs_base__token_buffer__reader_slice(this); } inline uint64_t // wuffs_base__token_buffer::reader_token_position() const { return wuffs_base__token_buffer__reader_token_position(this); } inline uint64_t // wuffs_base__token_buffer::writer_length() const { return wuffs_base__token_buffer__writer_length(this); } inline wuffs_base__token* // wuffs_base__token_buffer::writer_pointer() const { return wuffs_base__token_buffer__writer_pointer(this); } inline wuffs_base__slice_token // wuffs_base__token_buffer::writer_slice() const { return wuffs_base__token_buffer__writer_slice(this); } inline uint64_t // wuffs_base__token_buffer::writer_token_position() const { return wuffs_base__token_buffer__writer_token_position(this); } #endif // __cplusplus // ---------------- Memory Allocation // The memory allocation related functions in this section aren't used by Wuffs // per se, but they may be helpful to the code that uses Wuffs. // wuffs_base__malloc_slice_uxx wraps calling a malloc-like function, except // that it takes a uint64_t number of elements instead of a size_t size in // bytes, and it returns a slice (a pointer and a length) instead of just a // pointer. // // You can pass the C stdlib's malloc as the malloc_func. // // It returns an empty slice (containing a NULL ptr field) if num_uxx is zero // or if (num_uxx * sizeof(uintxx_t)) would overflow SIZE_MAX. static inline wuffs_base__slice_u8 // wuffs_base__malloc_slice_u8(void* (*malloc_func)(size_t), uint64_t num_u8) { if (malloc_func && num_u8 && (num_u8 <= (SIZE_MAX / sizeof(uint8_t)))) { void* p = (*malloc_func)((size_t)(num_u8 * sizeof(uint8_t))); if (p) { return wuffs_base__make_slice_u8((uint8_t*)(p), (size_t)num_u8); } } return wuffs_base__empty_slice_u8(); } static inline wuffs_base__slice_u16 // wuffs_base__malloc_slice_u16(void* (*malloc_func)(size_t), uint64_t num_u16) { if (malloc_func && num_u16 && (num_u16 <= (SIZE_MAX / sizeof(uint16_t)))) { void* p = (*malloc_func)((size_t)(num_u16 * sizeof(uint16_t))); if (p) { return wuffs_base__make_slice_u16((uint16_t*)(p), (size_t)num_u16); } } return wuffs_base__empty_slice_u16(); } static inline wuffs_base__slice_u32 // wuffs_base__malloc_slice_u32(void* (*malloc_func)(size_t), uint64_t num_u32) { if (malloc_func && num_u32 && (num_u32 <= (SIZE_MAX / sizeof(uint32_t)))) { void* p = (*malloc_func)((size_t)(num_u32 * sizeof(uint32_t))); if (p) { return wuffs_base__make_slice_u32((uint32_t*)(p), (size_t)num_u32); } } return wuffs_base__empty_slice_u32(); } static inline wuffs_base__slice_u64 // wuffs_base__malloc_slice_u64(void* (*malloc_func)(size_t), uint64_t num_u64) { if (malloc_func && num_u64 && (num_u64 <= (SIZE_MAX / sizeof(uint64_t)))) { void* p = (*malloc_func)((size_t)(num_u64 * sizeof(uint64_t))); if (p) { return wuffs_base__make_slice_u64((uint64_t*)(p), (size_t)num_u64); } } return wuffs_base__empty_slice_u64(); } // ---------------- Images #define WUFFS_BASE__IMAGE__DIMENSION_MAX_INCL 0xFFFFFF // wuffs_base__color_u32_argb_premul is an 8 bit per channel premultiplied // Alpha, Red, Green, Blue color, as a uint32_t value. Its value is always // 0xAARRGGBB (Alpha most significant, Blue least), regardless of endianness. typedef uint32_t wuffs_base__color_u32_argb_premul; // wuffs_base__color_u32_argb_premul__is_valid returns whether c's Red, Green // and Blue channels are all less than or equal to its Alpha channel. c uses // premultiplied alpha, so 50% opaque 100% saturated red is 0x7F7F_0000 and a // value like 0x7F80_0000 is invalid. static inline bool // wuffs_base__color_u32_argb_premul__is_valid( wuffs_base__color_u32_argb_premul c) { uint32_t a = 0xFF & (c >> 24); uint32_t r = 0xFF & (c >> 16); uint32_t g = 0xFF & (c >> 8); uint32_t b = 0xFF & (c >> 0); return (a >= r) && (a >= g) && (a >= b); } static inline uint16_t // wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_base__color_u32_argb_premul c) { uint32_t r5 = 0xF800 & (c >> 8); uint32_t g6 = 0x07E0 & (c >> 5); uint32_t b5 = 0x001F & (c >> 3); return (uint16_t)(r5 | g6 | b5); } static inline wuffs_base__color_u32_argb_premul // wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul(uint16_t rgb_565) { uint32_t b5 = 0x1F & (rgb_565 >> 0); uint32_t b = (b5 << 3) | (b5 >> 2); uint32_t g6 = 0x3F & (rgb_565 >> 5); uint32_t g = (g6 << 2) | (g6 >> 4); uint32_t r5 = 0x1F & (rgb_565 >> 11); uint32_t r = (r5 << 3) | (r5 >> 2); return 0xFF000000 | (r << 16) | (g << 8) | (b << 0); } static inline uint8_t // wuffs_base__color_u32_argb_premul__as__color_u8_gray( wuffs_base__color_u32_argb_premul c) { // Work in 16-bit color. uint32_t cr = 0x101 * (0xFF & (c >> 16)); uint32_t cg = 0x101 * (0xFF & (c >> 8)); uint32_t cb = 0x101 * (0xFF & (c >> 0)); // These coefficients (the fractions 0.299, 0.587 and 0.114) are the same // as those given by the JFIF specification. // // Note that 19595 + 38470 + 7471 equals 65536, also known as (1 << 16). We // shift by 24, not just by 16, because the return value is 8-bit color, not // 16-bit color. uint32_t weighted_average = (19595 * cr) + (38470 * cg) + (7471 * cb) + 32768; return (uint8_t)(weighted_average >> 24); } static inline uint16_t // wuffs_base__color_u32_argb_premul__as__color_u16_alpha_gray_nonpremul( wuffs_base__color_u32_argb_premul c) { uint32_t a = 0xFF & (c >> 24); if (a == 0) { return 0; } uint32_t a16 = a * 0x101; uint32_t cr = 0xFF & (c >> 16); cr = (cr * (0x101 * 0xFFFF)) / a16; uint32_t cg = 0xFF & (c >> 8); cg = (cg * (0x101 * 0xFFFF)) / a16; uint32_t cb = 0xFF & (c >> 0); cb = (cb * (0x101 * 0xFFFF)) / a16; uint32_t weighted_average = (19595 * cr) + (38470 * cg) + (7471 * cb) + 32768; return (uint16_t)((a16 & 0xFF00) | (weighted_average >> 24)); } static inline uint16_t // wuffs_base__color_u32_argb_premul__as__color_u16_gray( wuffs_base__color_u32_argb_premul c) { // Work in 16-bit color. uint32_t cr = 0x101 * (0xFF & (c >> 16)); uint32_t cg = 0x101 * (0xFF & (c >> 8)); uint32_t cb = 0x101 * (0xFF & (c >> 0)); // These coefficients (the fractions 0.299, 0.587 and 0.114) are the same // as those given by the JFIF specification. // // Note that 19595 + 38470 + 7471 equals 65536, also known as (1 << 16). uint32_t weighted_average = (19595 * cr) + (38470 * cg) + (7471 * cb) + 32768; return (uint16_t)(weighted_average >> 16); } // wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul converts // from non-premultiplied alpha to premultiplied alpha. static inline wuffs_base__color_u32_argb_premul // wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( uint32_t argb_nonpremul) { // Multiplying by 0x101 (twice, once for alpha and once for color) converts // from 8-bit to 16-bit color. Shifting right by 8 undoes that. // // Working in the higher bit depth can produce slightly different (and // arguably slightly more accurate) results. For example, given 8-bit blue // and alpha of 0x80 and 0x81: // // - ((0x80 * 0x81 ) / 0xFF ) = 0x40 = 0x40 // - ((0x8080 * 0x8181) / 0xFFFF) >> 8 = 0x4101 >> 8 = 0x41 uint32_t a = 0xFF & (argb_nonpremul >> 24); uint32_t a16 = a * (0x101 * 0x101); uint32_t r = 0xFF & (argb_nonpremul >> 16); r = ((r * a16) / 0xFFFF) >> 8; uint32_t g = 0xFF & (argb_nonpremul >> 8); g = ((g * a16) / 0xFFFF) >> 8; uint32_t b = 0xFF & (argb_nonpremul >> 0); b = ((b * a16) / 0xFFFF) >> 8; return (a << 24) | (r << 16) | (g << 8) | (b << 0); } // wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul converts // from premultiplied alpha to non-premultiplied alpha. static inline uint32_t // wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( wuffs_base__color_u32_argb_premul c) { uint32_t a = 0xFF & (c >> 24); if (a == 0xFF) { return c; } else if (a == 0) { return 0; } uint32_t a16 = a * 0x101; uint32_t r = 0xFF & (c >> 16); r = ((r * (0x101 * 0xFFFF)) / a16) >> 8; uint32_t g = 0xFF & (c >> 8); g = ((g * (0x101 * 0xFFFF)) / a16) >> 8; uint32_t b = 0xFF & (c >> 0); b = ((b * (0x101 * 0xFFFF)) / a16) >> 8; return (a << 24) | (r << 16) | (g << 8) | (b << 0); } // wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul converts // from 4x16LE non-premultiplied alpha to 4x8 premultiplied alpha. static inline wuffs_base__color_u32_argb_premul // wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( uint64_t argb_nonpremul) { uint32_t a16 = ((uint32_t)(0xFFFF & (argb_nonpremul >> 48))); uint32_t r16 = ((uint32_t)(0xFFFF & (argb_nonpremul >> 32))); r16 = (r16 * a16) / 0xFFFF; uint32_t g16 = ((uint32_t)(0xFFFF & (argb_nonpremul >> 16))); g16 = (g16 * a16) / 0xFFFF; uint32_t b16 = ((uint32_t)(0xFFFF & (argb_nonpremul >> 0))); b16 = (b16 * a16) / 0xFFFF; return ((a16 >> 8) << 24) | ((r16 >> 8) << 16) | ((g16 >> 8) << 8) | ((b16 >> 8) << 0); } // wuffs_base__color_u32_argb_premul__as__color_u64_argb_nonpremul converts // from 4x8 premultiplied alpha to 4x16LE non-premultiplied alpha. static inline uint64_t // wuffs_base__color_u32_argb_premul__as__color_u64_argb_nonpremul( wuffs_base__color_u32_argb_premul c) { uint32_t a = 0xFF & (c >> 24); if (a == 0xFF) { uint64_t r16 = 0x101 * (0xFF & (c >> 16)); uint64_t g16 = 0x101 * (0xFF & (c >> 8)); uint64_t b16 = 0x101 * (0xFF & (c >> 0)); return 0xFFFF000000000000u | (r16 << 32) | (g16 << 16) | (b16 << 0); } else if (a == 0) { return 0; } uint64_t a16 = a * 0x101; uint64_t r = 0xFF & (c >> 16); uint64_t r16 = (r * (0x101 * 0xFFFF)) / a16; uint64_t g = 0xFF & (c >> 8); uint64_t g16 = (g * (0x101 * 0xFFFF)) / a16; uint64_t b = 0xFF & (c >> 0); uint64_t b16 = (b * (0x101 * 0xFFFF)) / a16; return (a16 << 48) | (r16 << 32) | (g16 << 16) | (b16 << 0); } static inline uint64_t // wuffs_base__color_u32__as__color_u64(uint32_t c) { uint64_t a16 = 0x101 * (0xFF & (c >> 24)); uint64_t r16 = 0x101 * (0xFF & (c >> 16)); uint64_t g16 = 0x101 * (0xFF & (c >> 8)); uint64_t b16 = 0x101 * (0xFF & (c >> 0)); return (a16 << 48) | (r16 << 32) | (g16 << 16) | (b16 << 0); } static inline uint32_t // wuffs_base__color_u64__as__color_u32(uint64_t c) { uint32_t a = ((uint32_t)(0xFF & (c >> 56))); uint32_t r = ((uint32_t)(0xFF & (c >> 40))); uint32_t g = ((uint32_t)(0xFF & (c >> 24))); uint32_t b = ((uint32_t)(0xFF & (c >> 8))); return (a << 24) | (r << 16) | (g << 8) | (b << 0); } // wuffs_base__color_ycc__as__color_u32 converts from YCbCr to 0xAARRGGBB. The // alpha bits are always 0xFF. static inline wuffs_base__color_u32_argb_premul // wuffs_base__color_ycc__as__color_u32(uint8_t yy, uint8_t cb, uint8_t cr) { // Work in 16.16 fixed point arithmetic (so that 'one half' is (1 << 15)) and // bias the chroma values by 0x80. uint32_t yy32 = (((uint32_t)yy) << 16) | (1 << 15); uint32_t cb32 = (((uint32_t)cb) - 0x80); uint32_t cr32 = (((uint32_t)cr) - 0x80); // The formulae: // // R = Y + 1.40200 * Cr // G = Y - 0.34414 * Cb - 0.71414 * Cr // B = Y + 1.77200 * Cb // // When scaled by 1<<16: // // 0.34414 becomes 0x0581A = 22554. // 0.71414 becomes 0x0B6D2 = 46802. // 1.40200 becomes 0x166E9 = 91881. // 1.77200 becomes 0x1C5A2 = 116130. // // Since we're working in 16.16 fixed point arithmetic, masking by 0x00FF0000 // (possibly followed by a shift) gives the relevant 8 bits per channel. // // However, we need to saturate for overflow (above 0x00FFFFFF, but not so // high that the MSB Most Significant Bit is set) or for underflow (below // 0x00000000 as int32_t, which means that the MSB is set as uint32_t). In // both cases, some of the high 8 bits (bits 24 ..= 31) will be set. // // "((uint32_t)(((int32_t)x) >> 31))" just replicates x's MSB across all 32 // bits. Prepending that with "~" inverts those bits. Thus, "~(etc)" is // either 0xFFFFFFFF (for overflow) or 0x00000000 (for underflow). uint32_t rr32 = yy32 + (0x166E9 * cr32); uint32_t gg32 = yy32 - (0x0581A * cb32) - (0x0B6D2 * cr32); uint32_t bb32 = yy32 + (0x1C5A2 * cb32); if (rr32 >> 24) { rr32 = ~((uint32_t)(((int32_t)rr32) >> 31)); } if (gg32 >> 24) { gg32 = ~((uint32_t)(((int32_t)gg32) >> 31)); } if (bb32 >> 24) { bb32 = ~((uint32_t)(((int32_t)bb32) >> 31)); } return 0xFF000000 | // ((0x00FF0000 & rr32) >> 0) | // ((0x00FF0000 & gg32) >> 8) | // ((0x00FF0000 & bb32) >> 16); } // wuffs_base__color_ycc__as__color_u32_abgr is like // wuffs_base__color_ycc__as__color_u32 but the uint32_t returned is in // 0xAABBGGRR order, not 0xAARRGGBB. static inline uint32_t // wuffs_base__color_ycc__as__color_u32_abgr(uint8_t yy, uint8_t cb, uint8_t cr) { uint32_t yy32 = (((uint32_t)yy) << 16) | (1 << 15); uint32_t cb32 = (((uint32_t)cb) - 0x80); uint32_t cr32 = (((uint32_t)cr) - 0x80); uint32_t rr32 = yy32 + (0x166E9 * cr32); uint32_t gg32 = yy32 - (0x0581A * cb32) - (0x0B6D2 * cr32); uint32_t bb32 = yy32 + (0x1C5A2 * cb32); if (rr32 >> 24) { rr32 = ~((uint32_t)(((int32_t)rr32) >> 31)); } if (gg32 >> 24) { gg32 = ~((uint32_t)(((int32_t)gg32) >> 31)); } if (bb32 >> 24) { bb32 = ~((uint32_t)(((int32_t)bb32) >> 31)); } return 0xFF000000 | // ((0x00FF0000 & bb32) >> 0) | // ((0x00FF0000 & gg32) >> 8) | // ((0x00FF0000 & rr32) >> 16); } // -------- typedef uint8_t wuffs_base__pixel_blend; // wuffs_base__pixel_blend encodes how to blend source and destination pixels, // accounting for transparency. It encompasses the Porter-Duff compositing // operators as well as the other blending modes defined by PDF. // // TODO: implement the other modes. #define WUFFS_BASE__PIXEL_BLEND__SRC ((wuffs_base__pixel_blend)0) #define WUFFS_BASE__PIXEL_BLEND__SRC_OVER ((wuffs_base__pixel_blend)1) // -------- // wuffs_base__pixel_alpha_transparency is a pixel format's alpha channel // model. It is a property of the pixel format in general, not of a specific // pixel. An RGBA pixel format (with alpha) can still have fully opaque pixels. typedef uint32_t wuffs_base__pixel_alpha_transparency; #define WUFFS_BASE__PIXEL_ALPHA_TRANSPARENCY__OPAQUE 0 #define WUFFS_BASE__PIXEL_ALPHA_TRANSPARENCY__NONPREMULTIPLIED_ALPHA 1 #define WUFFS_BASE__PIXEL_ALPHA_TRANSPARENCY__PREMULTIPLIED_ALPHA 2 #define WUFFS_BASE__PIXEL_ALPHA_TRANSPARENCY__BINARY_ALPHA 3 // -------- // Deprecated: use WUFFS_BASE__PIXEL_FORMAT__NUM_PLANES_MAX_INCL. #define WUFFS_BASE__PIXEL_FORMAT__NUM_PLANES_MAX 4 #define WUFFS_BASE__PIXEL_FORMAT__NUM_PLANES_MAX_INCL 4 #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__INDEX_PLANE 0 #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__COLOR_PLANE 3 // A palette is 256 entries × 4 bytes per entry (e.g. BGRA). #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH 1024 // wuffs_base__pixel_format encodes the format of the bytes that constitute an // image frame's pixel data. // // See https://github.com/google/wuffs/blob/main/doc/note/pixel-formats.md // // Do not manipulate its bits directly; they are private implementation // details. Use methods such as wuffs_base__pixel_format__num_planes instead. typedef struct wuffs_base__pixel_format__struct { uint32_t repr; #ifdef __cplusplus inline bool is_valid() const; inline uint32_t bits_per_pixel() const; inline bool is_direct() const; inline bool is_indexed() const; inline bool is_interleaved() const; inline bool is_planar() const; inline uint32_t num_planes() const; inline wuffs_base__pixel_alpha_transparency transparency() const; #endif // __cplusplus } wuffs_base__pixel_format; static inline wuffs_base__pixel_format // wuffs_base__make_pixel_format(uint32_t repr) { wuffs_base__pixel_format f; f.repr = repr; return f; } // Common 8-bit-depth pixel formats. This list is not exhaustive; not all valid // wuffs_base__pixel_format values are present. // clang-format off #define WUFFS_BASE__PIXEL_FORMAT__INVALID 0x00000000 #define WUFFS_BASE__PIXEL_FORMAT__A 0x02000008 #define WUFFS_BASE__PIXEL_FORMAT__Y 0x20000008 #define WUFFS_BASE__PIXEL_FORMAT__Y_16LE 0x2000000B #define WUFFS_BASE__PIXEL_FORMAT__Y_16BE 0x2010000B #define WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL 0x21000088 #define WUFFS_BASE__PIXEL_FORMAT__YA_PREMUL 0x22000088 #define WUFFS_BASE__PIXEL_FORMAT__YCBCR 0x40020888 #define WUFFS_BASE__PIXEL_FORMAT__YCBCRA_NONPREMUL 0x41038888 #define WUFFS_BASE__PIXEL_FORMAT__YCBCRK 0x50038888 #define WUFFS_BASE__PIXEL_FORMAT__YCOCG 0x60020888 #define WUFFS_BASE__PIXEL_FORMAT__YCOCGA_NONPREMUL 0x61038888 #define WUFFS_BASE__PIXEL_FORMAT__YCOCGK 0x70038888 #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL 0x81040008 #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL 0x82040008 #define WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY 0x83040008 #define WUFFS_BASE__PIXEL_FORMAT__BGR_565 0x80000565 #define WUFFS_BASE__PIXEL_FORMAT__BGR 0x80000888 #define WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL 0x81008888 #define WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE 0x8100BBBB #define WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL 0x82008888 #define WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE 0x8200BBBB #define WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY 0x83008888 #define WUFFS_BASE__PIXEL_FORMAT__BGRX 0x90008888 #define WUFFS_BASE__PIXEL_FORMAT__RGB 0xA0000888 #define WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL 0xA1008888 #define WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL_4X16LE 0xA100BBBB #define WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL 0xA2008888 #define WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL_4X16LE 0xA200BBBB #define WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY 0xA3008888 #define WUFFS_BASE__PIXEL_FORMAT__RGBX 0xB0008888 #define WUFFS_BASE__PIXEL_FORMAT__CMY 0xC0020888 #define WUFFS_BASE__PIXEL_FORMAT__CMYK 0xD0038888 // clang-format on extern const uint32_t wuffs_private_impl__pixel_format__bits_per_channel[16]; static inline bool // wuffs_base__pixel_format__is_valid(const wuffs_base__pixel_format* f) { return f->repr != 0; } // wuffs_base__pixel_format__bits_per_pixel returns the number of bits per // pixel for interleaved pixel formats, and returns 0 for planar pixel formats. static inline uint32_t // wuffs_base__pixel_format__bits_per_pixel(const wuffs_base__pixel_format* f) { if (((f->repr >> 16) & 0x03) != 0) { return 0; } return wuffs_private_impl__pixel_format__bits_per_channel[0x0F & (f->repr >> 0)] + wuffs_private_impl__pixel_format__bits_per_channel[0x0F & (f->repr >> 4)] + wuffs_private_impl__pixel_format__bits_per_channel[0x0F & (f->repr >> 8)] + wuffs_private_impl__pixel_format__bits_per_channel[0x0F & (f->repr >> 12)]; } static inline bool // wuffs_base__pixel_format__is_direct(const wuffs_base__pixel_format* f) { return ((f->repr >> 18) & 0x01) == 0; } static inline bool // wuffs_base__pixel_format__is_indexed(const wuffs_base__pixel_format* f) { return ((f->repr >> 18) & 0x01) != 0; } static inline bool // wuffs_base__pixel_format__is_interleaved(const wuffs_base__pixel_format* f) { return ((f->repr >> 16) & 0x03) == 0; } static inline bool // wuffs_base__pixel_format__is_planar(const wuffs_base__pixel_format* f) { return ((f->repr >> 16) & 0x03) != 0; } static inline uint32_t // wuffs_base__pixel_format__num_planes(const wuffs_base__pixel_format* f) { return ((f->repr >> 16) & 0x03) + 1; } static inline wuffs_base__pixel_alpha_transparency // wuffs_base__pixel_format__transparency(const wuffs_base__pixel_format* f) { return (wuffs_base__pixel_alpha_transparency)((f->repr >> 24) & 0x03); } #ifdef __cplusplus inline bool // wuffs_base__pixel_format::is_valid() const { return wuffs_base__pixel_format__is_valid(this); } inline uint32_t // wuffs_base__pixel_format::bits_per_pixel() const { return wuffs_base__pixel_format__bits_per_pixel(this); } inline bool // wuffs_base__pixel_format::is_direct() const { return wuffs_base__pixel_format__is_direct(this); } inline bool // wuffs_base__pixel_format::is_indexed() const { return wuffs_base__pixel_format__is_indexed(this); } inline bool // wuffs_base__pixel_format::is_interleaved() const { return wuffs_base__pixel_format__is_interleaved(this); } inline bool // wuffs_base__pixel_format::is_planar() const { return wuffs_base__pixel_format__is_planar(this); } inline uint32_t // wuffs_base__pixel_format::num_planes() const { return wuffs_base__pixel_format__num_planes(this); } inline wuffs_base__pixel_alpha_transparency // wuffs_base__pixel_format::transparency() const { return wuffs_base__pixel_format__transparency(this); } #endif // __cplusplus // -------- // wuffs_base__pixel_subsampling encodes whether sample values cover one pixel // or cover multiple pixels. // // See https://github.com/google/wuffs/blob/main/doc/note/pixel-subsampling.md // // Do not manipulate its bits directly; they are private implementation // details. Use methods such as wuffs_base__pixel_subsampling__bias_x instead. typedef struct wuffs_base__pixel_subsampling__struct { uint32_t repr; #ifdef __cplusplus inline uint32_t bias_x(uint32_t plane) const; inline uint32_t denominator_x(uint32_t plane) const; inline uint32_t bias_y(uint32_t plane) const; inline uint32_t denominator_y(uint32_t plane) const; #endif // __cplusplus } wuffs_base__pixel_subsampling; static inline wuffs_base__pixel_subsampling // wuffs_base__make_pixel_subsampling(uint32_t repr) { wuffs_base__pixel_subsampling s; s.repr = repr; return s; } #define WUFFS_BASE__PIXEL_SUBSAMPLING__NONE 0x00000000 #define WUFFS_BASE__PIXEL_SUBSAMPLING__444 0x000000 #define WUFFS_BASE__PIXEL_SUBSAMPLING__440 0x010100 #define WUFFS_BASE__PIXEL_SUBSAMPLING__422 0x101000 #define WUFFS_BASE__PIXEL_SUBSAMPLING__420 0x111100 #define WUFFS_BASE__PIXEL_SUBSAMPLING__411 0x303000 #define WUFFS_BASE__PIXEL_SUBSAMPLING__410 0x313100 static inline uint32_t // wuffs_base__pixel_subsampling__bias_x(const wuffs_base__pixel_subsampling* s, uint32_t plane) { uint32_t shift = ((plane & 0x03) * 8) + 6; return (s->repr >> shift) & 0x03; } static inline uint32_t // wuffs_base__pixel_subsampling__denominator_x( const wuffs_base__pixel_subsampling* s, uint32_t plane) { uint32_t shift = ((plane & 0x03) * 8) + 4; return ((s->repr >> shift) & 0x03) + 1; } static inline uint32_t // wuffs_base__pixel_subsampling__bias_y(const wuffs_base__pixel_subsampling* s, uint32_t plane) { uint32_t shift = ((plane & 0x03) * 8) + 2; return (s->repr >> shift) & 0x03; } static inline uint32_t // wuffs_base__pixel_subsampling__denominator_y( const wuffs_base__pixel_subsampling* s, uint32_t plane) { uint32_t shift = ((plane & 0x03) * 8) + 0; return ((s->repr >> shift) & 0x03) + 1; } #ifdef __cplusplus inline uint32_t // wuffs_base__pixel_subsampling::bias_x(uint32_t plane) const { return wuffs_base__pixel_subsampling__bias_x(this, plane); } inline uint32_t // wuffs_base__pixel_subsampling::denominator_x(uint32_t plane) const { return wuffs_base__pixel_subsampling__denominator_x(this, plane); } inline uint32_t // wuffs_base__pixel_subsampling::bias_y(uint32_t plane) const { return wuffs_base__pixel_subsampling__bias_y(this, plane); } inline uint32_t // wuffs_base__pixel_subsampling::denominator_y(uint32_t plane) const { return wuffs_base__pixel_subsampling__denominator_y(this, plane); } #endif // __cplusplus // -------- typedef struct wuffs_base__pixel_config__struct { // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { wuffs_base__pixel_format pixfmt; wuffs_base__pixel_subsampling pixsub; uint32_t width; uint32_t height; } private_impl; #ifdef __cplusplus inline void set(uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height); inline void invalidate(); inline bool is_valid() const; inline wuffs_base__pixel_format pixel_format() const; inline wuffs_base__pixel_subsampling pixel_subsampling() const; inline wuffs_base__rect_ie_u32 bounds() const; inline uint32_t width() const; inline uint32_t height() const; inline uint64_t pixbuf_len() const; #endif // __cplusplus } wuffs_base__pixel_config; static inline wuffs_base__pixel_config // wuffs_base__null_pixel_config(void) { wuffs_base__pixel_config ret; ret.private_impl.pixfmt.repr = 0; ret.private_impl.pixsub.repr = 0; ret.private_impl.width = 0; ret.private_impl.height = 0; return ret; } // TODO: Should this function return bool? An error type? static inline void // wuffs_base__pixel_config__set(wuffs_base__pixel_config* c, uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height) { if (!c) { return; } if (pixfmt_repr) { do { #if SIZE_MAX < 0xFFFFFFFFFFFFFFFFull uint64_t wh = ((uint64_t)width) * ((uint64_t)height); // TODO: handle things other than 1 byte per pixel. if (wh > ((uint64_t)SIZE_MAX)) { break; } #endif c->private_impl.pixfmt.repr = pixfmt_repr; c->private_impl.pixsub.repr = pixsub_repr; c->private_impl.width = width; c->private_impl.height = height; return; } while (0); } c->private_impl.pixfmt.repr = 0; c->private_impl.pixsub.repr = 0; c->private_impl.width = 0; c->private_impl.height = 0; } static inline void // wuffs_base__pixel_config__invalidate(wuffs_base__pixel_config* c) { if (c) { c->private_impl.pixfmt.repr = 0; c->private_impl.pixsub.repr = 0; c->private_impl.width = 0; c->private_impl.height = 0; } } static inline bool // wuffs_base__pixel_config__is_valid(const wuffs_base__pixel_config* c) { return c && c->private_impl.pixfmt.repr; } static inline wuffs_base__pixel_format // wuffs_base__pixel_config__pixel_format(const wuffs_base__pixel_config* c) { return c ? c->private_impl.pixfmt : wuffs_base__make_pixel_format(0); } static inline wuffs_base__pixel_subsampling // wuffs_base__pixel_config__pixel_subsampling(const wuffs_base__pixel_config* c) { return c ? c->private_impl.pixsub : wuffs_base__make_pixel_subsampling(0); } static inline wuffs_base__rect_ie_u32 // wuffs_base__pixel_config__bounds(const wuffs_base__pixel_config* c) { if (c) { wuffs_base__rect_ie_u32 ret; ret.min_incl_x = 0; ret.min_incl_y = 0; ret.max_excl_x = c->private_impl.width; ret.max_excl_y = c->private_impl.height; return ret; } wuffs_base__rect_ie_u32 ret; ret.min_incl_x = 0; ret.min_incl_y = 0; ret.max_excl_x = 0; ret.max_excl_y = 0; return ret; } static inline uint32_t // wuffs_base__pixel_config__width(const wuffs_base__pixel_config* c) { return c ? c->private_impl.width : 0; } static inline uint32_t // wuffs_base__pixel_config__height(const wuffs_base__pixel_config* c) { return c ? c->private_impl.height : 0; } // TODO: this is the right API for planar (not interleaved) pixbufs? Should it // allow decoding into a color model different from the format's intrinsic one? // For example, decoding a JPEG image straight to RGBA instead of to YCbCr? static inline uint64_t // wuffs_base__pixel_config__pixbuf_len(const wuffs_base__pixel_config* c) { if (!c) { return 0; } if (wuffs_base__pixel_format__is_planar(&c->private_impl.pixfmt)) { // TODO: support planar pixel formats, concious of pixel subsampling. return 0; } uint32_t bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&c->private_impl.pixfmt); if ((bits_per_pixel == 0) || ((bits_per_pixel % 8) != 0)) { // TODO: support fraction-of-byte pixels, e.g. 1 bit per pixel? return 0; } uint64_t bytes_per_pixel = bits_per_pixel / 8; uint64_t n = ((uint64_t)c->private_impl.width) * ((uint64_t)c->private_impl.height); if (n > (UINT64_MAX / bytes_per_pixel)) { return 0; } n *= bytes_per_pixel; if (wuffs_base__pixel_format__is_indexed(&c->private_impl.pixfmt)) { if (n > (UINT64_MAX - WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH)) { return 0; } n += WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; } return n; } #ifdef __cplusplus inline void // wuffs_base__pixel_config::set(uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height) { wuffs_base__pixel_config__set(this, pixfmt_repr, pixsub_repr, width, height); } inline void // wuffs_base__pixel_config::invalidate() { wuffs_base__pixel_config__invalidate(this); } inline bool // wuffs_base__pixel_config::is_valid() const { return wuffs_base__pixel_config__is_valid(this); } inline wuffs_base__pixel_format // wuffs_base__pixel_config::pixel_format() const { return wuffs_base__pixel_config__pixel_format(this); } inline wuffs_base__pixel_subsampling // wuffs_base__pixel_config::pixel_subsampling() const { return wuffs_base__pixel_config__pixel_subsampling(this); } inline wuffs_base__rect_ie_u32 // wuffs_base__pixel_config::bounds() const { return wuffs_base__pixel_config__bounds(this); } inline uint32_t // wuffs_base__pixel_config::width() const { return wuffs_base__pixel_config__width(this); } inline uint32_t // wuffs_base__pixel_config::height() const { return wuffs_base__pixel_config__height(this); } inline uint64_t // wuffs_base__pixel_config::pixbuf_len() const { return wuffs_base__pixel_config__pixbuf_len(this); } #endif // __cplusplus // -------- typedef struct wuffs_base__image_config__struct { wuffs_base__pixel_config pixcfg; // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { uint64_t first_frame_io_position; bool first_frame_is_opaque; } private_impl; #ifdef __cplusplus inline void set(uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height, uint64_t first_frame_io_position, bool first_frame_is_opaque); inline void invalidate(); inline bool is_valid() const; inline uint64_t first_frame_io_position() const; inline bool first_frame_is_opaque() const; #endif // __cplusplus } wuffs_base__image_config; static inline wuffs_base__image_config // wuffs_base__null_image_config(void) { wuffs_base__image_config ret; ret.pixcfg = wuffs_base__null_pixel_config(); ret.private_impl.first_frame_io_position = 0; ret.private_impl.first_frame_is_opaque = false; return ret; } // TODO: Should this function return bool? An error type? static inline void // wuffs_base__image_config__set(wuffs_base__image_config* c, uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height, uint64_t first_frame_io_position, bool first_frame_is_opaque) { if (!c) { return; } if (pixfmt_repr) { c->pixcfg.private_impl.pixfmt.repr = pixfmt_repr; c->pixcfg.private_impl.pixsub.repr = pixsub_repr; c->pixcfg.private_impl.width = width; c->pixcfg.private_impl.height = height; c->private_impl.first_frame_io_position = first_frame_io_position; c->private_impl.first_frame_is_opaque = first_frame_is_opaque; return; } c->pixcfg.private_impl.pixfmt.repr = 0; c->pixcfg.private_impl.pixsub.repr = 0; c->pixcfg.private_impl.width = 0; c->pixcfg.private_impl.height = 0; c->private_impl.first_frame_io_position = 0; c->private_impl.first_frame_is_opaque = 0; } static inline void // wuffs_base__image_config__invalidate(wuffs_base__image_config* c) { if (c) { c->pixcfg.private_impl.pixfmt.repr = 0; c->pixcfg.private_impl.pixsub.repr = 0; c->pixcfg.private_impl.width = 0; c->pixcfg.private_impl.height = 0; c->private_impl.first_frame_io_position = 0; c->private_impl.first_frame_is_opaque = 0; } } static inline bool // wuffs_base__image_config__is_valid(const wuffs_base__image_config* c) { return c && wuffs_base__pixel_config__is_valid(&(c->pixcfg)); } static inline uint64_t // wuffs_base__image_config__first_frame_io_position( const wuffs_base__image_config* c) { return c ? c->private_impl.first_frame_io_position : 0; } static inline bool // wuffs_base__image_config__first_frame_is_opaque( const wuffs_base__image_config* c) { return c ? c->private_impl.first_frame_is_opaque : false; } #ifdef __cplusplus inline void // wuffs_base__image_config::set(uint32_t pixfmt_repr, uint32_t pixsub_repr, uint32_t width, uint32_t height, uint64_t first_frame_io_position, bool first_frame_is_opaque) { wuffs_base__image_config__set(this, pixfmt_repr, pixsub_repr, width, height, first_frame_io_position, first_frame_is_opaque); } inline void // wuffs_base__image_config::invalidate() { wuffs_base__image_config__invalidate(this); } inline bool // wuffs_base__image_config::is_valid() const { return wuffs_base__image_config__is_valid(this); } inline uint64_t // wuffs_base__image_config::first_frame_io_position() const { return wuffs_base__image_config__first_frame_io_position(this); } inline bool // wuffs_base__image_config::first_frame_is_opaque() const { return wuffs_base__image_config__first_frame_is_opaque(this); } #endif // __cplusplus // -------- // wuffs_base__animation_disposal encodes, for an animated image, how to // dispose of a frame after displaying it: // - None means to draw the next frame on top of this one. // - Restore Background means to clear the frame's dirty rectangle to "the // background color" (in practice, this means transparent black) before // drawing the next frame. // - Restore Previous means to undo the current frame, so that the next frame // is drawn on top of the previous one. typedef uint8_t wuffs_base__animation_disposal; #define WUFFS_BASE__ANIMATION_DISPOSAL__NONE ((wuffs_base__animation_disposal)0) #define WUFFS_BASE__ANIMATION_DISPOSAL__RESTORE_BACKGROUND \ ((wuffs_base__animation_disposal)1) #define WUFFS_BASE__ANIMATION_DISPOSAL__RESTORE_PREVIOUS \ ((wuffs_base__animation_disposal)2) // -------- typedef struct wuffs_base__frame_config__struct { // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { wuffs_base__rect_ie_u32 bounds; wuffs_base__flicks duration; uint64_t index; uint64_t io_position; wuffs_base__animation_disposal disposal; bool opaque_within_bounds; bool overwrite_instead_of_blend; wuffs_base__color_u32_argb_premul background_color; } private_impl; #ifdef __cplusplus inline void set(wuffs_base__rect_ie_u32 bounds, wuffs_base__flicks duration, uint64_t index, uint64_t io_position, wuffs_base__animation_disposal disposal, bool opaque_within_bounds, bool overwrite_instead_of_blend, wuffs_base__color_u32_argb_premul background_color); inline wuffs_base__rect_ie_u32 bounds() const; inline uint32_t width() const; inline uint32_t height() const; inline wuffs_base__flicks duration() const; inline uint64_t index() const; inline uint64_t io_position() const; inline wuffs_base__animation_disposal disposal() const; inline bool opaque_within_bounds() const; inline bool overwrite_instead_of_blend() const; inline wuffs_base__color_u32_argb_premul background_color() const; #endif // __cplusplus } wuffs_base__frame_config; static inline wuffs_base__frame_config // wuffs_base__null_frame_config(void) { wuffs_base__frame_config ret; ret.private_impl.bounds = wuffs_base__make_rect_ie_u32(0, 0, 0, 0); ret.private_impl.duration = 0; ret.private_impl.index = 0; ret.private_impl.io_position = 0; ret.private_impl.disposal = 0; ret.private_impl.opaque_within_bounds = false; ret.private_impl.overwrite_instead_of_blend = false; return ret; } static inline void // wuffs_base__frame_config__set( wuffs_base__frame_config* c, wuffs_base__rect_ie_u32 bounds, wuffs_base__flicks duration, uint64_t index, uint64_t io_position, wuffs_base__animation_disposal disposal, bool opaque_within_bounds, bool overwrite_instead_of_blend, wuffs_base__color_u32_argb_premul background_color) { if (!c) { return; } c->private_impl.bounds = bounds; c->private_impl.duration = duration; c->private_impl.index = index; c->private_impl.io_position = io_position; c->private_impl.disposal = disposal; c->private_impl.opaque_within_bounds = opaque_within_bounds; c->private_impl.overwrite_instead_of_blend = overwrite_instead_of_blend; c->private_impl.background_color = background_color; } static inline wuffs_base__rect_ie_u32 // wuffs_base__frame_config__bounds(const wuffs_base__frame_config* c) { if (c) { return c->private_impl.bounds; } wuffs_base__rect_ie_u32 ret; ret.min_incl_x = 0; ret.min_incl_y = 0; ret.max_excl_x = 0; ret.max_excl_y = 0; return ret; } static inline uint32_t // wuffs_base__frame_config__width(const wuffs_base__frame_config* c) { return c ? wuffs_base__rect_ie_u32__width(&c->private_impl.bounds) : 0; } static inline uint32_t // wuffs_base__frame_config__height(const wuffs_base__frame_config* c) { return c ? wuffs_base__rect_ie_u32__height(&c->private_impl.bounds) : 0; } // wuffs_base__frame_config__duration returns the amount of time to display // this frame. Zero means to display forever - a still (non-animated) image. static inline wuffs_base__flicks // wuffs_base__frame_config__duration(const wuffs_base__frame_config* c) { return c ? c->private_impl.duration : 0; } // wuffs_base__frame_config__index returns the index of this frame. The first // frame in an image has index 0, the second frame has index 1, and so on. static inline uint64_t // wuffs_base__frame_config__index(const wuffs_base__frame_config* c) { return c ? c->private_impl.index : 0; } // wuffs_base__frame_config__io_position returns the I/O stream position before // the frame config. static inline uint64_t // wuffs_base__frame_config__io_position(const wuffs_base__frame_config* c) { return c ? c->private_impl.io_position : 0; } // wuffs_base__frame_config__disposal returns, for an animated image, how to // dispose of this frame after displaying it. static inline wuffs_base__animation_disposal // wuffs_base__frame_config__disposal(const wuffs_base__frame_config* c) { return c ? c->private_impl.disposal : 0; } // wuffs_base__frame_config__opaque_within_bounds returns whether all pixels // within the frame's bounds are fully opaque. It makes no claim about pixels // outside the frame bounds but still inside the overall image. The two // bounding rectangles can differ for animated images. // // Its semantics are conservative. It is valid for a fully opaque frame to have // this value be false: a false negative. // // If true, drawing the frame with WUFFS_BASE__PIXEL_BLEND__SRC and // WUFFS_BASE__PIXEL_BLEND__SRC_OVER should be equivalent, in terms of // resultant pixels, but the former may be faster. static inline bool // wuffs_base__frame_config__opaque_within_bounds( const wuffs_base__frame_config* c) { return c && c->private_impl.opaque_within_bounds; } // wuffs_base__frame_config__overwrite_instead_of_blend returns, for an // animated image, whether to ignore the previous image state (within the frame // bounds) when drawing this incremental frame. Equivalently, whether to use // WUFFS_BASE__PIXEL_BLEND__SRC instead of WUFFS_BASE__PIXEL_BLEND__SRC_OVER. // // The WebP spec (https://developers.google.com/speed/webp/docs/riff_container) // calls this the "Blending method" bit. WebP's "Do not blend" corresponds to // Wuffs' "overwrite_instead_of_blend". static inline bool // wuffs_base__frame_config__overwrite_instead_of_blend( const wuffs_base__frame_config* c) { return c && c->private_impl.overwrite_instead_of_blend; } static inline wuffs_base__color_u32_argb_premul // wuffs_base__frame_config__background_color(const wuffs_base__frame_config* c) { return c ? c->private_impl.background_color : 0; } #ifdef __cplusplus inline void // wuffs_base__frame_config::set( wuffs_base__rect_ie_u32 bounds, wuffs_base__flicks duration, uint64_t index, uint64_t io_position, wuffs_base__animation_disposal disposal, bool opaque_within_bounds, bool overwrite_instead_of_blend, wuffs_base__color_u32_argb_premul background_color) { wuffs_base__frame_config__set(this, bounds, duration, index, io_position, disposal, opaque_within_bounds, overwrite_instead_of_blend, background_color); } inline wuffs_base__rect_ie_u32 // wuffs_base__frame_config::bounds() const { return wuffs_base__frame_config__bounds(this); } inline uint32_t // wuffs_base__frame_config::width() const { return wuffs_base__frame_config__width(this); } inline uint32_t // wuffs_base__frame_config::height() const { return wuffs_base__frame_config__height(this); } inline wuffs_base__flicks // wuffs_base__frame_config::duration() const { return wuffs_base__frame_config__duration(this); } inline uint64_t // wuffs_base__frame_config::index() const { return wuffs_base__frame_config__index(this); } inline uint64_t // wuffs_base__frame_config::io_position() const { return wuffs_base__frame_config__io_position(this); } inline wuffs_base__animation_disposal // wuffs_base__frame_config::disposal() const { return wuffs_base__frame_config__disposal(this); } inline bool // wuffs_base__frame_config::opaque_within_bounds() const { return wuffs_base__frame_config__opaque_within_bounds(this); } inline bool // wuffs_base__frame_config::overwrite_instead_of_blend() const { return wuffs_base__frame_config__overwrite_instead_of_blend(this); } inline wuffs_base__color_u32_argb_premul // wuffs_base__frame_config::background_color() const { return wuffs_base__frame_config__background_color(this); } #endif // __cplusplus // -------- typedef struct wuffs_base__pixel_buffer__struct { wuffs_base__pixel_config pixcfg; // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { wuffs_base__table_u8 planes[WUFFS_BASE__PIXEL_FORMAT__NUM_PLANES_MAX_INCL]; // TODO: color spaces. } private_impl; #ifdef __cplusplus inline wuffs_base__status set_interleaved( const wuffs_base__pixel_config* pixcfg, wuffs_base__table_u8 primary_memory, wuffs_base__slice_u8 palette_memory); inline wuffs_base__status set_from_slice( const wuffs_base__pixel_config* pixcfg, wuffs_base__slice_u8 pixbuf_memory); inline wuffs_base__slice_u8 palette(); inline wuffs_base__slice_u8 palette_or_else(wuffs_base__slice_u8 fallback); inline wuffs_base__pixel_format pixel_format() const; inline wuffs_base__table_u8 plane(uint32_t p); inline wuffs_base__color_u32_argb_premul color_u32_at(uint32_t x, uint32_t y) const; inline wuffs_base__status set_color_u32_at( uint32_t x, uint32_t y, wuffs_base__color_u32_argb_premul color); inline wuffs_base__status set_color_u32_fill_rect( wuffs_base__rect_ie_u32 rect, wuffs_base__color_u32_argb_premul color); #endif // __cplusplus } wuffs_base__pixel_buffer; static inline wuffs_base__pixel_buffer // wuffs_base__null_pixel_buffer(void) { wuffs_base__pixel_buffer ret; ret.pixcfg = wuffs_base__null_pixel_config(); ret.private_impl.planes[0] = wuffs_base__empty_table_u8(); ret.private_impl.planes[1] = wuffs_base__empty_table_u8(); ret.private_impl.planes[2] = wuffs_base__empty_table_u8(); ret.private_impl.planes[3] = wuffs_base__empty_table_u8(); return ret; } static inline wuffs_base__status // wuffs_base__pixel_buffer__set_interleaved( wuffs_base__pixel_buffer* pb, const wuffs_base__pixel_config* pixcfg, wuffs_base__table_u8 primary_memory, wuffs_base__slice_u8 palette_memory) { if (!pb) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } memset(pb, 0, sizeof(*pb)); if (!pixcfg || wuffs_base__pixel_format__is_planar(&pixcfg->private_impl.pixfmt)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if (wuffs_base__pixel_format__is_indexed(&pixcfg->private_impl.pixfmt) && (palette_memory.len < WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH)) { return wuffs_base__make_status( wuffs_base__error__bad_argument_length_too_short); } uint32_t bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&pixcfg->private_impl.pixfmt); if ((bits_per_pixel == 0) || ((bits_per_pixel % 8) != 0)) { // TODO: support fraction-of-byte pixels, e.g. 1 bit per pixel? return wuffs_base__make_status(wuffs_base__error__unsupported_option); } uint64_t bytes_per_pixel = bits_per_pixel / 8; uint64_t width_in_bytes = ((uint64_t)pixcfg->private_impl.width) * bytes_per_pixel; if ((width_in_bytes > primary_memory.width) || (pixcfg->private_impl.height > primary_memory.height)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } pb->pixcfg = *pixcfg; pb->private_impl.planes[0] = primary_memory; if (wuffs_base__pixel_format__is_indexed(&pixcfg->private_impl.pixfmt)) { wuffs_base__table_u8* tab = &pb->private_impl .planes[WUFFS_BASE__PIXEL_FORMAT__INDEXED__COLOR_PLANE]; tab->ptr = palette_memory.ptr; tab->width = WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; tab->height = 1; tab->stride = WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; } return wuffs_base__make_status(NULL); } static inline wuffs_base__status // wuffs_base__pixel_buffer__set_from_slice(wuffs_base__pixel_buffer* pb, const wuffs_base__pixel_config* pixcfg, wuffs_base__slice_u8 pixbuf_memory) { if (!pb) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } memset(pb, 0, sizeof(*pb)); if (!pixcfg) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if (wuffs_base__pixel_format__is_planar(&pixcfg->private_impl.pixfmt)) { // TODO: support planar pixel formats, concious of pixel subsampling. return wuffs_base__make_status(wuffs_base__error__unsupported_option); } uint32_t bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&pixcfg->private_impl.pixfmt); if ((bits_per_pixel == 0) || ((bits_per_pixel % 8) != 0)) { // TODO: support fraction-of-byte pixels, e.g. 1 bit per pixel? return wuffs_base__make_status(wuffs_base__error__unsupported_option); } uint64_t bytes_per_pixel = bits_per_pixel / 8; uint8_t* ptr = pixbuf_memory.ptr; uint64_t len = pixbuf_memory.len; if (wuffs_base__pixel_format__is_indexed(&pixcfg->private_impl.pixfmt)) { // Split a WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH byte // chunk (1024 bytes = 256 palette entries × 4 bytes per entry) from the // start of pixbuf_memory. We split from the start, not the end, so that // the both chunks' pointers have the same alignment as the original // pointer, up to an alignment of 1024. if (len < WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return wuffs_base__make_status( wuffs_base__error__bad_argument_length_too_short); } wuffs_base__table_u8* tab = &pb->private_impl .planes[WUFFS_BASE__PIXEL_FORMAT__INDEXED__COLOR_PLANE]; tab->ptr = ptr; tab->width = WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; tab->height = 1; tab->stride = WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; ptr += WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; len -= WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH; } uint64_t wh = ((uint64_t)pixcfg->private_impl.width) * ((uint64_t)pixcfg->private_impl.height); size_t width = (size_t)(pixcfg->private_impl.width); if ((wh > (UINT64_MAX / bytes_per_pixel)) || (width > (SIZE_MAX / bytes_per_pixel))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } wh *= bytes_per_pixel; width = ((size_t)(width * bytes_per_pixel)); if (wh > len) { return wuffs_base__make_status( wuffs_base__error__bad_argument_length_too_short); } pb->pixcfg = *pixcfg; wuffs_base__table_u8* tab = &pb->private_impl.planes[0]; tab->ptr = ptr; tab->width = width; tab->height = pixcfg->private_impl.height; tab->stride = width; return wuffs_base__make_status(NULL); } // wuffs_base__pixel_buffer__palette returns the palette color data. If // non-empty, it will have length // WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH. static inline wuffs_base__slice_u8 // wuffs_base__pixel_buffer__palette(wuffs_base__pixel_buffer* pb) { if (pb && wuffs_base__pixel_format__is_indexed(&pb->pixcfg.private_impl.pixfmt)) { wuffs_base__table_u8* tab = &pb->private_impl .planes[WUFFS_BASE__PIXEL_FORMAT__INDEXED__COLOR_PLANE]; if ((tab->width == WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) && (tab->height == 1)) { return wuffs_base__make_slice_u8( tab->ptr, WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH); } } return wuffs_base__empty_slice_u8(); } static inline wuffs_base__slice_u8 // wuffs_base__pixel_buffer__palette_or_else(wuffs_base__pixel_buffer* pb, wuffs_base__slice_u8 fallback) { if (pb && wuffs_base__pixel_format__is_indexed(&pb->pixcfg.private_impl.pixfmt)) { wuffs_base__table_u8* tab = &pb->private_impl .planes[WUFFS_BASE__PIXEL_FORMAT__INDEXED__COLOR_PLANE]; if ((tab->width == WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) && (tab->height == 1)) { return wuffs_base__make_slice_u8( tab->ptr, WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH); } } return fallback; } static inline wuffs_base__pixel_format // wuffs_base__pixel_buffer__pixel_format(const wuffs_base__pixel_buffer* pb) { if (pb) { return pb->pixcfg.private_impl.pixfmt; } return wuffs_base__make_pixel_format(WUFFS_BASE__PIXEL_FORMAT__INVALID); } static inline wuffs_base__table_u8 // wuffs_base__pixel_buffer__plane(wuffs_base__pixel_buffer* pb, uint32_t p) { if (pb && (p < WUFFS_BASE__PIXEL_FORMAT__NUM_PLANES_MAX_INCL)) { return pb->private_impl.planes[p]; } wuffs_base__table_u8 ret; ret.ptr = NULL; ret.width = 0; ret.height = 0; ret.stride = 0; return ret; } WUFFS_BASE__MAYBE_STATIC wuffs_base__color_u32_argb_premul // wuffs_base__pixel_buffer__color_u32_at(const wuffs_base__pixel_buffer* pb, uint32_t x, uint32_t y); WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_buffer__set_color_u32_at( wuffs_base__pixel_buffer* pb, uint32_t x, uint32_t y, wuffs_base__color_u32_argb_premul color); WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_buffer__set_color_u32_fill_rect( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, wuffs_base__color_u32_argb_premul color); #ifdef __cplusplus inline wuffs_base__status // wuffs_base__pixel_buffer::set_interleaved( const wuffs_base__pixel_config* pixcfg_arg, wuffs_base__table_u8 primary_memory, wuffs_base__slice_u8 palette_memory) { return wuffs_base__pixel_buffer__set_interleaved( this, pixcfg_arg, primary_memory, palette_memory); } inline wuffs_base__status // wuffs_base__pixel_buffer::set_from_slice( const wuffs_base__pixel_config* pixcfg_arg, wuffs_base__slice_u8 pixbuf_memory) { return wuffs_base__pixel_buffer__set_from_slice(this, pixcfg_arg, pixbuf_memory); } inline wuffs_base__slice_u8 // wuffs_base__pixel_buffer::palette() { return wuffs_base__pixel_buffer__palette(this); } inline wuffs_base__slice_u8 // wuffs_base__pixel_buffer::palette_or_else(wuffs_base__slice_u8 fallback) { return wuffs_base__pixel_buffer__palette_or_else(this, fallback); } inline wuffs_base__pixel_format // wuffs_base__pixel_buffer::pixel_format() const { return wuffs_base__pixel_buffer__pixel_format(this); } inline wuffs_base__table_u8 // wuffs_base__pixel_buffer::plane(uint32_t p) { return wuffs_base__pixel_buffer__plane(this, p); } inline wuffs_base__color_u32_argb_premul // wuffs_base__pixel_buffer::color_u32_at(uint32_t x, uint32_t y) const { return wuffs_base__pixel_buffer__color_u32_at(this, x, y); } inline wuffs_base__status // wuffs_base__pixel_buffer::set_color_u32_at( uint32_t x, uint32_t y, wuffs_base__color_u32_argb_premul color) { return wuffs_base__pixel_buffer__set_color_u32_at(this, x, y, color); } inline wuffs_base__status // wuffs_base__pixel_buffer::set_color_u32_fill_rect( wuffs_base__rect_ie_u32 rect, wuffs_base__color_u32_argb_premul color) { return wuffs_base__pixel_buffer__set_color_u32_fill_rect(this, rect, color); } #endif // __cplusplus // -------- typedef struct wuffs_base__decode_frame_options__struct { // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { uint8_t TODO; } private_impl; #ifdef __cplusplus #endif // __cplusplus } wuffs_base__decode_frame_options; #ifdef __cplusplus #endif // __cplusplus // -------- // wuffs_base__pixel_palette__closest_element returns the index of the palette // element that minimizes the sum of squared differences of the four ARGB // channels, working in premultiplied alpha. Ties favor the smaller index. // // The palette_slice.len may equal (N*4), for N less than 256, which means that // only the first N palette elements are considered. It returns 0 when N is 0. // // Applying this function on a per-pixel basis will not produce whole-of-image // dithering. WUFFS_BASE__MAYBE_STATIC uint8_t // wuffs_base__pixel_palette__closest_element( wuffs_base__slice_u8 palette_slice, wuffs_base__pixel_format palette_format, wuffs_base__color_u32_argb_premul c); // -------- // TODO: should the func type take restrict pointers? typedef uint64_t (*wuffs_base__pixel_swizzler__func)(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len); typedef uint64_t (*wuffs_base__pixel_swizzler__transparent_black_func)( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, uint64_t num_pixels, uint32_t dst_pixfmt_bytes_per_pixel); typedef struct wuffs_base__pixel_swizzler__struct { // Do not access the private_impl's fields directly. There is no API/ABI // compatibility or safety guarantee if you do so. struct { wuffs_base__pixel_swizzler__func func; wuffs_base__pixel_swizzler__transparent_black_func transparent_black_func; uint32_t dst_pixfmt_bytes_per_pixel; uint32_t src_pixfmt_bytes_per_pixel; } private_impl; #ifdef __cplusplus inline wuffs_base__status prepare(wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__pixel_format src_pixfmt, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend); inline uint64_t swizzle_interleaved_from_slice( wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src) const; #endif // __cplusplus } wuffs_base__pixel_swizzler; // wuffs_base__pixel_swizzler__prepare readies the pixel swizzler so that its // other methods may be called. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__PIXCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_swizzler__prepare(wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__pixel_format src_pixfmt, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend); // wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice converts pixels // from a source format to a destination format. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__PIXCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src); #ifdef __cplusplus inline wuffs_base__status // wuffs_base__pixel_swizzler::prepare(wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__pixel_format src_pixfmt, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { return wuffs_base__pixel_swizzler__prepare(this, dst_pixfmt, dst_palette, src_pixfmt, src_palette, blend); } uint64_t // wuffs_base__pixel_swizzler::swizzle_interleaved_from_slice( wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src) const { return wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice( this, dst, dst_palette, src); } #endif // __cplusplus // ---------------- String Conversions // Options (bitwise or'ed together) for wuffs_base__parse_number_xxx // functions. The XXX options apply to both integer and floating point. The FXX // options apply only to floating point. #define WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS ((uint32_t)0x00000000) // WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_MULTIPLE_LEADING_ZEROES means to accept // inputs like "00", "0644" and "00.7". By default, they are rejected. #define WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_MULTIPLE_LEADING_ZEROES \ ((uint32_t)0x00000001) // WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES means to accept inputs like // "1__2" and "_3.141_592". By default, they are rejected. #define WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES ((uint32_t)0x00000002) // WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA means to accept // "1,5" and not "1.5" as one-and-a-half. // // If the caller wants to accept either, it is responsible for canonicalizing // the input before calling wuffs_base__parse_number_fxx. The caller also has // more context on e.g. exactly how to treat something like "$1,234". #define WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA \ ((uint32_t)0x00000010) // WUFFS_BASE__PARSE_NUMBER_FXX__REJECT_INF_AND_NAN means to reject inputs that // would lead to infinite or Not-a-Number floating point values. By default, // they are accepted. // // This affects the literal "inf" as input, but also affects inputs like // "1e999" that would overflow double-precision floating point. #define WUFFS_BASE__PARSE_NUMBER_FXX__REJECT_INF_AND_NAN ((uint32_t)0x00000020) // -------- // Options (bitwise or'ed together) for wuffs_base__render_number_xxx // functions. The XXX options apply to both integer and floating point. The FXX // options apply only to floating point. #define WUFFS_BASE__RENDER_NUMBER_XXX__DEFAULT_OPTIONS ((uint32_t)0x00000000) // WUFFS_BASE__RENDER_NUMBER_XXX__ALIGN_RIGHT means to render to the right side // (higher indexes) of the destination slice, leaving any untouched bytes on // the left side (lower indexes). The default is vice versa: rendering on the // left with slack on the right. #define WUFFS_BASE__RENDER_NUMBER_XXX__ALIGN_RIGHT ((uint32_t)0x00000100) // WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN means to render the leading // "+" for non-negative numbers: "+0" and "+12.3" instead of "0" and "12.3". #define WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN ((uint32_t)0x00000200) // WUFFS_BASE__RENDER_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA means to render // one-and-a-half as "1,5" instead of "1.5". #define WUFFS_BASE__RENDER_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA \ ((uint32_t)0x00001000) // WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_ETC means whether to never // (EXPONENT_ABSENT, equivalent to printf's "%f") or to always // (EXPONENT_PRESENT, equivalent to printf's "%e") render a floating point // number as "1.23e+05" instead of "123000". // // Having both bits set is the same has having neither bit set, where the // notation used depends on whether the exponent is sufficiently large: "0.5" // is preferred over "5e-01" but "5e-09" is preferred over "0.000000005". #define WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_ABSENT ((uint32_t)0x00002000) #define WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_PRESENT ((uint32_t)0x00004000) // WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION means to render the // smallest number of digits so that parsing the resultant string will recover // the same double-precision floating point number. // // For example, double-precision cannot distinguish between 0.3 and // 0.299999999999999988897769753748434595763683319091796875, so when this bit // is set, rendering the latter will produce "0.3" but rendering // 0.3000000000000000444089209850062616169452667236328125 will produce // "0.30000000000000004". #define WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION \ ((uint32_t)0x00008000) // ---------------- IEEE 754 Floating Point // wuffs_base__ieee_754_bit_representation__etc converts between a double // precision numerical value and its IEEE 754 representations: // - 16-bit: 1 sign bit, 5 exponent bits, 10 explicit significand bits. // - 32-bit: 1 sign bit, 8 exponent bits, 23 explicit significand bits. // - 64-bit: 1 sign bit, 11 exponent bits, 52 explicit significand bits. // // For example, it converts between: // - +1.0 and 0x3C00, 0x3F80_0000 or 0x3FF0_0000_0000_0000. // - +5.5 and 0x4580, 0x40B0_0000 or 0x4016_0000_0000_0000. // - -inf and 0xFC00, 0xFF80_0000 or 0xFFF0_0000_0000_0000. // // Converting from f64 to shorter formats (f16 or f32, represented in C as // uint16_t and uint32_t) may be lossy. Such functions have names that look // like etc_truncate, as converting finite numbers produce equal or smaller // (closer-to-zero) finite numbers. For example, 1048576.0 is a perfectly valid // f64 number, but converting it to a f16 (with truncation) produces 65504.0, // the largest finite f16 number. Truncating a f64-typed value d to f32 does // not always produce the same result as the C-style cast ((float)d), as // casting can convert from finite numbers to infinite ones. // // Converting infinities or NaNs produces infinities or NaNs and always report // no loss, even though there a multiple NaN representations so that round- // tripping a f64-typed NaN may produce a different 64 bits. Nonetheless, the // etc_truncate functions preserve a NaN's "quiet vs signaling" bit. // // See https://en.wikipedia.org/wiki/Double-precision_floating-point_format typedef struct wuffs_base__lossy_value_u16__struct { uint16_t value; bool lossy; } wuffs_base__lossy_value_u16; typedef struct wuffs_base__lossy_value_u32__struct { uint32_t value; bool lossy; } wuffs_base__lossy_value_u32; WUFFS_BASE__MAYBE_STATIC wuffs_base__lossy_value_u16 // wuffs_base__ieee_754_bit_representation__from_f64_to_u16_truncate(double f); WUFFS_BASE__MAYBE_STATIC wuffs_base__lossy_value_u32 // wuffs_base__ieee_754_bit_representation__from_f64_to_u32_truncate(double f); static inline uint64_t // wuffs_base__ieee_754_bit_representation__from_f64_to_u64(double f) { uint64_t u = 0; if (sizeof(uint64_t) == sizeof(double)) { memcpy(&u, &f, sizeof(uint64_t)); } return u; } static inline double // wuffs_base__ieee_754_bit_representation__from_u16_to_f64(uint16_t u) { uint64_t v = ((uint64_t)(u & 0x8000)) << 48; do { uint64_t exp = (u >> 10) & 0x1F; uint64_t man = u & 0x3FF; if (exp == 0x1F) { // Infinity or NaN. exp = 2047; } else if (exp != 0) { // Normal. exp += 1008; // 1008 = 1023 - 15, the difference in biases. } else if (man != 0) { // Subnormal but non-zero. uint32_t clz = wuffs_base__count_leading_zeroes_u64(man); exp = 1062 - clz; // 1062 = 1008 + 64 - 10. man = 0x3FF & (man << (clz - 53)); } else { // Zero. break; } v |= (exp << 52) | (man << 42); } while (0); double f = 0; if (sizeof(uint64_t) == sizeof(double)) { memcpy(&f, &v, sizeof(uint64_t)); } return f; } static inline double // wuffs_base__ieee_754_bit_representation__from_u32_to_f64(uint32_t u) { float f = 0; if (sizeof(uint32_t) == sizeof(float)) { memcpy(&f, &u, sizeof(uint32_t)); } return (double)f; } static inline double // wuffs_base__ieee_754_bit_representation__from_u64_to_f64(uint64_t u) { double f = 0; if (sizeof(uint64_t) == sizeof(double)) { memcpy(&f, &u, sizeof(uint64_t)); } return f; } // ---------------- Parsing and Rendering Numbers // wuffs_base__parse_number_f64 parses the floating point number in s. For // example, if s contains the bytes "1.5" then it will return the double 1.5. // // It returns an error if s does not contain a floating point number. // // It does not necessarily return an error if the conversion is lossy, e.g. if // s is "0.3", which double-precision floating point cannot represent exactly. // // Similarly, the returned value may be infinite (and no error returned) even // if s was not "inf", when the input is nominally finite but sufficiently // larger than DBL_MAX, about 1.8e+308. // // It is similar to the C standard library's strtod function, but: // - Errors are returned in-band (in a result type), not out-of-band (errno). // - It takes a slice (a pointer and length), not a NUL-terminated C string. // - It does not take an optional endptr argument. It does not allow a partial // parse: it returns an error unless all of s is consumed. // - It does not allow whitespace, leading or otherwise. // - It does not allow hexadecimal floating point numbers. // - It is not affected by i18n / l10n settings such as environment variables. // // The options argument can change these, but by default, it: // - Allows "inf", "+Infinity" and "-NAN", case insensitive. Similarly, // without an explicit opt-out, it would successfully parse "1e999" as // infinity, even though it overflows double-precision floating point. // - Rejects underscores. With an explicit opt-in, "_3.141_592" would // successfully parse as an approximation to π. // - Rejects unnecessary leading zeroes: "00", "0644" and "00.7". // - Uses a dot '1.5' instead of a comma '1,5' for the decimal separator. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__FLOATCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__result_f64 // wuffs_base__parse_number_f64(wuffs_base__slice_u8 s, uint32_t options); // wuffs_base__parse_number_i64 parses the ASCII integer in s. For example, if // s contains the bytes "-123" then it will return the int64_t -123. // // It returns an error if s does not contain an integer or if the integer // within would overflow an int64_t. // // It is similar to wuffs_base__parse_number_u64 but it returns a signed // integer, not an unsigned integer. It also allows a leading '+' or '-'. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__result_i64 // wuffs_base__parse_number_i64(wuffs_base__slice_u8 s, uint32_t options); // wuffs_base__parse_number_u64 parses the ASCII integer in s. For example, if // s contains the bytes "123" then it will return the uint64_t 123. // // It returns an error if s does not contain an integer or if the integer // within would overflow a uint64_t. // // It is similar to the C standard library's strtoull function, but: // - Errors are returned in-band (in a result type), not out-of-band (errno). // - It takes a slice (a pointer and length), not a NUL-terminated C string. // - It does not take an optional endptr argument. It does not allow a partial // parse: it returns an error unless all of s is consumed. // - It does not allow whitespace, leading or otherwise. // - It does not allow a leading '+' or '-'. // - It does not take a base argument (e.g. base 10 vs base 16). Instead, it // always accepts both decimal (e.g "1234", "0d5678") and hexadecimal (e.g. // "0x9aBC"). The caller is responsible for prior filtering of e.g. hex // numbers if they are unwanted. For example, Wuffs' JSON decoder will only // produce a wuffs_base__token for decimal numbers, not hexadecimal. // - It is not affected by i18n / l10n settings such as environment variables. // // The options argument can change these, but by default, it: // - Rejects underscores. With an explicit opt-in, "__0D_1_002" would // successfully parse as "one thousand and two". Underscores are still // rejected inside the optional 2-byte opening "0d" or "0X" that denotes // base-10 or base-16. // - Rejects unnecessary leading zeroes: "00" and "0644". // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__result_u64 // wuffs_base__parse_number_u64(wuffs_base__slice_u8 s, uint32_t options); // -------- // WUFFS_BASE__I64__BYTE_LENGTH__MAX_INCL is the string length of // "-9223372036854775808" and "+9223372036854775807", INT64_MIN and INT64_MAX. #define WUFFS_BASE__I64__BYTE_LENGTH__MAX_INCL 20 // WUFFS_BASE__U64__BYTE_LENGTH__MAX_INCL is the string length of // "+18446744073709551615", UINT64_MAX. #define WUFFS_BASE__U64__BYTE_LENGTH__MAX_INCL 21 // wuffs_base__render_number_f64 writes the decimal encoding of x to dst and // returns the number of bytes written. If dst is shorter than the entire // encoding, it returns 0 (and no bytes are written). // // For those familiar with C's printf or Go's fmt.Printf functions: // - "%e" means the WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_PRESENT option. // - "%f" means the WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_ABSENT option. // - "%g" means neither or both bits are set. // // The precision argument controls the number of digits rendered, excluding the // exponent (the "e+05" in "1.23e+05"): // - for "%e" and "%f" it is the number of digits after the decimal separator, // - for "%g" it is the number of significant digits (and trailing zeroes are // removed). // // A precision of 6 gives similar output to printf's defaults. // // A precision greater than 4095 is equivalent to 4095. // // The precision argument is ignored when the // WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION option is set. This is // similar to Go's strconv.FormatFloat with a negative (i.e. non-sensical) // precision, but there is no corresponding feature in C's printf. // // Extreme values of x will be rendered as "NaN", "Inf" (or "+Inf" if the // WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN option is set) or "-Inf". // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__FLOATCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_f64(wuffs_base__slice_u8 dst, double x, uint32_t precision, uint32_t options); // wuffs_base__render_number_i64 writes the decimal encoding of x to dst and // returns the number of bytes written. If dst is shorter than the entire // encoding, it returns 0 (and no bytes are written). // // dst will never be too short if its length is at least 20, also known as // WUFFS_BASE__I64__BYTE_LENGTH__MAX_INCL. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_i64(wuffs_base__slice_u8 dst, int64_t x, uint32_t options); // wuffs_base__render_number_u64 writes the decimal encoding of x to dst and // returns the number of bytes written. If dst is shorter than the entire // encoding, it returns 0 (and no bytes are written). // // dst will never be too short if its length is at least 21, also known as // WUFFS_BASE__U64__BYTE_LENGTH__MAX_INCL. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_u64(wuffs_base__slice_u8 dst, uint64_t x, uint32_t options); // ---------------- Base-16 // Options (bitwise or'ed together) for wuffs_base__base_16__xxx functions. #define WUFFS_BASE__BASE_16__DEFAULT_OPTIONS ((uint32_t)0x00000000) // wuffs_base__base_16__decode2 converts "6A6b" to "jk", where e.g. 'j' is // U+006A. There are 2 src bytes for every dst byte. // // It assumes that the src bytes are two hexadecimal digits (0-9, A-F, a-f), // repeated. It may write nonsense bytes if not, although it will not read or // write out of bounds. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__decode2(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // wuffs_base__base_16__decode4 converts both "\\x6A\\x6b" and "??6a??6B" to // "jk", where e.g. 'j' is U+006A. There are 4 src bytes for every dst byte. // // It assumes that the src bytes are two ignored bytes and then two hexadecimal // digits (0-9, A-F, a-f), repeated. It may write nonsense bytes if not, // although it will not read or write out of bounds. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__decode4(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // wuffs_base__base_16__encode2 converts "jk" to "6A6B", where e.g. 'j' is // U+006A. There are 2 dst bytes for every src byte. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__encode2(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // wuffs_base__base_16__encode4 converts "jk" to "\\x6A\\x6B", where e.g. 'j' // is U+006A. There are 4 dst bytes for every src byte. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__encode4(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // ---------------- Base-64 // Options (bitwise or'ed together) for wuffs_base__base_64__xxx functions. #define WUFFS_BASE__BASE_64__DEFAULT_OPTIONS ((uint32_t)0x00000000) // WUFFS_BASE__BASE_64__DECODE_ALLOW_PADDING means that, when decoding base-64, // the input may (but does not need to) be padded with '=' bytes so that the // overall encoded length in bytes is a multiple of 4. A successful decoding // will return a num_src that includes those padding bytes. // // Excess padding (e.g. three final '='s) will be rejected as bad data. #define WUFFS_BASE__BASE_64__DECODE_ALLOW_PADDING ((uint32_t)0x00000001) // WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING means that, when encoding base-64, // the output will be padded with '=' bytes so that the overall encoded length // in bytes is a multiple of 4. #define WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING ((uint32_t)0x00000002) // WUFFS_BASE__BASE_64__URL_ALPHABET means that, for base-64, the URL-friendly // and file-name-friendly alphabet be used, as per RFC 4648 section 5. When // this option bit is off, the standard alphabet from section 4 is used. #define WUFFS_BASE__BASE_64__URL_ALPHABET ((uint32_t)0x00000100) // wuffs_base__base_64__decode transforms base-64 encoded bytes from src to // arbitrary bytes in dst. // // It will not permit line breaks or other whitespace in src. Filtering those // out is the responsibility of the caller. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_64__decode(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // wuffs_base__base_64__encode transforms arbitrary bytes from src to base-64 // encoded bytes in dst. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__INTCONV sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_64__encode(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options); // ---------------- Unicode and UTF-8 #define WUFFS_BASE__UNICODE_CODE_POINT__MIN_INCL 0x00000000 #define WUFFS_BASE__UNICODE_CODE_POINT__MAX_INCL 0x0010FFFF #define WUFFS_BASE__UNICODE_REPLACEMENT_CHARACTER 0x0000FFFD #define WUFFS_BASE__UNICODE_SURROGATE__MIN_INCL 0x0000D800 #define WUFFS_BASE__UNICODE_SURROGATE__MAX_INCL 0x0000DFFF #define WUFFS_BASE__ASCII__MIN_INCL 0x00 #define WUFFS_BASE__ASCII__MAX_INCL 0x7F #define WUFFS_BASE__UTF_8__BYTE_LENGTH__MIN_INCL 1 #define WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL 4 #define WUFFS_BASE__UTF_8__BYTE_LENGTH_1__CODE_POINT__MIN_INCL 0x00000000 #define WUFFS_BASE__UTF_8__BYTE_LENGTH_1__CODE_POINT__MAX_INCL 0x0000007F #define WUFFS_BASE__UTF_8__BYTE_LENGTH_2__CODE_POINT__MIN_INCL 0x00000080 #define WUFFS_BASE__UTF_8__BYTE_LENGTH_2__CODE_POINT__MAX_INCL 0x000007FF #define WUFFS_BASE__UTF_8__BYTE_LENGTH_3__CODE_POINT__MIN_INCL 0x00000800 #define WUFFS_BASE__UTF_8__BYTE_LENGTH_3__CODE_POINT__MAX_INCL 0x0000FFFF #define WUFFS_BASE__UTF_8__BYTE_LENGTH_4__CODE_POINT__MIN_INCL 0x00010000 #define WUFFS_BASE__UTF_8__BYTE_LENGTH_4__CODE_POINT__MAX_INCL 0x0010FFFF // -------- // wuffs_base__utf_8__next__output is the type returned by // wuffs_base__utf_8__next. typedef struct wuffs_base__utf_8__next__output__struct { uint32_t code_point; uint32_t byte_length; #ifdef __cplusplus inline bool is_valid() const; #endif // __cplusplus } wuffs_base__utf_8__next__output; static inline wuffs_base__utf_8__next__output // wuffs_base__make_utf_8__next__output(uint32_t code_point, uint32_t byte_length) { wuffs_base__utf_8__next__output ret; ret.code_point = code_point; ret.byte_length = byte_length; return ret; } static inline bool // wuffs_base__utf_8__next__output__is_valid( const wuffs_base__utf_8__next__output* o) { if (o) { uint32_t cp = o->code_point; switch (o->byte_length) { case 1: return (cp <= 0x7F); case 2: return (0x080 <= cp) && (cp <= 0x7FF); case 3: // Avoid the 0xD800 ..= 0xDFFF surrogate range. return ((0x0800 <= cp) && (cp <= 0xD7FF)) || ((0xE000 <= cp) && (cp <= 0xFFFF)); case 4: return (0x00010000 <= cp) && (cp <= 0x0010FFFF); } } return false; } #ifdef __cplusplus inline bool // wuffs_base__utf_8__next__output::is_valid() const { return wuffs_base__utf_8__next__output__is_valid(this); } #endif // __cplusplus // -------- // wuffs_base__utf_8__encode writes the UTF-8 encoding of code_point to s and // returns the number of bytes written. If code_point is invalid, or if s is // shorter than the entire encoding, it returns 0 (and no bytes are written). // // s will never be too short if its length is at least 4, also known as // WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__UTF8 sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__utf_8__encode(wuffs_base__slice_u8 dst, uint32_t code_point); // wuffs_base__utf_8__next returns the next UTF-8 code point (and that code // point's byte length) at the start of the read-only slice (s_ptr, s_len). // // There are exactly two cases in which this function returns something where // wuffs_base__utf_8__next__output__is_valid is false: // - If s is empty then it returns {.code_point=0, .byte_length=0}. // - If s is non-empty and starts with invalid UTF-8 then it returns // {.code_point=WUFFS_BASE__UNICODE_REPLACEMENT_CHARACTER, .byte_length=1}. // // Otherwise, it returns something where // wuffs_base__utf_8__next__output__is_valid is true. // // In any case, it always returns an output that satisfies both of: // - (output.code_point <= WUFFS_BASE__UNICODE_CODE_POINT__MAX_INCL). // - (output.byte_length <= s_len). // // If s is a sub-slice of a larger slice of valid UTF-8, but that sub-slice // boundary occurs in the middle of a multi-byte UTF-8 encoding of a single // code point, then this function may return something invalid. It is the // caller's responsibility to split on or otherwise manage UTF-8 boundaries. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__UTF8 sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__utf_8__next__output // wuffs_base__utf_8__next(const uint8_t* s_ptr, size_t s_len); // wuffs_base__utf_8__next_from_end is like wuffs_base__utf_8__next except that // it looks at the end of (s_ptr, s_len) instead of the start. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__UTF8 sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC wuffs_base__utf_8__next__output // wuffs_base__utf_8__next_from_end(const uint8_t* s_ptr, size_t s_len); // wuffs_base__utf_8__longest_valid_prefix returns the largest n such that the // sub-slice s[..n] is valid UTF-8, where s is the read-only slice (s_ptr, // s_len). // // In particular, it returns s_len if and only if all of s is valid UTF-8. // // If s is a sub-slice of a larger slice of valid UTF-8, but that sub-slice // boundary occurs in the middle of a multi-byte UTF-8 encoding of a single // code point, then this function will return less than s_len. It is the // caller's responsibility to split on or otherwise manage UTF-8 boundaries. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__UTF8 sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__utf_8__longest_valid_prefix(const uint8_t* s_ptr, size_t s_len); // wuffs_base__ascii__longest_valid_prefix returns the largest n such that the // sub-slice s[..n] is valid ASCII, where s is the read-only slice (s_ptr, // s_len). // // In particular, it returns s_len if and only if all of s is valid ASCII. // Equivalently, when none of the bytes in s have the 0x80 high bit set. // // For modular builds that divide the base module into sub-modules, using this // function requires the WUFFS_CONFIG__MODULE__BASE__UTF8 sub-module, not just // WUFFS_CONFIG__MODULE__BASE__CORE. WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__ascii__longest_valid_prefix(const uint8_t* s_ptr, size_t s_len); // ---------------- Interface Declarations. // For modular builds that divide the base module into sub-modules, using these // functions require the WUFFS_CONFIG__MODULE__BASE__INTERFACES sub-module, not // just WUFFS_CONFIG__MODULE__BASE__CORE. // -------- extern const char wuffs_base__hasher_u32__vtable_name[]; typedef struct wuffs_base__hasher_u32__func_ptrs__struct { uint32_t (*checksum_u32)( const void* self); uint64_t (*get_quirk)( const void* self, uint32_t a_key); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__empty_struct (*update)( void* self, wuffs_base__slice_u8 a_x); uint32_t (*update_u32)( void* self, wuffs_base__slice_u8 a_x); } wuffs_base__hasher_u32__func_ptrs; typedef struct wuffs_base__hasher_u32__struct wuffs_base__hasher_u32; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__hasher_u32__checksum_u32( const wuffs_base__hasher_u32* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u32__get_quirk( const wuffs_base__hasher_u32* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_u32__set_quirk( wuffs_base__hasher_u32* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_u32__update( wuffs_base__hasher_u32* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__hasher_u32__update_u32( wuffs_base__hasher_u32* self, wuffs_base__slice_u8 a_x); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__hasher_u32__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline uint32_t checksum_u32() const { return wuffs_base__hasher_u32__checksum_u32(this); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__hasher_u32__get_quirk( this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__hasher_u32__set_quirk( this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_u32__update( this, a_x); } inline uint32_t update_u32( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_u32__update_u32( this, a_x); } #endif // __cplusplus }; // struct wuffs_base__hasher_u32__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // -------- extern const char wuffs_base__hasher_u64__vtable_name[]; typedef struct wuffs_base__hasher_u64__func_ptrs__struct { uint64_t (*checksum_u64)( const void* self); uint64_t (*get_quirk)( const void* self, uint32_t a_key); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__empty_struct (*update)( void* self, wuffs_base__slice_u8 a_x); uint64_t (*update_u64)( void* self, wuffs_base__slice_u8 a_x); } wuffs_base__hasher_u64__func_ptrs; typedef struct wuffs_base__hasher_u64__struct wuffs_base__hasher_u64; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__checksum_u64( const wuffs_base__hasher_u64* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__get_quirk( const wuffs_base__hasher_u64* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_u64__set_quirk( wuffs_base__hasher_u64* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_u64__update( wuffs_base__hasher_u64* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__update_u64( wuffs_base__hasher_u64* self, wuffs_base__slice_u8 a_x); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__hasher_u64__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline uint64_t checksum_u64() const { return wuffs_base__hasher_u64__checksum_u64(this); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__hasher_u64__get_quirk( this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__hasher_u64__set_quirk( this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_u64__update( this, a_x); } inline uint64_t update_u64( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_u64__update_u64( this, a_x); } #endif // __cplusplus }; // struct wuffs_base__hasher_u64__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // -------- extern const char wuffs_base__hasher_bitvec256__vtable_name[]; typedef struct wuffs_base__hasher_bitvec256__func_ptrs__struct { wuffs_base__bitvec256 (*checksum_bitvec256)( const void* self); uint64_t (*get_quirk)( const void* self, uint32_t a_key); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__empty_struct (*update)( void* self, wuffs_base__slice_u8 a_x); wuffs_base__bitvec256 (*update_bitvec256)( void* self, wuffs_base__slice_u8 a_x); } wuffs_base__hasher_bitvec256__func_ptrs; typedef struct wuffs_base__hasher_bitvec256__struct wuffs_base__hasher_bitvec256; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_base__hasher_bitvec256__checksum_bitvec256( const wuffs_base__hasher_bitvec256* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_bitvec256__get_quirk( const wuffs_base__hasher_bitvec256* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_bitvec256__set_quirk( wuffs_base__hasher_bitvec256* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_bitvec256__update( wuffs_base__hasher_bitvec256* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_base__hasher_bitvec256__update_bitvec256( wuffs_base__hasher_bitvec256* self, wuffs_base__slice_u8 a_x); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__hasher_bitvec256__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline wuffs_base__bitvec256 checksum_bitvec256() const { return wuffs_base__hasher_bitvec256__checksum_bitvec256(this); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__hasher_bitvec256__get_quirk( this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__hasher_bitvec256__set_quirk( this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_bitvec256__update( this, a_x); } inline wuffs_base__bitvec256 update_bitvec256( wuffs_base__slice_u8 a_x) { return wuffs_base__hasher_bitvec256__update_bitvec256( this, a_x); } #endif // __cplusplus }; // struct wuffs_base__hasher_bitvec256__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // -------- extern const char wuffs_base__image_decoder__vtable_name[]; typedef struct wuffs_base__image_decoder__func_ptrs__struct { wuffs_base__status (*decode_frame)( void* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); wuffs_base__status (*decode_frame_config)( void* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); wuffs_base__status (*decode_image_config)( void* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); wuffs_base__rect_ie_u32 (*frame_dirty_rect)( const void* self); uint64_t (*get_quirk)( const void* self, uint32_t a_key); uint32_t (*num_animation_loops)( const void* self); uint64_t (*num_decoded_frame_configs)( const void* self); uint64_t (*num_decoded_frames)( const void* self); wuffs_base__status (*restart_frame)( void* self, uint64_t a_index, uint64_t a_io_position); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__empty_struct (*set_report_metadata)( void* self, uint32_t a_fourcc, bool a_report); wuffs_base__status (*tell_me_more)( void* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); wuffs_base__range_ii_u64 (*workbuf_len)( const void* self); } wuffs_base__image_decoder__func_ptrs; typedef struct wuffs_base__image_decoder__struct wuffs_base__image_decoder; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_frame( wuffs_base__image_decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_frame_config( wuffs_base__image_decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_image_config( wuffs_base__image_decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_base__image_decoder__frame_dirty_rect( const wuffs_base__image_decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__get_quirk( const wuffs_base__image_decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__image_decoder__num_animation_loops( const wuffs_base__image_decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__num_decoded_frame_configs( const wuffs_base__image_decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__num_decoded_frames( const wuffs_base__image_decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__restart_frame( wuffs_base__image_decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__set_quirk( wuffs_base__image_decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__image_decoder__set_report_metadata( wuffs_base__image_decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__tell_me_more( wuffs_base__image_decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__image_decoder__workbuf_len( const wuffs_base__image_decoder* self); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__image_decoder__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_base__image_decoder__decode_frame( this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_base__image_decoder__decode_frame_config( this, a_dst, a_src); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_base__image_decoder__decode_image_config( this, a_dst, a_src); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_base__image_decoder__frame_dirty_rect(this); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__image_decoder__get_quirk( this, a_key); } inline uint32_t num_animation_loops() const { return wuffs_base__image_decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_base__image_decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_base__image_decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_base__image_decoder__restart_frame( this, a_index, a_io_position); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__image_decoder__set_quirk( this, a_key, a_value); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_base__image_decoder__set_report_metadata( this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_base__image_decoder__tell_me_more( this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_base__image_decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_base__image_decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // -------- extern const char wuffs_base__io_transformer__vtable_name[]; typedef struct wuffs_base__io_transformer__func_ptrs__struct { wuffs_base__optional_u63 (*dst_history_retain_length)( const void* self); uint64_t (*get_quirk)( const void* self, uint32_t a_key); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__status (*transform_io)( void* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); wuffs_base__range_ii_u64 (*workbuf_len)( const void* self); } wuffs_base__io_transformer__func_ptrs; typedef struct wuffs_base__io_transformer__struct wuffs_base__io_transformer; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_base__io_transformer__dst_history_retain_length( const wuffs_base__io_transformer* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__io_transformer__get_quirk( const wuffs_base__io_transformer* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__io_transformer__set_quirk( wuffs_base__io_transformer* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__io_transformer__transform_io( wuffs_base__io_transformer* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__io_transformer__workbuf_len( const wuffs_base__io_transformer* self); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__io_transformer__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_base__io_transformer__dst_history_retain_length(this); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__io_transformer__get_quirk( this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__io_transformer__set_quirk( this, a_key, a_value); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_base__io_transformer__transform_io( this, a_dst, a_src, a_workbuf); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_base__io_transformer__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_base__io_transformer__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // -------- extern const char wuffs_base__token_decoder__vtable_name[]; typedef struct wuffs_base__token_decoder__func_ptrs__struct { wuffs_base__status (*decode_tokens)( void* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); uint64_t (*get_quirk)( const void* self, uint32_t a_key); wuffs_base__status (*set_quirk)( void* self, uint32_t a_key, uint64_t a_value); wuffs_base__range_ii_u64 (*workbuf_len)( const void* self); } wuffs_base__token_decoder__func_ptrs; typedef struct wuffs_base__token_decoder__struct wuffs_base__token_decoder; WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__token_decoder__decode_tokens( wuffs_base__token_decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__token_decoder__get_quirk( const wuffs_base__token_decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__token_decoder__set_quirk( wuffs_base__token_decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__token_decoder__workbuf_len( const wuffs_base__token_decoder* self); #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_base__token_decoder__struct { struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable first_vtable; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; #endif inline wuffs_base__status decode_tokens( wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_base__token_decoder__decode_tokens( this, a_dst, a_src, a_workbuf); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_base__token_decoder__get_quirk( this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_base__token_decoder__set_quirk( this, a_key, a_value); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_base__token_decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_base__token_decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) // ---------------- #ifdef __cplusplus } // extern "C" #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ADLER32) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_adler32__hasher__struct wuffs_adler32__hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_adler32__hasher__initialize( wuffs_adler32__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_adler32__hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_adler32__hasher* wuffs_adler32__hasher__alloc(void); static inline wuffs_base__hasher_u32* wuffs_adler32__hasher__alloc_as__wuffs_base__hasher_u32(void) { return (wuffs_base__hasher_u32*)(wuffs_adler32__hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_u32* wuffs_adler32__hasher__upcast_as__wuffs_base__hasher_u32( wuffs_adler32__hasher* p) { return (wuffs_base__hasher_u32*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_adler32__hasher__get_quirk( const wuffs_adler32__hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_adler32__hasher__set_quirk( wuffs_adler32__hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_adler32__hasher__update( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_adler32__hasher__update_u32( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_adler32__hasher__checksum_u32( const wuffs_adler32__hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_adler32__hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_u32; wuffs_base__vtable null_vtable; uint32_t f_state; bool f_started; wuffs_base__empty_struct (*choosy_up)( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_adler32__hasher__alloc()); } static inline wuffs_base__hasher_u32::unique_ptr alloc_as__wuffs_base__hasher_u32() { return wuffs_base__hasher_u32::unique_ptr( wuffs_adler32__hasher__alloc_as__wuffs_base__hasher_u32()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_adler32__hasher__struct() = delete; wuffs_adler32__hasher__struct(const wuffs_adler32__hasher__struct&) = delete; wuffs_adler32__hasher__struct& operator=( const wuffs_adler32__hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_adler32__hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_u32* upcast_as__wuffs_base__hasher_u32() { return (wuffs_base__hasher_u32*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_adler32__hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_adler32__hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_adler32__hasher__update(this, a_x); } inline uint32_t update_u32( wuffs_base__slice_u8 a_x) { return wuffs_adler32__hasher__update_u32(this, a_x); } inline uint32_t checksum_u32() const { return wuffs_adler32__hasher__checksum_u32(this); } #endif // __cplusplus }; // struct wuffs_adler32__hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ADLER32) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BMP) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_bmp__error__bad_header[]; extern const char wuffs_bmp__error__bad_rle_compression[]; extern const char wuffs_bmp__error__truncated_input[]; extern const char wuffs_bmp__error__unsupported_bmp_file[]; // ---------------- Public Consts #define WUFFS_BMP__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_bmp__decoder__struct wuffs_bmp__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_bmp__decoder__initialize( wuffs_bmp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_bmp__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_bmp__decoder* wuffs_bmp__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_bmp__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_bmp__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_bmp__decoder__upcast_as__wuffs_base__image_decoder( wuffs_bmp__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__get_quirk( const wuffs_bmp__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__set_quirk( wuffs_bmp__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_image_config( wuffs_bmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_frame_config( wuffs_bmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_frame( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_bmp__decoder__frame_dirty_rect( const wuffs_bmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_bmp__decoder__num_animation_loops( const wuffs_bmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__num_decoded_frame_configs( const wuffs_bmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__num_decoded_frames( const wuffs_bmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__restart_frame( wuffs_bmp__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_bmp__decoder__set_report_metadata( wuffs_bmp__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__tell_me_more( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_bmp__decoder__workbuf_len( const wuffs_bmp__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_bmp__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; bool f_top_down; uint32_t f_pad_per_row; uint32_t f_src_pixfmt; uint32_t f_io_redirect_fourcc; uint64_t f_io_redirect_pos; uint64_t f_frame_config_io_position; uint32_t f_bitmap_info_len; uint32_t f_padding; uint32_t f_bits_per_pixel; uint32_t f_compression; uint32_t f_channel_masks[4]; uint8_t f_channel_shifts[4]; uint8_t f_channel_num_bits[4]; uint32_t f_dst_x; uint32_t f_dst_y; uint32_t f_dst_y_inc; uint32_t f_pending_pad; uint32_t f_rle_state; uint32_t f_rle_length; uint8_t f_rle_delta_x; bool f_rle_padded; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_tell_me_more; uint32_t p_read_palette; } private_impl; struct { uint8_t f_scratch[2048]; uint8_t f_src_palette[1024]; struct { uint64_t scratch; } s_do_decode_image_config; struct { uint64_t scratch; } s_do_decode_frame; struct { uint32_t v_i; uint64_t scratch; } s_read_palette; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_bmp__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_bmp__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_bmp__decoder__struct() = delete; wuffs_bmp__decoder__struct(const wuffs_bmp__decoder__struct&) = delete; wuffs_bmp__decoder__struct& operator=( const wuffs_bmp__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_bmp__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_bmp__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_bmp__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_bmp__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_bmp__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_bmp__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_bmp__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_bmp__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_bmp__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_bmp__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_bmp__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_bmp__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_bmp__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_bmp__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_bmp__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BMP) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BZIP2) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_bzip2__error__bad_huffman_code_over_subscribed[]; extern const char wuffs_bzip2__error__bad_huffman_code_under_subscribed[]; extern const char wuffs_bzip2__error__bad_block_header[]; extern const char wuffs_bzip2__error__bad_block_length[]; extern const char wuffs_bzip2__error__bad_checksum[]; extern const char wuffs_bzip2__error__bad_header[]; extern const char wuffs_bzip2__error__bad_number_of_sections[]; extern const char wuffs_bzip2__error__truncated_input[]; extern const char wuffs_bzip2__error__unsupported_block_randomization[]; // ---------------- Public Consts #define WUFFS_BZIP2__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_BZIP2__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_bzip2__decoder__struct wuffs_bzip2__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_bzip2__decoder__initialize( wuffs_bzip2__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_bzip2__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_bzip2__decoder* wuffs_bzip2__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_bzip2__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_bzip2__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_bzip2__decoder__upcast_as__wuffs_base__io_transformer( wuffs_bzip2__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bzip2__decoder__get_quirk( const wuffs_bzip2__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bzip2__decoder__set_quirk( wuffs_bzip2__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_bzip2__decoder__dst_history_retain_length( const wuffs_bzip2__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_bzip2__decoder__workbuf_len( const wuffs_bzip2__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bzip2__decoder__transform_io( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_bzip2__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; uint32_t f_bits; uint32_t f_n_bits; uint32_t f_max_incl_block_size; uint32_t f_block_size; bool f_decode_huffman_finished; uint8_t f_decode_huffman_which; uint32_t f_decode_huffman_ticks; uint32_t f_decode_huffman_section; uint32_t f_decode_huffman_run_shift; uint32_t f_flush_pointer; uint32_t f_flush_repeat_count; uint8_t f_flush_prev; bool f_ignore_checksum; uint32_t f_final_checksum_have; uint32_t f_block_checksum_have; uint32_t f_block_checksum_want; uint32_t f_original_pointer; uint32_t f_num_symbols; uint32_t f_num_huffman_codes; uint32_t f_num_sections; uint32_t f_code_lengths_bitmask; uint32_t p_transform_io; uint32_t p_do_transform_io; uint32_t p_prepare_block; uint32_t p_read_code_lengths; uint32_t p_flush_slow; uint32_t p_decode_huffman_slow; } private_impl; struct { uint32_t f_scratch; uint32_t f_letter_counts[256]; uint8_t f_presence[256]; uint8_t f_mtft[256]; uint8_t f_huffman_selectors[32768]; uint16_t f_huffman_trees[6][257][2]; uint16_t f_huffman_tables[6][256]; uint32_t f_bwt[1048576]; struct { uint32_t v_i; uint64_t v_tag; uint32_t v_final_checksum_want; } s_do_transform_io; struct { uint32_t v_i; uint32_t v_selector; } s_prepare_block; struct { uint32_t v_i; uint32_t v_code_length; } s_read_code_lengths; struct { uint32_t v_flush_pointer; uint32_t v_flush_repeat_count; uint8_t v_flush_prev; uint32_t v_block_checksum_have; uint32_t v_block_size; uint8_t v_curr; uint64_t scratch; } s_flush_slow; struct { uint32_t v_node_index; } s_decode_huffman_slow; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_bzip2__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_bzip2__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_bzip2__decoder__struct() = delete; wuffs_bzip2__decoder__struct(const wuffs_bzip2__decoder__struct&) = delete; wuffs_bzip2__decoder__struct& operator=( const wuffs_bzip2__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_bzip2__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_bzip2__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_bzip2__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_bzip2__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_bzip2__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_bzip2__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_bzip2__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BZIP2) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CBOR) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_cbor__error__bad_input[]; extern const char wuffs_cbor__error__unsupported_recursion_depth[]; // ---------------- Public Consts #define WUFFS_CBOR__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u #define WUFFS_CBOR__DECODER_DEPTH_MAX_INCL 1024u #define WUFFS_CBOR__DECODER_DST_TOKEN_BUFFER_LENGTH_MIN_INCL 2u #define WUFFS_CBOR__DECODER_SRC_IO_BUFFER_LENGTH_MIN_INCL 9u #define WUFFS_CBOR__TOKEN_VALUE_MAJOR 787997u #define WUFFS_CBOR__TOKEN_VALUE_MINOR__DETAIL_MASK 262143u #define WUFFS_CBOR__TOKEN_VALUE_MINOR__MINUS_1_MINUS_X 16777216u #define WUFFS_CBOR__TOKEN_VALUE_MINOR__SIMPLE_VALUE 8388608u #define WUFFS_CBOR__TOKEN_VALUE_MINOR__TAG 4194304u // ---------------- Struct Declarations typedef struct wuffs_cbor__decoder__struct wuffs_cbor__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_cbor__decoder__initialize( wuffs_cbor__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_cbor__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_cbor__decoder* wuffs_cbor__decoder__alloc(void); static inline wuffs_base__token_decoder* wuffs_cbor__decoder__alloc_as__wuffs_base__token_decoder(void) { return (wuffs_base__token_decoder*)(wuffs_cbor__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__token_decoder* wuffs_cbor__decoder__upcast_as__wuffs_base__token_decoder( wuffs_cbor__decoder* p) { return (wuffs_base__token_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_cbor__decoder__get_quirk( const wuffs_cbor__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_cbor__decoder__set_quirk( wuffs_cbor__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_cbor__decoder__workbuf_len( const wuffs_cbor__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_cbor__decoder__decode_tokens( wuffs_cbor__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_cbor__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__token_decoder; wuffs_base__vtable null_vtable; bool f_end_of_data; uint32_t p_decode_tokens; } private_impl; struct { uint32_t f_stack[64]; uint64_t f_container_num_remaining[1024]; struct { uint64_t v_string_length; uint32_t v_depth; bool v_tagged; uint8_t v_indefinite_string_major_type; } s_decode_tokens; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_cbor__decoder__alloc()); } static inline wuffs_base__token_decoder::unique_ptr alloc_as__wuffs_base__token_decoder() { return wuffs_base__token_decoder::unique_ptr( wuffs_cbor__decoder__alloc_as__wuffs_base__token_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_cbor__decoder__struct() = delete; wuffs_cbor__decoder__struct(const wuffs_cbor__decoder__struct&) = delete; wuffs_cbor__decoder__struct& operator=( const wuffs_cbor__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_cbor__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__token_decoder* upcast_as__wuffs_base__token_decoder() { return (wuffs_base__token_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_cbor__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_cbor__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_cbor__decoder__workbuf_len(this); } inline wuffs_base__status decode_tokens( wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_cbor__decoder__decode_tokens(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_cbor__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CBOR) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC32) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_crc32__ieee_hasher__struct wuffs_crc32__ieee_hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_crc32__ieee_hasher__initialize( wuffs_crc32__ieee_hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_crc32__ieee_hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_crc32__ieee_hasher* wuffs_crc32__ieee_hasher__alloc(void); static inline wuffs_base__hasher_u32* wuffs_crc32__ieee_hasher__alloc_as__wuffs_base__hasher_u32(void) { return (wuffs_base__hasher_u32*)(wuffs_crc32__ieee_hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_u32* wuffs_crc32__ieee_hasher__upcast_as__wuffs_base__hasher_u32( wuffs_crc32__ieee_hasher* p) { return (wuffs_base__hasher_u32*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc32__ieee_hasher__get_quirk( const wuffs_crc32__ieee_hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_crc32__ieee_hasher__set_quirk( wuffs_crc32__ieee_hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_crc32__ieee_hasher__update( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_crc32__ieee_hasher__update_u32( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_crc32__ieee_hasher__checksum_u32( const wuffs_crc32__ieee_hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_crc32__ieee_hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_u32; wuffs_base__vtable null_vtable; uint32_t f_state; wuffs_base__empty_struct (*choosy_up)( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_crc32__ieee_hasher__alloc()); } static inline wuffs_base__hasher_u32::unique_ptr alloc_as__wuffs_base__hasher_u32() { return wuffs_base__hasher_u32::unique_ptr( wuffs_crc32__ieee_hasher__alloc_as__wuffs_base__hasher_u32()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_crc32__ieee_hasher__struct() = delete; wuffs_crc32__ieee_hasher__struct(const wuffs_crc32__ieee_hasher__struct&) = delete; wuffs_crc32__ieee_hasher__struct& operator=( const wuffs_crc32__ieee_hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_crc32__ieee_hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_u32* upcast_as__wuffs_base__hasher_u32() { return (wuffs_base__hasher_u32*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_crc32__ieee_hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_crc32__ieee_hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_crc32__ieee_hasher__update(this, a_x); } inline uint32_t update_u32( wuffs_base__slice_u8 a_x) { return wuffs_crc32__ieee_hasher__update_u32(this, a_x); } inline uint32_t checksum_u32() const { return wuffs_crc32__ieee_hasher__checksum_u32(this); } #endif // __cplusplus }; // struct wuffs_crc32__ieee_hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC32) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC64) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_crc64__ecma_hasher__struct wuffs_crc64__ecma_hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_crc64__ecma_hasher__initialize( wuffs_crc64__ecma_hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_crc64__ecma_hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_crc64__ecma_hasher* wuffs_crc64__ecma_hasher__alloc(void); static inline wuffs_base__hasher_u64* wuffs_crc64__ecma_hasher__alloc_as__wuffs_base__hasher_u64(void) { return (wuffs_base__hasher_u64*)(wuffs_crc64__ecma_hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_u64* wuffs_crc64__ecma_hasher__upcast_as__wuffs_base__hasher_u64( wuffs_crc64__ecma_hasher* p) { return (wuffs_base__hasher_u64*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__get_quirk( const wuffs_crc64__ecma_hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_crc64__ecma_hasher__set_quirk( wuffs_crc64__ecma_hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_crc64__ecma_hasher__update( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__update_u64( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__checksum_u64( const wuffs_crc64__ecma_hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_crc64__ecma_hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_u64; wuffs_base__vtable null_vtable; uint64_t f_state; wuffs_base__empty_struct (*choosy_up)( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_crc64__ecma_hasher__alloc()); } static inline wuffs_base__hasher_u64::unique_ptr alloc_as__wuffs_base__hasher_u64() { return wuffs_base__hasher_u64::unique_ptr( wuffs_crc64__ecma_hasher__alloc_as__wuffs_base__hasher_u64()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_crc64__ecma_hasher__struct() = delete; wuffs_crc64__ecma_hasher__struct(const wuffs_crc64__ecma_hasher__struct&) = delete; wuffs_crc64__ecma_hasher__struct& operator=( const wuffs_crc64__ecma_hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_crc64__ecma_hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_u64* upcast_as__wuffs_base__hasher_u64() { return (wuffs_base__hasher_u64*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_crc64__ecma_hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_crc64__ecma_hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_crc64__ecma_hasher__update(this, a_x); } inline uint64_t update_u64( wuffs_base__slice_u8 a_x) { return wuffs_crc64__ecma_hasher__update_u64(this, a_x); } inline uint64_t checksum_u64() const { return wuffs_crc64__ecma_hasher__checksum_u64(this); } #endif // __cplusplus }; // struct wuffs_crc64__ecma_hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC64) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__DEFLATE) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_deflate__error__bad_huffman_code_over_subscribed[]; extern const char wuffs_deflate__error__bad_huffman_code_under_subscribed[]; extern const char wuffs_deflate__error__bad_huffman_code_length_count[]; extern const char wuffs_deflate__error__bad_huffman_code_length_repetition[]; extern const char wuffs_deflate__error__bad_huffman_code[]; extern const char wuffs_deflate__error__bad_huffman_minimum_code_length[]; extern const char wuffs_deflate__error__bad_block[]; extern const char wuffs_deflate__error__bad_distance[]; extern const char wuffs_deflate__error__bad_distance_code_count[]; extern const char wuffs_deflate__error__bad_literal_length_code_count[]; extern const char wuffs_deflate__error__inconsistent_stored_block_length[]; extern const char wuffs_deflate__error__missing_end_of_block_code[]; extern const char wuffs_deflate__error__no_huffman_codes[]; extern const char wuffs_deflate__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_DEFLATE__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_DEFLATE__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 1u // ---------------- Struct Declarations typedef struct wuffs_deflate__decoder__struct wuffs_deflate__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_deflate__decoder__initialize( wuffs_deflate__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_deflate__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_deflate__decoder* wuffs_deflate__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_deflate__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_deflate__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_deflate__decoder__upcast_as__wuffs_base__io_transformer( wuffs_deflate__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_deflate__decoder__add_history( wuffs_deflate__decoder* self, wuffs_base__slice_u8 a_hist); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_deflate__decoder__get_quirk( const wuffs_deflate__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_deflate__decoder__set_quirk( wuffs_deflate__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_deflate__decoder__dst_history_retain_length( const wuffs_deflate__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_deflate__decoder__workbuf_len( const wuffs_deflate__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_deflate__decoder__transform_io( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_deflate__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; uint32_t f_bits; uint32_t f_n_bits; uint64_t f_transformed_history_count; uint32_t f_history_index; uint32_t f_n_huffs_bits[2]; bool f_end_of_block; uint32_t p_transform_io; uint32_t p_do_transform_io; uint32_t p_decode_blocks; uint32_t p_decode_uncompressed; uint32_t p_init_dynamic_huffman; wuffs_base__status (*choosy_decode_huffman_fast64)( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); uint32_t p_decode_huffman_slow; } private_impl; struct { uint32_t f_huffs[2][1024]; uint8_t f_history[33025]; uint8_t f_code_lengths[320]; struct { uint32_t v_final; } s_decode_blocks; struct { uint32_t v_length; uint64_t scratch; } s_decode_uncompressed; struct { uint32_t v_bits; uint32_t v_n_bits; uint32_t v_n_lit; uint32_t v_n_dist; uint32_t v_n_clen; uint32_t v_i; uint32_t v_mask; uint32_t v_n_extra_bits; uint8_t v_rep_symbol; uint32_t v_rep_count; } s_init_dynamic_huffman; struct { uint32_t v_bits; uint32_t v_n_bits; uint32_t v_table_entry_n_bits; uint32_t v_lmask; uint32_t v_dmask; uint32_t v_redir_top; uint32_t v_redir_mask; uint32_t v_length; uint32_t v_dist_minus_1; uint64_t scratch; } s_decode_huffman_slow; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_deflate__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_deflate__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_deflate__decoder__struct() = delete; wuffs_deflate__decoder__struct(const wuffs_deflate__decoder__struct&) = delete; wuffs_deflate__decoder__struct& operator=( const wuffs_deflate__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_deflate__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline wuffs_base__empty_struct add_history( wuffs_base__slice_u8 a_hist) { return wuffs_deflate__decoder__add_history(this, a_hist); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_deflate__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_deflate__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_deflate__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_deflate__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_deflate__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_deflate__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__DEFLATE) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GIF) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_gif__error__bad_lzw_code[]; extern const char wuffs_gif__error__bad_extension_label[]; extern const char wuffs_gif__error__bad_frame_size[]; extern const char wuffs_gif__error__bad_graphic_control[]; extern const char wuffs_gif__error__bad_header[]; extern const char wuffs_gif__error__bad_literal_width[]; extern const char wuffs_gif__error__bad_palette[]; extern const char wuffs_gif__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_GIF__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u #define WUFFS_GIF__QUIRK_DELAY_NUM_DECODED_FRAMES 1041635328u #define WUFFS_GIF__QUIRK_FIRST_FRAME_LOCAL_PALETTE_MEANS_BLACK_BACKGROUND 1041635329u #define WUFFS_GIF__QUIRK_HONOR_BACKGROUND_COLOR 1041635330u #define WUFFS_GIF__QUIRK_IGNORE_TOO_MUCH_PIXEL_DATA 1041635331u #define WUFFS_GIF__QUIRK_IMAGE_BOUNDS_ARE_STRICT 1041635332u #define WUFFS_GIF__QUIRK_REJECT_EMPTY_FRAME 1041635333u #define WUFFS_GIF__QUIRK_REJECT_EMPTY_PALETTE 1041635334u // ---------------- Struct Declarations typedef struct wuffs_gif__decoder__struct wuffs_gif__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_gif__decoder__initialize( wuffs_gif__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_gif__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_gif__decoder* wuffs_gif__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_gif__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_gif__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_gif__decoder__upcast_as__wuffs_base__image_decoder( wuffs_gif__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__get_quirk( const wuffs_gif__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__set_quirk( wuffs_gif__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_image_config( wuffs_gif__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_gif__decoder__set_report_metadata( wuffs_gif__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__tell_me_more( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_gif__decoder__num_animation_loops( const wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__num_decoded_frame_configs( const wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__num_decoded_frames( const wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_gif__decoder__frame_dirty_rect( const wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_gif__decoder__workbuf_len( const wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__restart_frame( wuffs_gif__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_frame_config( wuffs_gif__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_frame( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_gif__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; bool f_report_metadata_iccp; bool f_report_metadata_xmp; uint32_t f_metadata_fourcc; uint64_t f_metadata_io_position; bool f_quirks[7]; bool f_delayed_num_decoded_frames; bool f_seen_header; bool f_ignored_but_affects_benchmarks; bool f_has_global_palette; uint8_t f_interlace; bool f_seen_num_animation_loops_value; uint32_t f_num_animation_loops_value; uint32_t f_background_color_u32_argb_premul; uint32_t f_black_color_u32_argb_premul; bool f_gc_has_transparent_index; uint8_t f_gc_transparent_index; uint8_t f_gc_disposal; uint64_t f_gc_duration; uint64_t f_frame_config_io_position; uint64_t f_num_decoded_frame_configs_value; uint64_t f_num_decoded_frames_value; uint32_t f_frame_rect_x0; uint32_t f_frame_rect_y0; uint32_t f_frame_rect_x1; uint32_t f_frame_rect_y1; uint32_t f_dst_x; uint32_t f_dst_y; uint32_t f_dirty_max_excl_y; uint64_t f_compressed_ri; uint64_t f_compressed_wi; wuffs_base__pixel_swizzler f_swizzler; uint32_t f_lzw_pending_literal_width_plus_one; uint32_t f_lzw_literal_width; uint32_t f_lzw_clear_code; uint32_t f_lzw_end_code; uint32_t f_lzw_save_code; uint32_t f_lzw_prev_code; uint32_t f_lzw_width; uint32_t f_lzw_bits; uint32_t f_lzw_n_bits; uint32_t f_lzw_output_ri; uint32_t f_lzw_output_wi; uint32_t f_lzw_read_from_return_value; uint16_t f_lzw_prefixes[4096]; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_tell_me_more; uint32_t p_do_tell_me_more; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_skip_frame; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_decode_up_to_id_part1; uint32_t p_decode_header; uint32_t p_decode_lsd; uint32_t p_decode_extension; uint32_t p_skip_blocks; uint32_t p_decode_ae; uint32_t p_decode_gc; uint32_t p_decode_id_part0; uint32_t p_decode_id_part1; uint32_t p_decode_id_part2; } private_impl; struct { uint8_t f_compressed[4096]; uint8_t f_palettes[2][1024]; uint8_t f_dst_palette[1024]; uint8_t f_lzw_suffixes[4096][8]; uint16_t f_lzw_lm1s[4096]; uint8_t f_lzw_output[8199]; struct { uint32_t v_background_color; } s_do_decode_frame_config; struct { uint64_t scratch; } s_skip_frame; struct { uint64_t scratch; } s_decode_header; struct { uint8_t v_flags; uint8_t v_background_color_index; uint32_t v_num_palette_entries; uint32_t v_i; uint64_t scratch; } s_decode_lsd; struct { uint64_t scratch; } s_skip_blocks; struct { uint8_t v_block_size; bool v_is_animexts; bool v_is_netscape; bool v_is_iccp; bool v_is_xmp; uint64_t scratch; } s_decode_ae; struct { uint64_t scratch; } s_decode_gc; struct { uint64_t scratch; } s_decode_id_part0; struct { uint8_t v_which_palette; uint32_t v_num_palette_entries; uint32_t v_i; uint64_t scratch; } s_decode_id_part1; struct { uint64_t v_block_size; bool v_need_block_size; uint64_t scratch; } s_decode_id_part2; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_gif__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_gif__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_gif__decoder__struct() = delete; wuffs_gif__decoder__struct(const wuffs_gif__decoder__struct&) = delete; wuffs_gif__decoder__struct& operator=( const wuffs_gif__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_gif__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_gif__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_gif__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_gif__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_gif__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_gif__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline uint32_t num_animation_loops() const { return wuffs_gif__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_gif__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_gif__decoder__num_decoded_frames(this); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_gif__decoder__frame_dirty_rect(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_gif__decoder__workbuf_len(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_gif__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_gif__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_gif__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } #endif // __cplusplus }; // struct wuffs_gif__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GIF) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GZIP) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_gzip__error__bad_checksum[]; extern const char wuffs_gzip__error__bad_compression_method[]; extern const char wuffs_gzip__error__bad_encoding_flags[]; extern const char wuffs_gzip__error__bad_header[]; extern const char wuffs_gzip__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_GZIP__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_GZIP__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 1u // ---------------- Struct Declarations typedef struct wuffs_gzip__decoder__struct wuffs_gzip__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_gzip__decoder__initialize( wuffs_gzip__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_gzip__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_gzip__decoder* wuffs_gzip__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_gzip__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_gzip__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_gzip__decoder__upcast_as__wuffs_base__io_transformer( wuffs_gzip__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gzip__decoder__get_quirk( const wuffs_gzip__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gzip__decoder__set_quirk( wuffs_gzip__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_gzip__decoder__dst_history_retain_length( const wuffs_gzip__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_gzip__decoder__workbuf_len( const wuffs_gzip__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gzip__decoder__transform_io( wuffs_gzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_gzip__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; bool f_ignore_checksum; uint32_t p_transform_io; uint32_t p_do_transform_io; } private_impl; struct { wuffs_crc32__ieee_hasher f_checksum; wuffs_deflate__decoder f_flate; struct { uint8_t v_flags; uint32_t v_checksum_have; uint32_t v_decoded_length_have; uint32_t v_checksum_want; uint64_t scratch; } s_do_transform_io; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_gzip__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_gzip__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_gzip__decoder__struct() = delete; wuffs_gzip__decoder__struct(const wuffs_gzip__decoder__struct&) = delete; wuffs_gzip__decoder__struct& operator=( const wuffs_gzip__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_gzip__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_gzip__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_gzip__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_gzip__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_gzip__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_gzip__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_gzip__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GZIP) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JPEG) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_jpeg__error__bad_dht_marker[]; extern const char wuffs_jpeg__error__bad_dqt_marker[]; extern const char wuffs_jpeg__error__bad_dri_marker[]; extern const char wuffs_jpeg__error__bad_sof_marker[]; extern const char wuffs_jpeg__error__bad_sos_marker[]; extern const char wuffs_jpeg__error__bad_header[]; extern const char wuffs_jpeg__error__bad_marker[]; extern const char wuffs_jpeg__error__bad_scan_count[]; extern const char wuffs_jpeg__error__missing_huffman_table[]; extern const char wuffs_jpeg__error__missing_quantization_table[]; extern const char wuffs_jpeg__error__rejected_progressive_jpeg[]; extern const char wuffs_jpeg__error__truncated_input[]; extern const char wuffs_jpeg__error__unsupported_arithmetic_coding[]; extern const char wuffs_jpeg__error__unsupported_color_model[]; extern const char wuffs_jpeg__error__unsupported_fractional_sampling[]; extern const char wuffs_jpeg__error__unsupported_hierarchical_coding[]; extern const char wuffs_jpeg__error__unsupported_implicit_height[]; extern const char wuffs_jpeg__error__unsupported_lossless_coding[]; extern const char wuffs_jpeg__error__unsupported_marker[]; extern const char wuffs_jpeg__error__unsupported_precision_12_bits[]; extern const char wuffs_jpeg__error__unsupported_precision_16_bits[]; extern const char wuffs_jpeg__error__unsupported_precision[]; extern const char wuffs_jpeg__error__unsupported_scan_count[]; // ---------------- Public Consts #define WUFFS_JPEG__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 51552191232u #define WUFFS_JPEG__QUIRK_REJECT_PROGRESSIVE_JPEGS 1220532224u // ---------------- Struct Declarations typedef struct wuffs_jpeg__decoder__struct wuffs_jpeg__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_jpeg__decoder__initialize( wuffs_jpeg__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_jpeg__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_jpeg__decoder* wuffs_jpeg__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_jpeg__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_jpeg__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_jpeg__decoder__upcast_as__wuffs_base__image_decoder( wuffs_jpeg__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__get_quirk( const wuffs_jpeg__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__set_quirk( wuffs_jpeg__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_image_config( wuffs_jpeg__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_frame_config( wuffs_jpeg__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_frame( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_jpeg__decoder__frame_dirty_rect( const wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_jpeg__decoder__num_animation_loops( const wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__num_decoded_frame_configs( const wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__num_decoded_frames( const wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__restart_frame( wuffs_jpeg__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_jpeg__decoder__set_report_metadata( wuffs_jpeg__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__tell_me_more( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_jpeg__decoder__workbuf_len( const wuffs_jpeg__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_jpeg__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint32_t f_width_in_mcus; uint32_t f_height_in_mcus; uint8_t f_call_sequence; bool f_test_only_interrupt_decode_mcu; bool f_is_jfif; uint8_t f_is_adobe; bool f_is_rgb_or_cmyk; uint8_t f_sof_marker; uint8_t f_next_restart_marker; uint8_t f_max_incl_components_h; uint8_t f_max_incl_components_v; uint32_t f_num_components; uint8_t f_components_c[4]; uint8_t f_components_h[4]; uint8_t f_components_v[4]; uint8_t f_components_tq[4]; uint32_t f_components_workbuf_widths[4]; uint32_t f_components_workbuf_heights[4]; uint64_t f_components_workbuf_offsets[9]; uint32_t f_scan_count; uint32_t f_scan_num_components; uint8_t f_scan_comps_cselector[4]; uint8_t f_scan_comps_td[4]; uint8_t f_scan_comps_ta[4]; uint8_t f_scan_ss; uint8_t f_scan_se; uint8_t f_scan_ah; uint8_t f_scan_al; uint32_t f_scan_width_in_mcus; uint32_t f_scan_height_in_mcus; uint8_t f_scan_comps_bx_offset[16]; uint8_t f_scan_comps_by_offset[16]; uint32_t f_mcu_num_blocks; uint32_t f_mcu_current_block; uint32_t f_mcu_zig_index; uint8_t f_mcu_blocks_sselector[16]; uint64_t f_mcu_blocks_offset[10]; uint32_t f_mcu_blocks_mx_mul[10]; uint32_t f_mcu_blocks_my_mul[10]; uint8_t f_mcu_blocks_dc_hselector[10]; uint8_t f_mcu_blocks_ac_hselector[10]; uint16_t f_mcu_previous_dc_values[4]; uint8_t f_block_smoothing_lowest_scan_al[4][10]; uint16_t f_block_smoothing_dc_values[5][5]; uint32_t f_block_smoothing_mx_max_incl; uint32_t f_block_smoothing_my_max_incl; uint16_t f_restart_interval; uint16_t f_saved_restart_interval; uint16_t f_restarts_remaining; uint16_t f_eob_run; uint64_t f_frame_config_io_position; uint32_t f_payload_length; bool f_seen_dqt[4]; bool f_saved_seen_dqt[4]; bool f_seen_dht[8]; uint64_t f_bitstream_bits; uint32_t f_bitstream_n_bits; uint32_t f_bitstream_ri; uint32_t f_bitstream_wi; bool f_bitstream_is_closed; bool f_expect_multiple_scans; bool f_use_lower_quality; bool f_reject_progressive_jpegs; bool f_swizzle_immediately; wuffs_base__status f_swizzle_immediately_status; uint32_t f_swizzle_immediately_b_offsets[10]; uint32_t f_swizzle_immediately_c_offsets[5]; uint32_t f_bitstream_padding; uint16_t f_quant_tables[4][64]; uint16_t f_saved_quant_tables[4][64]; uint8_t f_huff_tables_symbols[8][256]; uint32_t f_huff_tables_slow[8][16]; uint16_t f_huff_tables_fast[8][256]; wuffs_base__pixel_swizzler f_swizzler; wuffs_base__empty_struct (*choosy_decode_idct)( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q); uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_dqt; uint32_t p_decode_dri; uint32_t p_decode_appn; uint32_t p_decode_sof; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_decode_dht; uint32_t p_decode_sos; uint32_t p_prepare_scan; wuffs_base__empty_struct (*choosy_load_mcu_blocks_for_single_component)( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel); uint32_t p_skip_past_the_next_restart_marker; uint32_t (*choosy_decode_mcu)( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); } private_impl; struct { uint8_t f_bitstream_buffer[2048]; uint16_t f_mcu_blocks[10][64]; uint8_t f_swizzle_immediately_buffer[640]; uint8_t f_swizzle_ycck_scratch_buffer_2k[2048]; uint8_t f_dht_temp_counts[16]; uint8_t f_dht_temp_bit_lengths[256]; uint16_t f_dht_temp_bit_strings[256]; uint8_t f_dst_palette[1024]; struct { uint8_t v_marker; uint64_t scratch; } s_do_decode_image_config; struct { uint8_t v_q; uint32_t v_i; } s_decode_dqt; struct { uint64_t scratch; } s_decode_dri; struct { uint64_t scratch; } s_decode_appn; struct { uint32_t v_i; uint64_t scratch; } s_decode_sof; struct { uint8_t v_marker; uint64_t scratch; } s_do_decode_frame; struct { uint8_t v_tc4_th; uint32_t v_total_count; uint32_t v_i; } s_decode_dht; struct { uint32_t v_my; uint32_t v_mx; } s_decode_sos; struct { uint32_t v_i; uint64_t scratch; } s_prepare_scan; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_jpeg__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_jpeg__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_jpeg__decoder__struct() = delete; wuffs_jpeg__decoder__struct(const wuffs_jpeg__decoder__struct&) = delete; wuffs_jpeg__decoder__struct& operator=( const wuffs_jpeg__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_jpeg__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_jpeg__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_jpeg__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_jpeg__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_jpeg__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_jpeg__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_jpeg__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_jpeg__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_jpeg__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_jpeg__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_jpeg__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_jpeg__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_jpeg__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_jpeg__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_jpeg__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JPEG) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JSON) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_json__error__bad_c0_control_code[]; extern const char wuffs_json__error__bad_utf_8[]; extern const char wuffs_json__error__bad_backslash_escape[]; extern const char wuffs_json__error__bad_input[]; extern const char wuffs_json__error__bad_new_line_in_a_string[]; extern const char wuffs_json__error__bad_quirk_combination[]; extern const char wuffs_json__error__unsupported_number_length[]; extern const char wuffs_json__error__unsupported_recursion_depth[]; // ---------------- Public Consts #define WUFFS_JSON__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u #define WUFFS_JSON__DECODER_DEPTH_MAX_INCL 1024u #define WUFFS_JSON__DECODER_DST_TOKEN_BUFFER_LENGTH_MIN_INCL 1u #define WUFFS_JSON__DECODER_SRC_IO_BUFFER_LENGTH_MIN_INCL 100u #define WUFFS_JSON__QUIRK_ALLOW_ASCII_CONTROL_CODES 1225364480u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_A 1225364481u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_CAPITAL_U 1225364482u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_E 1225364483u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_NEW_LINE 1225364484u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_QUESTION_MARK 1225364485u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_SINGLE_QUOTE 1225364486u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_V 1225364487u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_X_AS_CODE_POINTS 1225364489u #define WUFFS_JSON__QUIRK_ALLOW_BACKSLASH_ZERO 1225364490u #define WUFFS_JSON__QUIRK_ALLOW_COMMENT_BLOCK 1225364491u #define WUFFS_JSON__QUIRK_ALLOW_COMMENT_LINE 1225364492u #define WUFFS_JSON__QUIRK_ALLOW_EXTRA_COMMA 1225364493u #define WUFFS_JSON__QUIRK_ALLOW_INF_NAN_NUMBERS 1225364494u #define WUFFS_JSON__QUIRK_ALLOW_LEADING_ASCII_RECORD_SEPARATOR 1225364495u #define WUFFS_JSON__QUIRK_ALLOW_LEADING_UNICODE_BYTE_ORDER_MARK 1225364496u #define WUFFS_JSON__QUIRK_ALLOW_TRAILING_FILLER 1225364497u #define WUFFS_JSON__QUIRK_EXPECT_TRAILING_NEW_LINE_OR_EOF 1225364498u #define WUFFS_JSON__QUIRK_JSON_POINTER_ALLOW_TILDE_N_TILDE_R_TILDE_T 1225364499u #define WUFFS_JSON__QUIRK_REPLACE_INVALID_UNICODE 1225364500u // ---------------- Struct Declarations typedef struct wuffs_json__decoder__struct wuffs_json__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_json__decoder__initialize( wuffs_json__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_json__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_json__decoder* wuffs_json__decoder__alloc(void); static inline wuffs_base__token_decoder* wuffs_json__decoder__alloc_as__wuffs_base__token_decoder(void) { return (wuffs_base__token_decoder*)(wuffs_json__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__token_decoder* wuffs_json__decoder__upcast_as__wuffs_base__token_decoder( wuffs_json__decoder* p) { return (wuffs_base__token_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_json__decoder__get_quirk( const wuffs_json__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_json__decoder__set_quirk( wuffs_json__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_json__decoder__workbuf_len( const wuffs_json__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_json__decoder__decode_tokens( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_json__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__token_decoder; wuffs_base__vtable null_vtable; bool f_quirks[21]; bool f_allow_leading_ars; bool f_allow_leading_ubom; bool f_end_of_data; uint8_t f_trailer_stop; uint8_t f_comment_type; uint32_t p_decode_tokens; uint32_t p_decode_leading; uint32_t p_decode_comment; uint32_t p_decode_inf_nan; uint32_t p_decode_trailer; } private_impl; struct { uint32_t f_stack[32]; struct { uint32_t v_depth; uint32_t v_expect; uint32_t v_expect_after_value; } s_decode_tokens; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_json__decoder__alloc()); } static inline wuffs_base__token_decoder::unique_ptr alloc_as__wuffs_base__token_decoder() { return wuffs_base__token_decoder::unique_ptr( wuffs_json__decoder__alloc_as__wuffs_base__token_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_json__decoder__struct() = delete; wuffs_json__decoder__struct(const wuffs_json__decoder__struct&) = delete; wuffs_json__decoder__struct& operator=( const wuffs_json__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_json__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__token_decoder* upcast_as__wuffs_base__token_decoder() { return (wuffs_base__token_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_json__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_json__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_json__decoder__workbuf_len(this); } inline wuffs_base__status decode_tokens( wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_json__decoder__decode_tokens(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_json__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JSON) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZMA) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_lzma__error__bad_lzma2_header[]; extern const char wuffs_lzma__error__bad_bitstream_trailer[]; extern const char wuffs_lzma__error__bad_code[]; extern const char wuffs_lzma__error__bad_decoded_length[]; extern const char wuffs_lzma__error__bad_distance[]; extern const char wuffs_lzma__error__bad_header[]; extern const char wuffs_lzma__error__truncated_input[]; extern const char wuffs_lzma__error__unsupported_decoded_length[]; extern const char wuffs_lzma__error__unsupported_properties[]; // ---------------- Public Consts #define WUFFS_LZMA__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_LZMA__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 4294967568u #define WUFFS_LZMA__QUIRK_ALLOW_NON_ZERO_INITIAL_BYTE 1348001792u #define WUFFS_LZMA__QUIRK_FORMAT_EXTENSION 1348001793u // ---------------- Struct Declarations typedef struct wuffs_lzma__decoder__struct wuffs_lzma__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzma__decoder__initialize( wuffs_lzma__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_lzma__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_lzma__decoder* wuffs_lzma__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_lzma__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_lzma__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_lzma__decoder__upcast_as__wuffs_base__io_transformer( wuffs_lzma__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzma__decoder__get_quirk( const wuffs_lzma__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzma__decoder__set_quirk( wuffs_lzma__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzma__decoder__dst_history_retain_length( const wuffs_lzma__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzma__decoder__workbuf_len( const wuffs_lzma__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzma__decoder__transform_io( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_lzma__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; uint32_t f_lc; uint32_t f_lp; uint32_t f_pb; uint32_t f_format_extension; uint32_t f_dict_size; uint32_t f_dict_workbuf_index; uint32_t f_dict_seen; uint64_t f_decoded_length; uint64_t f_lzma2_encoded_length_have; uint64_t f_lzma2_encoded_length_want; bool f_lzma2_need_prob_reset; bool f_lzma2_need_properties; bool f_lzma2_need_dict_reset; bool f_prev_lzma2_chunk_was_uncompressed; bool f_allow_non_zero_initial_byte; bool f_end_of_chunk; uint8_t f_stashed_bytes[2]; uint32_t f_stashed_bits; uint32_t f_stashed_range; uint32_t f_stashed_state; uint32_t f_stashed_rep0; uint32_t f_stashed_rep1; uint32_t f_stashed_rep2; uint32_t f_stashed_rep3; uint64_t f_stashed_pos; uint64_t f_stashed_pos_end; uint32_t p_decode_bitstream_slow; uint32_t p_transform_io; uint32_t p_do_transform_io; uint32_t p_decode_bitstream; uint32_t p_update_stashed_bytes; uint32_t p_decode_optional_end_of_stream; } private_impl; struct { uint16_t f_probs_ao00[192]; uint16_t f_probs_ao20[12]; uint16_t f_probs_ao40[12]; uint16_t f_probs_ao41[192]; uint16_t f_probs_ao60[12]; uint16_t f_probs_ao63[12]; uint16_t f_probs_match_len_low[16][8]; uint16_t f_probs_match_len_mid[16][8]; uint16_t f_probs_match_len_high[1][256]; uint16_t f_probs_longrep_len_low[16][8]; uint16_t f_probs_longrep_len_mid[16][8]; uint16_t f_probs_longrep_len_high[1][256]; uint16_t f_probs_slot[4][64]; uint16_t f_probs_small_dist[128]; uint16_t f_probs_large_dist[16]; uint16_t f_probs_lit[16][768]; struct { uint32_t v_bits; uint32_t v_range; uint32_t v_state; uint32_t v_rep0; uint32_t v_rep1; uint32_t v_rep2; uint32_t v_rep3; uint32_t v_rep; uint64_t v_pos; uint64_t v_pos_end; uint32_t v_lc; uint64_t v_lp_mask; uint64_t v_pb_mask; uint32_t v_tree_node; uint8_t v_prev_byte; uint32_t v_match_byte; uint32_t v_len_state; uint32_t v_slot; uint32_t v_len; uint32_t v_lanl_offset; uint32_t v_num_extra_bits; uint32_t v_dist_extra_bits; uint32_t v_i; uint32_t v_index_lit; uint32_t v_index_len; uint32_t v_index_small_dist_base; uint32_t v_index_small_dist_extra; uint32_t v_index_large_dist; uint32_t v_dist; uint64_t scratch; } s_decode_bitstream_slow; struct { uint8_t v_header_byte; uint32_t v_length; uint64_t scratch; } s_do_transform_io; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_lzma__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_lzma__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_lzma__decoder__struct() = delete; wuffs_lzma__decoder__struct(const wuffs_lzma__decoder__struct&) = delete; wuffs_lzma__decoder__struct& operator=( const wuffs_lzma__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_lzma__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_lzma__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_lzma__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_lzma__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_lzma__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_lzma__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_lzma__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZMA) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZIP) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_lzip__error__bad_checksum[]; extern const char wuffs_lzip__error__bad_footer[]; extern const char wuffs_lzip__error__bad_header[]; extern const char wuffs_lzip__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_LZIP__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_LZIP__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 4294967568u // ---------------- Struct Declarations typedef struct wuffs_lzip__decoder__struct wuffs_lzip__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzip__decoder__initialize( wuffs_lzip__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_lzip__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_lzip__decoder* wuffs_lzip__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_lzip__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_lzip__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_lzip__decoder__upcast_as__wuffs_base__io_transformer( wuffs_lzip__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzip__decoder__get_quirk( const wuffs_lzip__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzip__decoder__set_quirk( wuffs_lzip__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzip__decoder__dst_history_retain_length( const wuffs_lzip__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzip__decoder__workbuf_len( const wuffs_lzip__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzip__decoder__transform_io( wuffs_lzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_lzip__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; bool f_ignore_checksum; uint64_t f_dsize_have; uint64_t f_ssize_have; uint32_t p_transform_io; uint32_t p_do_transform_io; } private_impl; struct { wuffs_crc32__ieee_hasher f_crc32; wuffs_lzma__decoder f_lzma; struct { uint64_t scratch; } s_do_transform_io; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_lzip__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_lzip__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_lzip__decoder__struct() = delete; wuffs_lzip__decoder__struct(const wuffs_lzip__decoder__struct&) = delete; wuffs_lzip__decoder__struct& operator=( const wuffs_lzip__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_lzip__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_lzip__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_lzip__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_lzip__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_lzip__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_lzip__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_lzip__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZIP) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZW) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_lzw__error__bad_code[]; extern const char wuffs_lzw__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_LZW__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_LZW__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u #define WUFFS_LZW__QUIRK_LITERAL_WIDTH_PLUS_ONE 1348378624u // ---------------- Struct Declarations typedef struct wuffs_lzw__decoder__struct wuffs_lzw__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzw__decoder__initialize( wuffs_lzw__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_lzw__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_lzw__decoder* wuffs_lzw__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_lzw__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_lzw__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_lzw__decoder__upcast_as__wuffs_base__io_transformer( wuffs_lzw__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzw__decoder__get_quirk( const wuffs_lzw__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzw__decoder__set_quirk( wuffs_lzw__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzw__decoder__dst_history_retain_length( const wuffs_lzw__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzw__decoder__workbuf_len( const wuffs_lzw__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzw__decoder__transform_io( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__slice_u8 wuffs_lzw__decoder__flush( wuffs_lzw__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_lzw__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; uint32_t f_pending_literal_width_plus_one; uint32_t f_literal_width; uint32_t f_clear_code; uint32_t f_end_code; uint32_t f_save_code; uint32_t f_prev_code; uint32_t f_width; uint32_t f_bits; uint32_t f_n_bits; uint32_t f_output_ri; uint32_t f_output_wi; uint32_t f_read_from_return_value; uint16_t f_prefixes[4096]; uint32_t p_transform_io; uint32_t p_write_to; } private_impl; struct { uint8_t f_suffixes[4096][8]; uint16_t f_lm1s[4096]; uint8_t f_output[8199]; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_lzw__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_lzw__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_lzw__decoder__struct() = delete; wuffs_lzw__decoder__struct(const wuffs_lzw__decoder__struct&) = delete; wuffs_lzw__decoder__struct& operator=( const wuffs_lzw__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_lzw__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_lzw__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_lzw__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_lzw__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_lzw__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_lzw__decoder__transform_io(this, a_dst, a_src, a_workbuf); } inline wuffs_base__slice_u8 flush() { return wuffs_lzw__decoder__flush(this); } #endif // __cplusplus }; // struct wuffs_lzw__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZW) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NETPBM) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_netpbm__error__bad_header[]; extern const char wuffs_netpbm__error__truncated_input[]; extern const char wuffs_netpbm__error__unsupported_netpbm_file[]; // ---------------- Public Consts #define WUFFS_NETPBM__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_netpbm__decoder__struct wuffs_netpbm__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_netpbm__decoder__initialize( wuffs_netpbm__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_netpbm__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_netpbm__decoder* wuffs_netpbm__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_netpbm__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_netpbm__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_netpbm__decoder__upcast_as__wuffs_base__image_decoder( wuffs_netpbm__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__get_quirk( const wuffs_netpbm__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__set_quirk( wuffs_netpbm__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_image_config( wuffs_netpbm__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_frame_config( wuffs_netpbm__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_frame( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_netpbm__decoder__frame_dirty_rect( const wuffs_netpbm__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_netpbm__decoder__num_animation_loops( const wuffs_netpbm__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__num_decoded_frame_configs( const wuffs_netpbm__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__num_decoded_frames( const wuffs_netpbm__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__restart_frame( wuffs_netpbm__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_netpbm__decoder__set_report_metadata( wuffs_netpbm__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__tell_me_more( wuffs_netpbm__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_netpbm__decoder__workbuf_len( const wuffs_netpbm__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_netpbm__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_pixfmt; uint32_t f_width; uint32_t f_height; uint32_t f_max_value; uint8_t f_call_sequence; uint64_t f_frame_config_io_position; uint32_t f_dst_x; uint32_t f_dst_y; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_netpbm__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_netpbm__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_netpbm__decoder__struct() = delete; wuffs_netpbm__decoder__struct(const wuffs_netpbm__decoder__struct&) = delete; wuffs_netpbm__decoder__struct& operator=( const wuffs_netpbm__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_netpbm__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_netpbm__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_netpbm__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_netpbm__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_netpbm__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_netpbm__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_netpbm__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_netpbm__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_netpbm__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_netpbm__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_netpbm__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_netpbm__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_netpbm__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_netpbm__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_netpbm__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NETPBM) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NIE) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_nie__error__bad_header[]; extern const char wuffs_nie__error__truncated_input[]; extern const char wuffs_nie__error__unsupported_nie_file[]; // ---------------- Public Consts #define WUFFS_NIE__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_nie__decoder__struct wuffs_nie__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_nie__decoder__initialize( wuffs_nie__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_nie__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_nie__decoder* wuffs_nie__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_nie__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_nie__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_nie__decoder__upcast_as__wuffs_base__image_decoder( wuffs_nie__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__get_quirk( const wuffs_nie__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__set_quirk( wuffs_nie__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_image_config( wuffs_nie__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_frame_config( wuffs_nie__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_frame( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_nie__decoder__frame_dirty_rect( const wuffs_nie__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_nie__decoder__num_animation_loops( const wuffs_nie__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__num_decoded_frame_configs( const wuffs_nie__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__num_decoded_frames( const wuffs_nie__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__restart_frame( wuffs_nie__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_nie__decoder__set_report_metadata( wuffs_nie__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__tell_me_more( wuffs_nie__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_nie__decoder__workbuf_len( const wuffs_nie__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_nie__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_pixfmt; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; uint32_t f_dst_x; uint32_t f_dst_y; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; } private_impl; struct { struct { uint64_t scratch; } s_do_decode_image_config; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_nie__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_nie__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_nie__decoder__struct() = delete; wuffs_nie__decoder__struct(const wuffs_nie__decoder__struct&) = delete; wuffs_nie__decoder__struct& operator=( const wuffs_nie__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_nie__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_nie__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_nie__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_nie__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_nie__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_nie__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_nie__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_nie__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_nie__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_nie__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_nie__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_nie__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_nie__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_nie__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_nie__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NIE) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ZLIB) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_zlib__note__dictionary_required[]; extern const char wuffs_zlib__error__bad_checksum[]; extern const char wuffs_zlib__error__bad_compression_method[]; extern const char wuffs_zlib__error__bad_compression_window_size[]; extern const char wuffs_zlib__error__bad_parity_check[]; extern const char wuffs_zlib__error__incorrect_dictionary[]; extern const char wuffs_zlib__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_ZLIB__QUIRK_JUST_RAW_DEFLATE 2113790976u #define WUFFS_ZLIB__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_ZLIB__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 1u // ---------------- Struct Declarations typedef struct wuffs_zlib__decoder__struct wuffs_zlib__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_zlib__decoder__initialize( wuffs_zlib__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_zlib__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_zlib__decoder* wuffs_zlib__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_zlib__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_zlib__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_zlib__decoder__upcast_as__wuffs_base__io_transformer( wuffs_zlib__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_zlib__decoder__dictionary_id( const wuffs_zlib__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_zlib__decoder__add_dictionary( wuffs_zlib__decoder* self, wuffs_base__slice_u8 a_dict); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_zlib__decoder__get_quirk( const wuffs_zlib__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_zlib__decoder__set_quirk( wuffs_zlib__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_zlib__decoder__dst_history_retain_length( const wuffs_zlib__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_zlib__decoder__workbuf_len( const wuffs_zlib__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_zlib__decoder__transform_io( wuffs_zlib__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_zlib__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; bool f_bad_call_sequence; bool f_header_complete; bool f_got_dictionary; bool f_want_dictionary; bool f_quirks[1]; bool f_ignore_checksum; uint32_t f_dict_id_have; uint32_t f_dict_id_want; uint32_t p_transform_io; uint32_t p_do_transform_io; } private_impl; struct { wuffs_adler32__hasher f_checksum; wuffs_adler32__hasher f_dict_id_hasher; wuffs_deflate__decoder f_flate; struct { uint32_t v_checksum_have; uint64_t scratch; } s_do_transform_io; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_zlib__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_zlib__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_zlib__decoder__struct() = delete; wuffs_zlib__decoder__struct(const wuffs_zlib__decoder__struct&) = delete; wuffs_zlib__decoder__struct& operator=( const wuffs_zlib__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_zlib__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint32_t dictionary_id() const { return wuffs_zlib__decoder__dictionary_id(this); } inline wuffs_base__empty_struct add_dictionary( wuffs_base__slice_u8 a_dict) { return wuffs_zlib__decoder__add_dictionary(this, a_dict); } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_zlib__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_zlib__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_zlib__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_zlib__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_zlib__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_zlib__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ZLIB) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__PNG) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_png__error__bad_animation_sequence_number[]; extern const char wuffs_png__error__bad_checksum[]; extern const char wuffs_png__error__bad_chunk[]; extern const char wuffs_png__error__bad_filter[]; extern const char wuffs_png__error__bad_header[]; extern const char wuffs_png__error__bad_text_chunk_not_latin_1[]; extern const char wuffs_png__error__missing_palette[]; extern const char wuffs_png__error__truncated_input[]; extern const char wuffs_png__error__unsupported_cgbi_extension[]; extern const char wuffs_png__error__unsupported_png_compression_method[]; extern const char wuffs_png__error__unsupported_png_file[]; // ---------------- Public Consts #define WUFFS_PNG__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 2251799562027015u #define WUFFS_PNG__DECODER_SRC_IO_BUFFER_LENGTH_MIN_INCL 8u // ---------------- Struct Declarations typedef struct wuffs_png__decoder__struct wuffs_png__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_png__decoder__initialize( wuffs_png__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_png__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_png__decoder* wuffs_png__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_png__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_png__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_png__decoder__upcast_as__wuffs_base__image_decoder( wuffs_png__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__get_quirk( const wuffs_png__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__set_quirk( wuffs_png__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_image_config( wuffs_png__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_frame_config( wuffs_png__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_frame( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_png__decoder__frame_dirty_rect( const wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_png__decoder__num_animation_loops( const wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__num_decoded_frame_configs( const wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__num_decoded_frames( const wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__restart_frame( wuffs_png__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_png__decoder__set_report_metadata( wuffs_png__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__tell_me_more( wuffs_png__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_png__decoder__workbuf_len( const wuffs_png__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_png__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint64_t f_pass_bytes_per_row; uint64_t f_workbuf_wi; uint64_t f_workbuf_hist_pos_base; uint64_t f_overall_workbuf_length; uint64_t f_pass_workbuf_length; uint8_t f_call_sequence; bool f_report_metadata_chrm; bool f_report_metadata_exif; bool f_report_metadata_gama; bool f_report_metadata_iccp; bool f_report_metadata_kvp; bool f_report_metadata_srgb; bool f_ignore_checksum; uint8_t f_depth; uint8_t f_color_type; uint8_t f_filter_distance; uint8_t f_interlace_pass; bool f_seen_actl; bool f_seen_chrm; bool f_seen_fctl; bool f_seen_exif; bool f_seen_gama; bool f_seen_iccp; bool f_seen_idat; bool f_seen_ihdr; bool f_seen_plte; bool f_seen_srgb; bool f_seen_trns; bool f_metadata_is_zlib_compressed; bool f_zlib_is_dirty; uint32_t f_chunk_type; uint8_t f_chunk_type_array[4]; uint32_t f_chunk_length; uint64_t f_remap_transparency; uint32_t f_dst_pixfmt; uint32_t f_src_pixfmt; uint32_t f_num_animation_frames_value; uint32_t f_num_animation_loops_value; uint32_t f_num_decoded_frame_configs_value; uint32_t f_num_decoded_frames_value; uint32_t f_frame_rect_x0; uint32_t f_frame_rect_y0; uint32_t f_frame_rect_x1; uint32_t f_frame_rect_y1; uint32_t f_first_rect_x0; uint32_t f_first_rect_y0; uint32_t f_first_rect_x1; uint32_t f_first_rect_y1; uint64_t f_frame_config_io_position; uint64_t f_first_config_io_position; uint64_t f_frame_duration; uint64_t f_first_duration; uint8_t f_frame_disposal; uint8_t f_first_disposal; bool f_frame_overwrite_instead_of_blend; bool f_first_overwrite_instead_of_blend; uint32_t f_next_animation_seq_num; uint32_t f_metadata_flavor; uint32_t f_metadata_fourcc; uint64_t f_metadata_x; uint64_t f_metadata_y; uint64_t f_metadata_z; uint32_t f_ztxt_ri; uint32_t f_ztxt_wi; uint64_t f_ztxt_hist_pos; wuffs_base__pixel_swizzler f_swizzler; wuffs_base__empty_struct (*choosy_filter_1)( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); wuffs_base__empty_struct (*choosy_filter_3)( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); wuffs_base__empty_struct (*choosy_filter_4)( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_ihdr; uint32_t p_decode_other_chunk; uint32_t p_decode_actl; uint32_t p_decode_chrm; uint32_t p_decode_fctl; uint32_t p_decode_gama; uint32_t p_decode_iccp; uint32_t p_decode_plte; uint32_t p_decode_srgb; uint32_t p_decode_trns; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_skip_frame; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_decode_pass; uint32_t p_tell_me_more; uint32_t p_do_tell_me_more; wuffs_base__status (*choosy_filter_and_swizzle)( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf); } private_impl; struct { wuffs_crc32__ieee_hasher f_crc32; wuffs_zlib__decoder f_zlib; uint8_t f_dst_palette[1024]; uint8_t f_src_palette[1024]; struct { uint32_t v_checksum_have; uint64_t scratch; } s_do_decode_image_config; struct { uint64_t scratch; } s_decode_ihdr; struct { uint64_t scratch; } s_decode_other_chunk; struct { uint64_t scratch; } s_decode_actl; struct { uint64_t scratch; } s_decode_chrm; struct { uint32_t v_x0; uint32_t v_x1; uint32_t v_y1; uint64_t scratch; } s_decode_fctl; struct { uint64_t scratch; } s_decode_gama; struct { uint32_t v_num_entries; uint32_t v_i; uint64_t scratch; } s_decode_plte; struct { uint32_t v_i; uint32_t v_n; uint64_t scratch; } s_decode_trns; struct { uint64_t scratch; } s_do_decode_frame_config; struct { uint64_t scratch; } s_skip_frame; struct { uint64_t scratch; } s_do_decode_frame; struct { uint64_t scratch; } s_decode_pass; struct { wuffs_base__status v_zlib_status; uint64_t scratch; } s_do_tell_me_more; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_png__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_png__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_png__decoder__struct() = delete; wuffs_png__decoder__struct(const wuffs_png__decoder__struct&) = delete; wuffs_png__decoder__struct& operator=( const wuffs_png__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_png__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_png__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_png__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_png__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_png__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_png__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_png__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_png__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_png__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_png__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_png__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_png__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_png__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_png__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_png__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__PNG) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__QOI) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_qoi__error__bad_footer[]; extern const char wuffs_qoi__error__bad_header[]; extern const char wuffs_qoi__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_QOI__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_qoi__decoder__struct wuffs_qoi__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_qoi__decoder__initialize( wuffs_qoi__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_qoi__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_qoi__decoder* wuffs_qoi__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_qoi__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_qoi__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_qoi__decoder__upcast_as__wuffs_base__image_decoder( wuffs_qoi__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__get_quirk( const wuffs_qoi__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__set_quirk( wuffs_qoi__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_image_config( wuffs_qoi__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_frame_config( wuffs_qoi__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_frame( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_qoi__decoder__frame_dirty_rect( const wuffs_qoi__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_qoi__decoder__num_animation_loops( const wuffs_qoi__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__num_decoded_frame_configs( const wuffs_qoi__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__num_decoded_frames( const wuffs_qoi__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__restart_frame( wuffs_qoi__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_qoi__decoder__set_report_metadata( wuffs_qoi__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__tell_me_more( wuffs_qoi__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_qoi__decoder__workbuf_len( const wuffs_qoi__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_qoi__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_pixfmt; uint32_t f_width; uint32_t f_height; uint64_t f_remaining_pixels_times_4; uint8_t f_call_sequence; uint32_t f_buffer_index; uint32_t f_dst_x; uint32_t f_dst_y; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_from_src_to_buffer; } private_impl; struct { uint8_t f_pixel[4]; uint8_t f_cache[256]; uint8_t f_buffer[8196]; struct { uint64_t scratch; } s_do_decode_image_config; struct { uint64_t scratch; } s_do_decode_frame; struct { uint8_t v_dg; uint32_t v_bi; uint32_t v_bk; } s_from_src_to_buffer; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_qoi__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_qoi__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_qoi__decoder__struct() = delete; wuffs_qoi__decoder__struct(const wuffs_qoi__decoder__struct&) = delete; wuffs_qoi__decoder__struct& operator=( const wuffs_qoi__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_qoi__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_qoi__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_qoi__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_qoi__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_qoi__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_qoi__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_qoi__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_qoi__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_qoi__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_qoi__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_qoi__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_qoi__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_qoi__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_qoi__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_qoi__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__QOI) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__SHA256) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_sha256__hasher__struct wuffs_sha256__hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_sha256__hasher__initialize( wuffs_sha256__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_sha256__hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_sha256__hasher* wuffs_sha256__hasher__alloc(void); static inline wuffs_base__hasher_bitvec256* wuffs_sha256__hasher__alloc_as__wuffs_base__hasher_bitvec256(void) { return (wuffs_base__hasher_bitvec256*)(wuffs_sha256__hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_bitvec256* wuffs_sha256__hasher__upcast_as__wuffs_base__hasher_bitvec256( wuffs_sha256__hasher* p) { return (wuffs_base__hasher_bitvec256*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_sha256__hasher__get_quirk( const wuffs_sha256__hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_sha256__hasher__set_quirk( wuffs_sha256__hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_sha256__hasher__update( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_sha256__hasher__update_bitvec256( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_sha256__hasher__checksum_bitvec256( const wuffs_sha256__hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_sha256__hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_bitvec256; wuffs_base__vtable null_vtable; uint64_t f_length_modulo_u64; bool f_length_overflows_u64; uint8_t f_padding0; uint8_t f_padding1; uint8_t f_padding2; uint32_t f_buf_len; uint8_t f_buf_data[64]; uint32_t f_h0; uint32_t f_h1; uint32_t f_h2; uint32_t f_h3; uint32_t f_h4; uint32_t f_h5; uint32_t f_h6; uint32_t f_h7; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_sha256__hasher__alloc()); } static inline wuffs_base__hasher_bitvec256::unique_ptr alloc_as__wuffs_base__hasher_bitvec256() { return wuffs_base__hasher_bitvec256::unique_ptr( wuffs_sha256__hasher__alloc_as__wuffs_base__hasher_bitvec256()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_sha256__hasher__struct() = delete; wuffs_sha256__hasher__struct(const wuffs_sha256__hasher__struct&) = delete; wuffs_sha256__hasher__struct& operator=( const wuffs_sha256__hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_sha256__hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_bitvec256* upcast_as__wuffs_base__hasher_bitvec256() { return (wuffs_base__hasher_bitvec256*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_sha256__hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_sha256__hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_sha256__hasher__update(this, a_x); } inline wuffs_base__bitvec256 update_bitvec256( wuffs_base__slice_u8 a_x) { return wuffs_sha256__hasher__update_bitvec256(this, a_x); } inline wuffs_base__bitvec256 checksum_bitvec256() const { return wuffs_sha256__hasher__checksum_bitvec256(this); } #endif // __cplusplus }; // struct wuffs_sha256__hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__SHA256) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__TGA) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_tga__error__bad_header[]; extern const char wuffs_tga__error__bad_run_length_encoding[]; extern const char wuffs_tga__error__truncated_input[]; extern const char wuffs_tga__error__unsupported_tga_file[]; // ---------------- Public Consts #define WUFFS_TGA__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_tga__decoder__struct wuffs_tga__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_tga__decoder__initialize( wuffs_tga__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_tga__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_tga__decoder* wuffs_tga__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_tga__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_tga__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_tga__decoder__upcast_as__wuffs_base__image_decoder( wuffs_tga__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__get_quirk( const wuffs_tga__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__set_quirk( wuffs_tga__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_image_config( wuffs_tga__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_frame_config( wuffs_tga__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_frame( wuffs_tga__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_tga__decoder__frame_dirty_rect( const wuffs_tga__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_tga__decoder__num_animation_loops( const wuffs_tga__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__num_decoded_frame_configs( const wuffs_tga__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__num_decoded_frames( const wuffs_tga__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__restart_frame( wuffs_tga__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_tga__decoder__set_report_metadata( wuffs_tga__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__tell_me_more( wuffs_tga__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_tga__decoder__workbuf_len( const wuffs_tga__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_tga__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; uint8_t f_header_id_length; uint8_t f_header_color_map_type; uint8_t f_header_image_type; uint16_t f_header_color_map_first_entry_index; uint16_t f_header_color_map_length; uint8_t f_header_color_map_entry_size; uint8_t f_header_pixel_depth; uint8_t f_header_image_descriptor; bool f_opaque; uint32_t f_scratch_bytes_per_pixel; uint32_t f_src_bytes_per_pixel; uint32_t f_src_pixfmt; uint64_t f_frame_config_io_position; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; } private_impl; struct { uint8_t f_dst_palette[1024]; uint8_t f_src_palette[1024]; uint8_t f_scratch[4]; struct { uint32_t v_i; uint64_t scratch; } s_do_decode_image_config; struct { uint64_t v_dst_bytes_per_pixel; uint32_t v_dst_x; uint32_t v_dst_y; uint64_t v_mark; uint32_t v_num_pixels32; uint32_t v_lit_length; uint32_t v_run_length; uint64_t v_num_dst_bytes; uint64_t scratch; } s_do_decode_frame; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_tga__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_tga__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_tga__decoder__struct() = delete; wuffs_tga__decoder__struct(const wuffs_tga__decoder__struct&) = delete; wuffs_tga__decoder__struct& operator=( const wuffs_tga__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_tga__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_tga__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_tga__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_tga__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_tga__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_tga__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_tga__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_tga__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_tga__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_tga__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_tga__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_tga__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_tga__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_tga__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_tga__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__TGA) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__VP8) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_vp8__placeholder__struct wuffs_vp8__placeholder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_vp8__placeholder__initialize( wuffs_vp8__placeholder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_vp8__placeholder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_vp8__placeholder* wuffs_vp8__placeholder__alloc(void); // ---------------- Upcasts // ---------------- Public Function Prototypes #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_vp8__placeholder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable null_vtable; uint32_t f_placeholder; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_vp8__placeholder__alloc()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_vp8__placeholder__struct() = delete; wuffs_vp8__placeholder__struct(const wuffs_vp8__placeholder__struct&) = delete; wuffs_vp8__placeholder__struct& operator=( const wuffs_vp8__placeholder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_vp8__placeholder__initialize( this, sizeof_star_self, wuffs_version, options); } #endif // __cplusplus }; // struct wuffs_vp8__placeholder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__VP8) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WBMP) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_wbmp__error__bad_header[]; extern const char wuffs_wbmp__error__truncated_input[]; // ---------------- Public Consts #define WUFFS_WBMP__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_wbmp__decoder__struct wuffs_wbmp__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_wbmp__decoder__initialize( wuffs_wbmp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_wbmp__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_wbmp__decoder* wuffs_wbmp__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_wbmp__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_wbmp__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_wbmp__decoder__upcast_as__wuffs_base__image_decoder( wuffs_wbmp__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__get_quirk( const wuffs_wbmp__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__set_quirk( wuffs_wbmp__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_image_config( wuffs_wbmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_frame_config( wuffs_wbmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_frame( wuffs_wbmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_wbmp__decoder__frame_dirty_rect( const wuffs_wbmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_wbmp__decoder__num_animation_loops( const wuffs_wbmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__num_decoded_frame_configs( const wuffs_wbmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__num_decoded_frames( const wuffs_wbmp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__restart_frame( wuffs_wbmp__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_wbmp__decoder__set_report_metadata( wuffs_wbmp__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__tell_me_more( wuffs_wbmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_wbmp__decoder__workbuf_len( const wuffs_wbmp__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_wbmp__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; uint64_t f_frame_config_io_position; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; } private_impl; struct { struct { uint32_t v_i; uint32_t v_p; } s_do_decode_image_config; struct { uint64_t v_dst_bytes_per_pixel; uint32_t v_dst_x; uint32_t v_dst_y; uint8_t v_src[1]; uint8_t v_c8; } s_do_decode_frame; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_wbmp__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_wbmp__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_wbmp__decoder__struct() = delete; wuffs_wbmp__decoder__struct(const wuffs_wbmp__decoder__struct&) = delete; wuffs_wbmp__decoder__struct& operator=( const wuffs_wbmp__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_wbmp__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_wbmp__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_wbmp__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_wbmp__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_wbmp__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_wbmp__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_wbmp__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_wbmp__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_wbmp__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_wbmp__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_wbmp__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_wbmp__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_wbmp__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_wbmp__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_wbmp__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WBMP) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WEBP) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_webp__error__bad_huffman_code_over_subscribed[]; extern const char wuffs_webp__error__bad_huffman_code_under_subscribed[]; extern const char wuffs_webp__error__bad_huffman_code[]; extern const char wuffs_webp__error__bad_back_reference[]; extern const char wuffs_webp__error__bad_color_cache[]; extern const char wuffs_webp__error__bad_header[]; extern const char wuffs_webp__error__bad_transform[]; extern const char wuffs_webp__error__short_chunk[]; extern const char wuffs_webp__error__truncated_input[]; extern const char wuffs_webp__error__unsupported_number_of_huffman_groups[]; extern const char wuffs_webp__error__unsupported_transform_after_color_indexing_transform[]; extern const char wuffs_webp__error__unsupported_webp_file[]; // ---------------- Public Consts #define WUFFS_WEBP__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 0u // ---------------- Struct Declarations typedef struct wuffs_webp__decoder__struct wuffs_webp__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_webp__decoder__initialize( wuffs_webp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_webp__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_webp__decoder* wuffs_webp__decoder__alloc(void); static inline wuffs_base__image_decoder* wuffs_webp__decoder__alloc_as__wuffs_base__image_decoder(void) { return (wuffs_base__image_decoder*)(wuffs_webp__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__image_decoder* wuffs_webp__decoder__upcast_as__wuffs_base__image_decoder( wuffs_webp__decoder* p) { return (wuffs_base__image_decoder*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__get_quirk( const wuffs_webp__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__set_quirk( wuffs_webp__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_image_config( wuffs_webp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_frame_config( wuffs_webp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_frame( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_webp__decoder__frame_dirty_rect( const wuffs_webp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_webp__decoder__num_animation_loops( const wuffs_webp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__num_decoded_frame_configs( const wuffs_webp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__num_decoded_frames( const wuffs_webp__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__restart_frame( wuffs_webp__decoder* self, uint64_t a_index, uint64_t a_io_position); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_webp__decoder__set_report_metadata( wuffs_webp__decoder* self, uint32_t a_fourcc, bool a_report); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__tell_me_more( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_webp__decoder__workbuf_len( const wuffs_webp__decoder* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_webp__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__image_decoder; wuffs_base__vtable null_vtable; uint32_t f_pixfmt; uint32_t f_width; uint32_t f_height; uint8_t f_call_sequence; uint8_t f_code_length_code_lengths[19]; bool f_sub_chunk_has_padding; uint64_t f_frame_config_io_position; uint32_t f_riff_chunk_length; uint32_t f_sub_chunk_length; uint32_t f_bits; uint32_t f_n_bits; bool f_seen_transform[4]; uint8_t f_transform_type[4]; uint8_t f_transform_tile_size_log2[4]; uint32_t f_n_transforms; uint32_t f_color_cache_bits; uint32_t f_overall_color_cache_bits; uint32_t f_overall_tile_size_log2; uint32_t f_overall_n_huffman_groups; uint32_t f_ht_n_symbols; uint32_t f_ht_code_lengths_remaining; uint32_t f_color_indexing_palette_size; uint32_t f_color_indexing_width; uint32_t f_workbuf_offset_for_transform[4]; uint32_t f_workbuf_offset_for_color_indexing; wuffs_base__pixel_swizzler f_swizzler; uint32_t p_decode_huffman_groups; uint32_t p_decode_huffman_tree; uint32_t p_decode_huffman_tree_simple; uint32_t p_decode_code_length_code_lengths; uint32_t p_build_code_lengths; uint32_t p_decode_pixels_slow; uint32_t p_decode_image_config; uint32_t p_do_decode_image_config; uint32_t p_do_decode_image_config_limited; uint32_t p_do_decode_image_config_limited_vp8l; uint32_t p_decode_frame_config; uint32_t p_do_decode_frame_config; uint32_t p_decode_frame; uint32_t p_do_decode_frame; uint32_t p_decode_transform; uint32_t p_decode_color_cache_parameters; uint32_t p_decode_hg_table; uint32_t p_decode_pixels; } private_impl; struct { uint8_t f_palette[1024]; uint32_t f_color_cache[2048]; uint16_t f_codes[2328]; uint16_t f_code_lengths[2328]; uint16_t f_code_lengths_huffman_nodes[37]; uint16_t f_huffman_nodes[256][6267]; struct { uint32_t v_hg; uint32_t v_ht; } s_decode_huffman_groups; struct { uint32_t v_use_second_symbol; uint32_t v_first_symbol_n_bits; uint32_t v_symbol0; uint32_t v_base_offset; } s_decode_huffman_tree_simple; struct { uint32_t v_n_codes; uint32_t v_i; } s_decode_code_length_code_lengths; struct { uint32_t v_length_n_bits; uint16_t v_prev_code_length; uint32_t v_s; uint32_t v_s_max; uint16_t v_node; uint16_t v_repeat_value; uint32_t v_repeat_n_bits; } s_build_code_lengths; struct { uint64_t v_p; uint64_t v_p_max; uint32_t v_tile_size_log2; uint32_t v_width_in_tiles; uint32_t v_x; uint32_t v_y; uint32_t v_hg; uint16_t v_node; uint32_t v_color; uint32_t v_back_ref_len_n_bits; uint32_t v_back_ref_len_minus_1; uint32_t v_back_ref_dist_n_bits; uint32_t v_back_ref_dist_premap_minus_1; uint64_t v_color_cache_p; } s_decode_pixels_slow; struct { uint64_t scratch; } s_do_decode_image_config; struct { uint64_t scratch; } s_do_decode_image_config_limited; struct { uint64_t scratch; } s_do_decode_image_config_limited_vp8l; struct { uint32_t v_width; } s_do_decode_frame; struct { uint32_t v_transform_type; uint32_t v_tile_size_log2; } s_decode_transform; struct { uint32_t v_tile_size_log2; } s_decode_hg_table; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_webp__decoder__alloc()); } static inline wuffs_base__image_decoder::unique_ptr alloc_as__wuffs_base__image_decoder() { return wuffs_base__image_decoder::unique_ptr( wuffs_webp__decoder__alloc_as__wuffs_base__image_decoder()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_webp__decoder__struct() = delete; wuffs_webp__decoder__struct(const wuffs_webp__decoder__struct&) = delete; wuffs_webp__decoder__struct& operator=( const wuffs_webp__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_webp__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__image_decoder* upcast_as__wuffs_base__image_decoder() { return (wuffs_base__image_decoder*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_webp__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_webp__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__status decode_image_config( wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_webp__decoder__decode_image_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame_config( wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { return wuffs_webp__decoder__decode_frame_config(this, a_dst, a_src); } inline wuffs_base__status decode_frame( wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { return wuffs_webp__decoder__decode_frame(this, a_dst, a_src, a_blend, a_workbuf, a_opts); } inline wuffs_base__rect_ie_u32 frame_dirty_rect() const { return wuffs_webp__decoder__frame_dirty_rect(this); } inline uint32_t num_animation_loops() const { return wuffs_webp__decoder__num_animation_loops(this); } inline uint64_t num_decoded_frame_configs() const { return wuffs_webp__decoder__num_decoded_frame_configs(this); } inline uint64_t num_decoded_frames() const { return wuffs_webp__decoder__num_decoded_frames(this); } inline wuffs_base__status restart_frame( uint64_t a_index, uint64_t a_io_position) { return wuffs_webp__decoder__restart_frame(this, a_index, a_io_position); } inline wuffs_base__empty_struct set_report_metadata( uint32_t a_fourcc, bool a_report) { return wuffs_webp__decoder__set_report_metadata(this, a_fourcc, a_report); } inline wuffs_base__status tell_me_more( wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_webp__decoder__tell_me_more(this, a_dst, a_minfo, a_src); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_webp__decoder__workbuf_len(this); } #endif // __cplusplus }; // struct wuffs_webp__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WEBP) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH32) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_xxhash32__hasher__struct wuffs_xxhash32__hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xxhash32__hasher__initialize( wuffs_xxhash32__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_xxhash32__hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_xxhash32__hasher* wuffs_xxhash32__hasher__alloc(void); static inline wuffs_base__hasher_u32* wuffs_xxhash32__hasher__alloc_as__wuffs_base__hasher_u32(void) { return (wuffs_base__hasher_u32*)(wuffs_xxhash32__hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_u32* wuffs_xxhash32__hasher__upcast_as__wuffs_base__hasher_u32( wuffs_xxhash32__hasher* p) { return (wuffs_base__hasher_u32*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash32__hasher__get_quirk( const wuffs_xxhash32__hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xxhash32__hasher__set_quirk( wuffs_xxhash32__hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_xxhash32__hasher__update( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_xxhash32__hasher__update_u32( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_xxhash32__hasher__checksum_u32( const wuffs_xxhash32__hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_xxhash32__hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_u32; wuffs_base__vtable null_vtable; uint32_t f_length_modulo_u32; bool f_length_overflows_u32; uint8_t f_padding0; uint8_t f_padding1; uint8_t f_buf_len; uint8_t f_buf_data[16]; uint32_t f_v0; uint32_t f_v1; uint32_t f_v2; uint32_t f_v3; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_xxhash32__hasher__alloc()); } static inline wuffs_base__hasher_u32::unique_ptr alloc_as__wuffs_base__hasher_u32() { return wuffs_base__hasher_u32::unique_ptr( wuffs_xxhash32__hasher__alloc_as__wuffs_base__hasher_u32()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_xxhash32__hasher__struct() = delete; wuffs_xxhash32__hasher__struct(const wuffs_xxhash32__hasher__struct&) = delete; wuffs_xxhash32__hasher__struct& operator=( const wuffs_xxhash32__hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_xxhash32__hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_u32* upcast_as__wuffs_base__hasher_u32() { return (wuffs_base__hasher_u32*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_xxhash32__hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_xxhash32__hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_xxhash32__hasher__update(this, a_x); } inline uint32_t update_u32( wuffs_base__slice_u8 a_x) { return wuffs_xxhash32__hasher__update_u32(this, a_x); } inline uint32_t checksum_u32() const { return wuffs_xxhash32__hasher__checksum_u32(this); } #endif // __cplusplus }; // struct wuffs_xxhash32__hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH32) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH64) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes // ---------------- Public Consts // ---------------- Struct Declarations typedef struct wuffs_xxhash64__hasher__struct wuffs_xxhash64__hasher; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xxhash64__hasher__initialize( wuffs_xxhash64__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_xxhash64__hasher(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_xxhash64__hasher* wuffs_xxhash64__hasher__alloc(void); static inline wuffs_base__hasher_u64* wuffs_xxhash64__hasher__alloc_as__wuffs_base__hasher_u64(void) { return (wuffs_base__hasher_u64*)(wuffs_xxhash64__hasher__alloc()); } // ---------------- Upcasts static inline wuffs_base__hasher_u64* wuffs_xxhash64__hasher__upcast_as__wuffs_base__hasher_u64( wuffs_xxhash64__hasher* p) { return (wuffs_base__hasher_u64*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__get_quirk( const wuffs_xxhash64__hasher* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xxhash64__hasher__set_quirk( wuffs_xxhash64__hasher* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_xxhash64__hasher__update( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__update_u64( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__checksum_u64( const wuffs_xxhash64__hasher* self); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_xxhash64__hasher__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__hasher_u64; wuffs_base__vtable null_vtable; uint64_t f_length_modulo_u64; bool f_length_overflows_u64; uint8_t f_padding0; uint8_t f_padding1; uint8_t f_padding2; uint32_t f_buf_len; uint8_t f_buf_data[32]; uint64_t f_v0; uint64_t f_v1; uint64_t f_v2; uint64_t f_v3; } private_impl; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_xxhash64__hasher__alloc()); } static inline wuffs_base__hasher_u64::unique_ptr alloc_as__wuffs_base__hasher_u64() { return wuffs_base__hasher_u64::unique_ptr( wuffs_xxhash64__hasher__alloc_as__wuffs_base__hasher_u64()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_xxhash64__hasher__struct() = delete; wuffs_xxhash64__hasher__struct(const wuffs_xxhash64__hasher__struct&) = delete; wuffs_xxhash64__hasher__struct& operator=( const wuffs_xxhash64__hasher__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_xxhash64__hasher__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__hasher_u64* upcast_as__wuffs_base__hasher_u64() { return (wuffs_base__hasher_u64*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_xxhash64__hasher__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_xxhash64__hasher__set_quirk(this, a_key, a_value); } inline wuffs_base__empty_struct update( wuffs_base__slice_u8 a_x) { return wuffs_xxhash64__hasher__update(this, a_x); } inline uint64_t update_u64( wuffs_base__slice_u8 a_x) { return wuffs_xxhash64__hasher__update_u64(this, a_x); } inline uint64_t checksum_u64() const { return wuffs_xxhash64__hasher__checksum_u64(this); } #endif // __cplusplus }; // struct wuffs_xxhash64__hasher__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH64) || defined(WUFFS_NONMONOLITHIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XZ) || defined(WUFFS_NONMONOLITHIC) // ---------------- Status Codes extern const char wuffs_xz__error__bad_bcj_offset[]; extern const char wuffs_xz__error__bad_block_header[]; extern const char wuffs_xz__error__bad_checksum[]; extern const char wuffs_xz__error__bad_filter[]; extern const char wuffs_xz__error__bad_footer[]; extern const char wuffs_xz__error__bad_header[]; extern const char wuffs_xz__error__bad_header_concatenated_stream[]; extern const char wuffs_xz__error__bad_index[]; extern const char wuffs_xz__error__bad_padding[]; extern const char wuffs_xz__error__truncated_input[]; extern const char wuffs_xz__error__unsupported_checksum_algorithm[]; extern const char wuffs_xz__error__unsupported_filter[]; extern const char wuffs_xz__error__unsupported_filter_combination[]; // ---------------- Public Consts #define WUFFS_XZ__QUIRK_DECODE_STANDALONE_CONCATENATED_STREAMS 2021322752u #define WUFFS_XZ__DECODER_DST_HISTORY_RETAIN_LENGTH_MAX_INCL_WORST_CASE 0u #define WUFFS_XZ__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE 4294967568u // ---------------- Struct Declarations typedef struct wuffs_xz__decoder__struct wuffs_xz__decoder; #ifdef __cplusplus extern "C" { #endif // ---------------- Public Initializer Prototypes // For any given "wuffs_foo__bar* self", "wuffs_foo__bar__initialize(self, // etc)" should be called before any other "wuffs_foo__bar__xxx(self, etc)". // // Pass sizeof(*self) and WUFFS_VERSION for sizeof_star_self and wuffs_version. // Pass 0 (or some combination of WUFFS_INITIALIZE__XXX) for options. wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xz__decoder__initialize( wuffs_xz__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options); size_t sizeof__wuffs_xz__decoder(void); // ---------------- Allocs // These functions allocate and initialize Wuffs structs. They return NULL if // memory allocation fails. If they return non-NULL, there is no need to call // wuffs_foo__bar__initialize, but the caller is responsible for eventually // calling free on the returned pointer. That pointer is effectively a C++ // std::unique_ptr. wuffs_xz__decoder* wuffs_xz__decoder__alloc(void); static inline wuffs_base__io_transformer* wuffs_xz__decoder__alloc_as__wuffs_base__io_transformer(void) { return (wuffs_base__io_transformer*)(wuffs_xz__decoder__alloc()); } // ---------------- Upcasts static inline wuffs_base__io_transformer* wuffs_xz__decoder__upcast_as__wuffs_base__io_transformer( wuffs_xz__decoder* p) { return (wuffs_base__io_transformer*)p; } // ---------------- Public Function Prototypes WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xz__decoder__get_quirk( const wuffs_xz__decoder* self, uint32_t a_key); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xz__decoder__set_quirk( wuffs_xz__decoder* self, uint32_t a_key, uint64_t a_value); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_xz__decoder__dst_history_retain_length( const wuffs_xz__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_xz__decoder__workbuf_len( const wuffs_xz__decoder* self); WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xz__decoder__transform_io( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); #ifdef __cplusplus } // extern "C" #endif // ---------------- Struct Definitions // These structs' fields, and the sizeof them, are private implementation // details that aren't guaranteed to be stable across Wuffs versions. // // See https://en.wikipedia.org/wiki/Opaque_pointer#C #if defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) struct wuffs_xz__decoder__struct { // Do not access the private_impl's or private_data's fields directly. There // is no API/ABI compatibility or safety guarantee if you do so. Instead, use // the wuffs_foo__bar__baz functions. // // It is a struct, not a struct*, so that the outermost wuffs_foo__bar struct // can be stack allocated when WUFFS_IMPLEMENTATION is defined. struct { uint32_t magic; uint32_t active_coroutine; wuffs_base__vtable vtable_for__wuffs_base__io_transformer; wuffs_base__vtable null_vtable; uint32_t f_filters[3]; uint32_t f_num_non_final_filters; uint8_t f_checksummer; bool f_ignore_checksum; bool f_standalone_format; bool f_lzma_needs_reset; bool f_block_has_compressed_size; bool f_block_has_uncompressed_size; uint8_t f_bcj_undo_index; uint32_t f_bcj_pos; uint32_t f_bcj_x86_prev_mask; uint64_t f_block_compressed_size; uint64_t f_block_uncompressed_size; uint64_t f_compressed_size_for_index; uint32_t f_verification_have_hashed_sizes[2]; uint32_t f_verification_want_hashed_sizes[2]; uint64_t f_verification_have_total_sizes[2]; uint64_t f_verification_want_total_sizes[2]; uint64_t f_num_actual_blocks; uint64_t f_num_index_blocks; uint64_t f_index_block_compressed_size; uint64_t f_index_block_uncompressed_size; uint64_t f_backwards_size; bool f_started_verify_index; uint16_t f_flags; uint8_t (*choosy_apply_non_final_filters)( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); uint32_t p_transform_io; uint32_t p_do_transform_io; uint32_t p_decode_block_header_with_padding; uint32_t p_decode_block_header_sans_padding; uint32_t p_verify_index; uint32_t p_verify_footer; } private_impl; struct { uint8_t f_filter_data[3][256]; wuffs_crc32__ieee_hasher f_crc32; wuffs_crc64__ecma_hasher f_crc64; wuffs_sha256__hasher f_sha256; wuffs_lzma__decoder f_lzma; struct { uint32_t v_checksum32_have; uint32_t v_checksum32_want; wuffs_base__bitvec256 v_checksum256_have; uint64_t v_compressed_size; uint64_t v_uncompressed_size; uint64_t scratch; } s_do_transform_io; struct { uint64_t v_padded_size_have; uint64_t v_padded_size_want; } s_decode_block_header_with_padding; struct { uint8_t v_flags; uint8_t v_filter_id; uint32_t v_shift; uint32_t v_f; uint64_t scratch; } s_decode_block_header_sans_padding; struct { uint32_t v_shift; } s_verify_index; struct { uint64_t scratch; } s_verify_footer; } private_data; #ifdef __cplusplus #if defined(WUFFS_BASE__HAVE_UNIQUE_PTR) using unique_ptr = std::unique_ptr; // On failure, the alloc_etc functions return nullptr. They don't throw. static inline unique_ptr alloc() { return unique_ptr(wuffs_xz__decoder__alloc()); } static inline wuffs_base__io_transformer::unique_ptr alloc_as__wuffs_base__io_transformer() { return wuffs_base__io_transformer::unique_ptr( wuffs_xz__decoder__alloc_as__wuffs_base__io_transformer()); } #endif // defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #if defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) // Disallow constructing or copying an object via standard C++ mechanisms, // e.g. the "new" operator, as this struct is intentionally opaque. Its total // size and field layout is not part of the public, stable, memory-safe API. // Use malloc or memcpy and the sizeof__wuffs_foo__bar function instead, and // call wuffs_foo__bar__baz methods (which all take a "this"-like pointer as // their first argument) rather than tweaking bar.private_impl.qux fields. // // In C, we can just leave wuffs_foo__bar as an incomplete type (unless // WUFFS_IMPLEMENTATION is #define'd). In C++, we define a complete type in // order to provide convenience methods. These forward on "this", so that you // can write "bar->baz(etc)" instead of "wuffs_foo__bar__baz(bar, etc)". wuffs_xz__decoder__struct() = delete; wuffs_xz__decoder__struct(const wuffs_xz__decoder__struct&) = delete; wuffs_xz__decoder__struct& operator=( const wuffs_xz__decoder__struct&) = delete; #endif // defined(WUFFS_BASE__HAVE_EQ_DELETE) && !defined(WUFFS_IMPLEMENTATION) #if !defined(WUFFS_IMPLEMENTATION) // As above, the size of the struct is not part of the public API, and unless // WUFFS_IMPLEMENTATION is #define'd, this struct type T should be heap // allocated, not stack allocated. Its size is not intended to be known at // compile time, but it is unfortunately divulged as a side effect of // defining C++ convenience methods. Use "sizeof__T()", calling the function, // instead of "sizeof T", invoking the operator. To make the two values // different, so that passing the latter will be rejected by the initialize // function, we add an arbitrary amount of dead weight. uint8_t dead_weight[123000000]; // 123 MB. #endif // !defined(WUFFS_IMPLEMENTATION) inline wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT initialize( size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options) { return wuffs_xz__decoder__initialize( this, sizeof_star_self, wuffs_version, options); } inline wuffs_base__io_transformer* upcast_as__wuffs_base__io_transformer() { return (wuffs_base__io_transformer*)this; } inline uint64_t get_quirk( uint32_t a_key) const { return wuffs_xz__decoder__get_quirk(this, a_key); } inline wuffs_base__status set_quirk( uint32_t a_key, uint64_t a_value) { return wuffs_xz__decoder__set_quirk(this, a_key, a_value); } inline wuffs_base__optional_u63 dst_history_retain_length() const { return wuffs_xz__decoder__dst_history_retain_length(this); } inline wuffs_base__range_ii_u64 workbuf_len() const { return wuffs_xz__decoder__workbuf_len(this); } inline wuffs_base__status transform_io( wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { return wuffs_xz__decoder__transform_io(this, a_dst, a_src, a_workbuf); } #endif // __cplusplus }; // struct wuffs_xz__decoder__struct #endif // defined(__cplusplus) || defined(WUFFS_IMPLEMENTATION) #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XZ) || defined(WUFFS_NONMONOLITHIC) #if defined(__cplusplus) && defined(WUFFS_BASE__HAVE_UNIQUE_PTR) // ---------------- Auxiliary - Base // Auxiliary code is discussed at // https://github.com/google/wuffs/blob/main/doc/note/auxiliary-code.md #include #include #include namespace wuffs_aux { using IOBuffer = wuffs_base__io_buffer; // MemOwner represents ownership of some memory. Dynamically allocated memory // (e.g. from malloc or new) is typically paired with free or delete, invoked // when the std::unique_ptr is destroyed. Statically allocated memory might use // MemOwner(nullptr, &free), even if that statically allocated memory is not // nullptr, since calling free(nullptr) is a no-op. using MemOwner = std::unique_ptr; using QuirkKeyValuePair = std::pair; namespace sync_io { // -------- // DynIOBuffer is an IOBuffer that is backed by a dynamically sized byte array. // It owns that backing array and will free it in its destructor. // // The array size can be explicitly extended (by calling the grow method) but, // unlike a C++ std::vector, there is no implicit extension (e.g. by calling // std::vector::insert) and its maximum size is capped by the max_incl // constructor argument. // // It contains an IOBuffer-typed field whose reader side provides access to // previously written bytes and whose writer side provides access to the // allocated but not-yet-written-to slack space. For Go programmers, this slack // space is roughly analogous to the s[len(s):cap(s)] space of a slice s. class DynIOBuffer { public: enum GrowResult { OK = 0, FailedMaxInclExceeded = 1, FailedOutOfMemory = 2, }; // m_buf holds the dynamically sized byte array and its read/write indexes: // - m_buf.meta.wi is roughly analogous to a Go slice's length. // - m_buf.data.len is roughly analogous to a Go slice's capacity. It is // also equal to the m_buf.data.ptr malloc/realloc size. // // Users should not modify the m_buf.data.ptr or m_buf.data.len fields (as // they are conceptually private to this class), but they can modify the // bytes referenced by that pointer-length pair (e.g. compactions). IOBuffer m_buf; // m_max_incl is an inclusive upper bound on the backing array size. const uint64_t m_max_incl; // Constructor and destructor. explicit DynIOBuffer(uint64_t max_incl); ~DynIOBuffer(); // Drop frees the byte array and resets m_buf. The DynIOBuffer can still be // used after a drop call. It just restarts from zero. void drop(); // grow ensures that the byte array size is at least min_incl and at most // max_incl. It returns FailedMaxInclExceeded if that would require // allocating more than max_incl bytes, including the case where (min_incl > // max_incl). It returns FailedOutOfMemory if memory allocation failed. GrowResult grow(uint64_t min_incl); private: // Delete the copy and assign constructors. DynIOBuffer(const DynIOBuffer&) = delete; DynIOBuffer& operator=(const DynIOBuffer&) = delete; static uint64_t round_up(uint64_t min_incl, uint64_t max_incl); }; // -------- class Input { public: virtual ~Input(); virtual IOBuffer* BringsItsOwnIOBuffer(); virtual std::string CopyIn(IOBuffer* dst) = 0; }; // -------- // FileInput is an Input that reads from a file source. // // It does not take responsibility for closing the file when done. class FileInput : public Input { public: FileInput(FILE* f); virtual std::string CopyIn(IOBuffer* dst); private: FILE* m_f; // Delete the copy and assign constructors. FileInput(const FileInput&) = delete; FileInput& operator=(const FileInput&) = delete; }; // -------- // MemoryInput is an Input that reads from an in-memory source. // // It does not take responsibility for freeing the memory when done. class MemoryInput : public Input { public: MemoryInput(const char* ptr, size_t len); MemoryInput(const uint8_t* ptr, size_t len); virtual IOBuffer* BringsItsOwnIOBuffer(); virtual std::string CopyIn(IOBuffer* dst); private: IOBuffer m_io; // Delete the copy and assign constructors. MemoryInput(const MemoryInput&) = delete; MemoryInput& operator=(const MemoryInput&) = delete; }; // -------- } // namespace sync_io } // namespace wuffs_aux // ---------------- Auxiliary - CBOR namespace wuffs_aux { struct DecodeCborResult { DecodeCborResult(std::string&& error_message0, uint64_t cursor_position0); std::string error_message; uint64_t cursor_position; }; class DecodeCborCallbacks { public: virtual ~DecodeCborCallbacks(); // AppendXxx are called for leaf nodes: literals, numbers, strings, etc. virtual std::string AppendNull() = 0; virtual std::string AppendUndefined() = 0; virtual std::string AppendBool(bool val) = 0; virtual std::string AppendF64(double val) = 0; virtual std::string AppendI64(int64_t val) = 0; virtual std::string AppendU64(uint64_t val) = 0; virtual std::string AppendByteString(std::string&& val) = 0; virtual std::string AppendTextString(std::string&& val) = 0; virtual std::string AppendMinus1MinusX(uint64_t val) = 0; virtual std::string AppendCborSimpleValue(uint8_t val) = 0; virtual std::string AppendCborTag(uint64_t val) = 0; // Push and Pop are called for container nodes: CBOR arrays (lists) and CBOR // maps (dictionaries). // // The flags bits combine exactly one of: // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_NONE // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_LIST // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_DICT // and exactly one of: // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_NONE // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_LIST // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_DICT virtual std::string Push(uint32_t flags) = 0; virtual std::string Pop(uint32_t flags) = 0; // Done is always the last Callback method called by DecodeCbor, whether or // not parsing the input as CBOR encountered an error. Even when successful, // trailing data may remain in input and buffer. // // Do not keep a reference to buffer or buffer.data.ptr after Done returns, // as DecodeCbor may then de-allocate the backing array. // // The default Done implementation is a no-op. virtual void // Done(DecodeCborResult& result, sync_io::Input& input, IOBuffer& buffer); }; // The FooArgBar types add structure to Foo's optional arguments. They wrap // inner representations for several reasons: // - It provides a home for the DefaultValue static method, for Foo callers // that want to override some but not all optional arguments. // - It provides the "Bar" name at Foo call sites, which can help self- // document Foo calls with many arguemnts. // - It provides some type safety against accidentally transposing or omitting // adjacent fundamentally-numeric-typed optional arguments. // DecodeCborArgQuirks wraps an optional argument to DecodeCbor. struct DecodeCborArgQuirks { explicit DecodeCborArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0); // DefaultValue returns an empty slice. static DecodeCborArgQuirks DefaultValue(); const QuirkKeyValuePair* ptr; const size_t len; }; // DecodeCbor calls callbacks based on the CBOR-formatted data in input. // // On success, the returned error_message is empty and cursor_position counts // the number of bytes consumed. On failure, error_message is non-empty and // cursor_position is the location of the error. That error may be a content // error (invalid CBOR) or an input error (e.g. network failure). DecodeCborResult // DecodeCbor(DecodeCborCallbacks& callbacks, sync_io::Input& input, DecodeCborArgQuirks quirks = DecodeCborArgQuirks::DefaultValue()); } // namespace wuffs_aux // ---------------- Auxiliary - Image namespace wuffs_aux { struct DecodeImageResult { DecodeImageResult(MemOwner&& pixbuf_mem_owner0, wuffs_base__pixel_buffer pixbuf0, std::string&& error_message0); DecodeImageResult(std::string&& error_message0); MemOwner pixbuf_mem_owner; wuffs_base__pixel_buffer pixbuf; std::string error_message; }; // DecodeImageCallbacks are the callbacks given to DecodeImage. They are always // called in this order: // 1. SelectDecoder // 2. HandleMetadata // 3. SelectPixfmt // 4. AllocPixbuf // 5. AllocWorkbuf // 6. Done // // It may return early - the third callback might not be invoked if the second // one fails - but the final callback (Done) is always invoked. class DecodeImageCallbacks { public: // AllocPixbufResult holds a memory allocation (the result of malloc or new, // a statically allocated pointer, etc), or an error message. The memory is // de-allocated when mem_owner goes out of scope and is destroyed. struct AllocPixbufResult { AllocPixbufResult(MemOwner&& mem_owner0, wuffs_base__pixel_buffer pixbuf0); AllocPixbufResult(std::string&& error_message0); MemOwner mem_owner; wuffs_base__pixel_buffer pixbuf; std::string error_message; }; // AllocWorkbufResult holds a memory allocation (the result of malloc or new, // a statically allocated pointer, etc), or an error message. The memory is // de-allocated when mem_owner goes out of scope and is destroyed. struct AllocWorkbufResult { AllocWorkbufResult(MemOwner&& mem_owner0, wuffs_base__slice_u8 workbuf0); AllocWorkbufResult(std::string&& error_message0); MemOwner mem_owner; wuffs_base__slice_u8 workbuf; std::string error_message; }; virtual ~DecodeImageCallbacks(); // SelectDecoder returns the image decoder for the input data's file format. // Returning a nullptr means failure (DecodeImage_UnsupportedImageFormat). // // Common formats will have a FourCC value in the range [1 ..= 0x7FFF_FFFF], // such as WUFFS_BASE__FOURCC__JPEG. A zero FourCC value means that Wuffs' // standard library did not recognize the image format but if SelectDecoder // was overridden, it may examine the input data's starting bytes and still // provide its own image decoder, e.g. for an exotic image file format that's // not in Wuffs' standard library. The prefix_etc fields have the same // meaning as wuffs_base__magic_number_guess_fourcc arguments. SelectDecoder // implementations should not modify prefix_data's contents. // // SelectDecoder might be called more than once, since some image file // formats can wrap others. For example, a nominal BMP file can actually // contain a JPEG or a PNG. // // The default SelectDecoder accepts the FOURCC codes listed below. For // modular builds (i.e. when #define'ing WUFFS_CONFIG__MODULES), acceptance // of the ETC file format is optional (for each value of ETC) and depends on // the corresponding module to be enabled at compile time (i.e. #define'ing // WUFFS_CONFIG__MODULE__ETC). // - WUFFS_BASE__FOURCC__BMP // - WUFFS_BASE__FOURCC__GIF // - WUFFS_BASE__FOURCC__JPEG // - WUFFS_BASE__FOURCC__NIE // - WUFFS_BASE__FOURCC__NPBM // - WUFFS_BASE__FOURCC__PNG // - WUFFS_BASE__FOURCC__QOI // - WUFFS_BASE__FOURCC__TGA // - WUFFS_BASE__FOURCC__WBMP // - WUFFS_BASE__FOURCC__WEBP virtual wuffs_base__image_decoder::unique_ptr // SelectDecoder(uint32_t fourcc, wuffs_base__slice_u8 prefix_data, bool prefix_closed); // HandleMetadata acknowledges image metadata. minfo.flavor will be one of: // - WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_RAW_PASSTHROUGH // - WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_PARSED // If it is ETC__METADATA_RAW_ETC then raw contains the metadata bytes. Those // bytes should not be retained beyond the the HandleMetadata call. // // minfo.metadata__fourcc() will typically match one of the // DecodeImageArgFlags bits. For example, if (REPORT_METADATA_CHRM | // REPORT_METADATA_GAMA) was passed to DecodeImage then the metadata FourCC // will be either WUFFS_BASE__FOURCC__CHRM or WUFFS_BASE__FOURCC__GAMA. // // It returns an error message, or an empty string on success. virtual std::string // HandleMetadata(const wuffs_base__more_information& minfo, wuffs_base__slice_u8 raw); // SelectPixfmt returns the destination pixel format for AllocPixbuf. It // should return wuffs_base__make_pixel_format(etc) called with one of: // - WUFFS_BASE__PIXEL_FORMAT__BGR_565 // - WUFFS_BASE__PIXEL_FORMAT__BGR // - WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL // - WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE // - WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL // - WUFFS_BASE__PIXEL_FORMAT__RGB // - WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL // - WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL // or return image_config.pixcfg.pixel_format(). The latter means to use the // image file's natural pixel format. For example, GIF images' natural pixel // format is an indexed one. // // Returning otherwise means failure (DecodeImage_UnsupportedPixelFormat). // // The default SelectPixfmt implementation returns // wuffs_base__make_pixel_format(WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL) which // is 4 bytes per pixel (8 bits per channel × 4 channels). virtual wuffs_base__pixel_format // SelectPixfmt(const wuffs_base__image_config& image_config); // AllocPixbuf allocates the pixel buffer. // // allow_uninitialized_memory will be true if a valid background_color was // passed to DecodeImage, since the pixel buffer's contents will be // overwritten with that color after AllocPixbuf returns. // // The default AllocPixbuf implementation allocates either uninitialized or // zeroed memory. Zeroed memory typically corresponds to filling with opaque // black or transparent black, depending on the pixel format. virtual AllocPixbufResult // AllocPixbuf(const wuffs_base__image_config& image_config, bool allow_uninitialized_memory); // AllocWorkbuf allocates the work buffer. The allocated buffer's length // should be at least len_range.min_incl, but larger allocations (up to // len_range.max_incl) may have better performance (by using more memory). // // The default AllocWorkbuf implementation allocates len_range.max_incl bytes // of either uninitialized or zeroed memory. virtual AllocWorkbufResult // AllocWorkbuf(wuffs_base__range_ii_u64 len_range, bool allow_uninitialized_memory); // Done is always the last Callback method called by DecodeImage, whether or // not parsing the input encountered an error. Even when successful, trailing // data may remain in input and buffer. // // The image_decoder is the one returned by SelectDecoder (if SelectDecoder // was successful), or a no-op unique_ptr otherwise. Like any unique_ptr, // ownership moves to the Done implementation. // // Do not keep a reference to buffer or buffer.data.ptr after Done returns, // as DecodeImage may then de-allocate the backing array. // // The default Done implementation is a no-op, other than running the // image_decoder unique_ptr destructor. virtual void // Done(DecodeImageResult& result, sync_io::Input& input, IOBuffer& buffer, wuffs_base__image_decoder::unique_ptr image_decoder); }; extern const char DecodeImage_BufferIsTooShort[]; extern const char DecodeImage_MaxInclDimensionExceeded[]; extern const char DecodeImage_MaxInclMetadataLengthExceeded[]; extern const char DecodeImage_OutOfMemory[]; extern const char DecodeImage_UnexpectedEndOfFile[]; extern const char DecodeImage_UnsupportedImageFormat[]; extern const char DecodeImage_UnsupportedMetadata[]; extern const char DecodeImage_UnsupportedPixelBlend[]; extern const char DecodeImage_UnsupportedPixelConfiguration[]; extern const char DecodeImage_UnsupportedPixelFormat[]; // The FooArgBar types add structure to Foo's optional arguments. They wrap // inner representations for several reasons: // - It provides a home for the DefaultValue static method, for Foo callers // that want to override some but not all optional arguments. // - It provides the "Bar" name at Foo call sites, which can help self- // document Foo calls with many arguemnts. // - It provides some type safety against accidentally transposing or omitting // adjacent fundamentally-numeric-typed optional arguments. // DecodeImageArgQuirks wraps an optional argument to DecodeImage. struct DecodeImageArgQuirks { explicit DecodeImageArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0); // DefaultValue returns an empty slice. static DecodeImageArgQuirks DefaultValue(); const QuirkKeyValuePair* ptr; const size_t len; }; // DecodeImageArgFlags wraps an optional argument to DecodeImage. struct DecodeImageArgFlags { explicit DecodeImageArgFlags(uint64_t repr0); // DefaultValue returns 0. static DecodeImageArgFlags DefaultValue(); // TODO: support all of the REPORT_METADATA_ETC flags, not just CHRM, EXIF, // GAMA, ICCP, KVP, SRGB and XMP. // Background Color. static constexpr uint64_t REPORT_METADATA_BGCL = 0x0001; // Primary Chromaticities and White Point. static constexpr uint64_t REPORT_METADATA_CHRM = 0x0002; // Exchangeable Image File Format. static constexpr uint64_t REPORT_METADATA_EXIF = 0x0004; // Gamma Correction. static constexpr uint64_t REPORT_METADATA_GAMA = 0x0008; // International Color Consortium Profile. static constexpr uint64_t REPORT_METADATA_ICCP = 0x0010; // Key-Value Pair. // // For PNG files, this includes iTXt, tEXt and zTXt chunks. In the // HandleMetadata callback, the raw argument contains UTF-8 strings. static constexpr uint64_t REPORT_METADATA_KVP = 0x0020; // Modification Time. static constexpr uint64_t REPORT_METADATA_MTIM = 0x0040; // Offset (2-Dimensional). static constexpr uint64_t REPORT_METADATA_OFS2 = 0x0080; // Physical Dimensions. static constexpr uint64_t REPORT_METADATA_PHYD = 0x0100; // Standard Red Green Blue (Rendering Intent). static constexpr uint64_t REPORT_METADATA_SRGB = 0x0200; // Extensible Metadata Platform. static constexpr uint64_t REPORT_METADATA_XMP = 0x0400; uint64_t repr; }; // DecodeImageArgPixelBlend wraps an optional argument to DecodeImage. struct DecodeImageArgPixelBlend { explicit DecodeImageArgPixelBlend(wuffs_base__pixel_blend repr0); // DefaultValue returns WUFFS_BASE__PIXEL_BLEND__SRC. static DecodeImageArgPixelBlend DefaultValue(); wuffs_base__pixel_blend repr; }; // DecodeImageArgBackgroundColor wraps an optional argument to DecodeImage. struct DecodeImageArgBackgroundColor { explicit DecodeImageArgBackgroundColor( wuffs_base__color_u32_argb_premul repr0); // DefaultValue returns 1, an invalid wuffs_base__color_u32_argb_premul. static DecodeImageArgBackgroundColor DefaultValue(); wuffs_base__color_u32_argb_premul repr; }; // DecodeImageArgMaxInclDimension wraps an optional argument to DecodeImage. struct DecodeImageArgMaxInclDimension { explicit DecodeImageArgMaxInclDimension(uint32_t repr0); // DefaultValue returns 1048575 = 0x000F_FFFF, more than 1 million pixels. static DecodeImageArgMaxInclDimension DefaultValue(); uint32_t repr; }; // DecodeImageArgMaxInclMetadataLength wraps an optional argument to // DecodeImage. struct DecodeImageArgMaxInclMetadataLength { explicit DecodeImageArgMaxInclMetadataLength(uint64_t repr0); // DefaultValue returns 16777215 = 0x00FF_FFFF, one less than 16 MiB. static DecodeImageArgMaxInclMetadataLength DefaultValue(); uint64_t repr; }; // DecodeImage decodes the image data in input. A variety of image file formats // can be decoded, depending on what callbacks.SelectDecoder returns. // // For animated formats, only the first frame is returned, since the API is // simpler for synchronous I/O and having DecodeImage only return when // completely done, but rendering animation often involves handling other // events in between animation frames. To decode multiple frames of animated // images, or for asynchronous I/O (e.g. when decoding an image streamed over // the network), use Wuffs' lower level C API instead of its higher level, // simplified C++ API (the wuffs_aux API). // // The DecodeImageResult's fields depend on whether decoding succeeded: // - On total success, the error_message is empty and pixbuf.pixcfg.is_valid() // is true. // - On partial success (e.g. the input file was truncated but we are still // able to decode some of the pixels), error_message is non-empty but // pixbuf.pixcfg.is_valid() is still true. It is up to the caller whether to // accept or reject partial success. // - On failure, the error_message is non_empty and pixbuf.pixcfg.is_valid() // is false. // // The callbacks allocate the pixel buffer memory and work buffer memory. On // success, pixel buffer memory ownership is passed to the DecodeImage caller // as the returned pixbuf_mem_owner. Regardless of success or failure, the work // buffer memory is deleted. // // The pixel_blend (one of the constants listed below) determines how to // composite the decoded image over the pixel buffer's original pixels (as // returned by callbacks.AllocPixbuf): // - WUFFS_BASE__PIXEL_BLEND__SRC // - WUFFS_BASE__PIXEL_BLEND__SRC_OVER // // The background_color is used to fill the pixel buffer after // callbacks.AllocPixbuf returns, if it is valid in the // wuffs_base__color_u32_argb_premul__is_valid sense. The default value, // 0x0000_0001, is not valid since its Blue channel value (0x01) is greater // than its Alpha channel value (0x00). A valid background_color will typically // be overwritten when pixel_blend is WUFFS_BASE__PIXEL_BLEND__SRC, but might // still be visible on partial (not total) success or when pixel_blend is // WUFFS_BASE__PIXEL_BLEND__SRC_OVER and the decoded image is not fully opaque. // // Decoding fails (with DecodeImage_MaxInclDimensionExceeded) if the image's // width or height is greater than max_incl_dimension or if any opted-in (via // flags bits) metadata is longer than max_incl_metadata_length. DecodeImageResult // DecodeImage(DecodeImageCallbacks& callbacks, sync_io::Input& input, DecodeImageArgQuirks quirks = DecodeImageArgQuirks::DefaultValue(), DecodeImageArgFlags flags = DecodeImageArgFlags::DefaultValue(), DecodeImageArgPixelBlend pixel_blend = DecodeImageArgPixelBlend::DefaultValue(), DecodeImageArgBackgroundColor background_color = DecodeImageArgBackgroundColor::DefaultValue(), DecodeImageArgMaxInclDimension max_incl_dimension = DecodeImageArgMaxInclDimension::DefaultValue(), DecodeImageArgMaxInclMetadataLength max_incl_metadata_length = DecodeImageArgMaxInclMetadataLength::DefaultValue()); } // namespace wuffs_aux // ---------------- Auxiliary - JSON namespace wuffs_aux { struct DecodeJsonResult { DecodeJsonResult(std::string&& error_message0, uint64_t cursor_position0); std::string error_message; uint64_t cursor_position; }; class DecodeJsonCallbacks { public: virtual ~DecodeJsonCallbacks(); // AppendXxx are called for leaf nodes: literals, numbers and strings. For // strings, the Callbacks implementation is responsible for tracking map keys // versus other values. virtual std::string AppendNull() = 0; virtual std::string AppendBool(bool val) = 0; virtual std::string AppendF64(double val) = 0; virtual std::string AppendI64(int64_t val) = 0; virtual std::string AppendTextString(std::string&& val) = 0; // Push and Pop are called for container nodes: JSON arrays (lists) and JSON // objects (dictionaries). // // The flags bits combine exactly one of: // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_NONE // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_LIST // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__FROM_DICT // and exactly one of: // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_NONE // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_LIST // - WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_DICT virtual std::string Push(uint32_t flags) = 0; virtual std::string Pop(uint32_t flags) = 0; // Done is always the last Callback method called by DecodeJson, whether or // not parsing the input as JSON encountered an error. Even when successful, // trailing data may remain in input and buffer. See "Unintuitive JSON // Parsing" (https://nullprogram.com/blog/2019/12/28/) which discusses JSON // parsing and when it stops. // // Do not keep a reference to buffer or buffer.data.ptr after Done returns, // as DecodeJson may then de-allocate the backing array. // // The default Done implementation is a no-op. virtual void // Done(DecodeJsonResult& result, sync_io::Input& input, IOBuffer& buffer); }; extern const char DecodeJson_BadJsonPointer[]; extern const char DecodeJson_NoMatch[]; // The FooArgBar types add structure to Foo's optional arguments. They wrap // inner representations for several reasons: // - It provides a home for the DefaultValue static method, for Foo callers // that want to override some but not all optional arguments. // - It provides the "Bar" name at Foo call sites, which can help self- // document Foo calls with many arguemnts. // - It provides some type safety against accidentally transposing or omitting // adjacent fundamentally-numeric-typed optional arguments. // DecodeJsonArgQuirks wraps an optional argument to DecodeJson. struct DecodeJsonArgQuirks { explicit DecodeJsonArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0); // DefaultValue returns an empty slice. static DecodeJsonArgQuirks DefaultValue(); const QuirkKeyValuePair* ptr; const size_t len; }; // DecodeJsonArgJsonPointer wraps an optional argument to DecodeJson. struct DecodeJsonArgJsonPointer { explicit DecodeJsonArgJsonPointer(std::string repr0); // DefaultValue returns an empty string. static DecodeJsonArgJsonPointer DefaultValue(); std::string repr; }; // DecodeJson calls callbacks based on the JSON-formatted data in input. // // On success, the returned error_message is empty and cursor_position counts // the number of bytes consumed. On failure, error_message is non-empty and // cursor_position is the location of the error. That error may be a content // error (invalid JSON) or an input error (e.g. network failure). // // json_pointer is a query in the JSON Pointer (RFC 6901) syntax. The callbacks // run for the input's sub-node that matches the query. DecodeJson_NoMatch is // returned if no matching sub-node was found. The empty query matches the // input's root node, consistent with JSON Pointer semantics. // // The JSON Pointer implementation is greedy: duplicate keys are not rejected // but only the first match for each '/'-separated fragment is followed. DecodeJsonResult // DecodeJson(DecodeJsonCallbacks& callbacks, sync_io::Input& input, DecodeJsonArgQuirks quirks = DecodeJsonArgQuirks::DefaultValue(), DecodeJsonArgJsonPointer json_pointer = DecodeJsonArgJsonPointer::DefaultValue()); } // namespace wuffs_aux #endif // defined(__cplusplus) && defined(WUFFS_BASE__HAVE_UNIQUE_PTR) // ‼ WUFFS C HEADER ENDS HERE. #ifdef WUFFS_IMPLEMENTATION #ifdef __cplusplus extern "C" { #endif // ---------------- Fundamentals // WUFFS_BASE__MAGIC is a magic number to check that initializers are called. // It's not foolproof, given C doesn't automatically zero memory before use, // but it should catch 99.99% of cases. // // Its (non-zero) value is arbitrary, based on md5sum("wuffs"). #define WUFFS_BASE__MAGIC ((uint32_t)0x3CCB6C71) // WUFFS_BASE__DISABLED is a magic number to indicate that a non-recoverable // error was previously encountered. // // Its (non-zero) value is arbitrary, based on md5sum("disabled"). #define WUFFS_BASE__DISABLED ((uint32_t)0x075AE3D2) // Use switch cases for coroutine suspension points, similar to the technique // in https://www.chiark.greenend.org.uk/~sgtatham/coroutines.html // // The implicit fallthrough is intentional. // // We use trivial macros instead of an explicit assignment and case statement // so that clang-format doesn't get confused by the unusual "case"s. #define WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0 case 0:; #define WUFFS_BASE__COROUTINE_SUSPENSION_POINT(n) \ coro_susp_point = n; \ case n:; #define WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(n) \ if (!status.repr) { \ goto ok; \ } else if (*status.repr != '$') { \ goto exit; \ } \ coro_susp_point = n; \ goto suspend; \ case n:; // The "defined(__clang__)" isn't redundant. While vanilla clang defines // __GNUC__, clang-cl (which mimics MSVC's cl.exe) does not. #if defined(__GNUC__) || defined(__clang__) #define WUFFS_BASE__LIKELY(expr) (__builtin_expect(!!(expr), 1)) #define WUFFS_BASE__UNLIKELY(expr) (__builtin_expect(!!(expr), 0)) #else #define WUFFS_BASE__LIKELY(expr) (expr) #define WUFFS_BASE__UNLIKELY(expr) (expr) #endif // -------- static inline wuffs_base__empty_struct // wuffs_private_impl__ignore_status(wuffs_base__status z) { return wuffs_base__make_empty_struct(); } static inline wuffs_base__status // wuffs_private_impl__status__ensure_not_a_suspension(wuffs_base__status z) { if (z.repr && (*z.repr == '$')) { z.repr = wuffs_base__error__cannot_return_a_suspension; } return z; } // -------- // wuffs_private_impl__iterate_total_advance returns the exclusive // pointer-offset at which iteration should stop. The overall slice has length // total_len, each iteration's sub-slice has length iter_len and are placed // iter_advance apart. // // The iter_advance may not be larger than iter_len. The iter_advance may be // smaller than iter_len, in which case the sub-slices will overlap. // // The return value r satisfies ((0 <= r) && (r <= total_len)). // // For example, if total_len = 15, iter_len = 5 and iter_advance = 3, there are // four iterations at offsets 0, 3, 6 and 9. This function returns 12. // // 0123456789012345 // [....] // [....] // [....] // [....] // $ // 0123456789012345 // // For example, if total_len = 15, iter_len = 5 and iter_advance = 5, there are // three iterations at offsets 0, 5 and 10. This function returns 15. // // 0123456789012345 // [....] // [....] // [....] // $ // 0123456789012345 static inline size_t // wuffs_private_impl__iterate_total_advance(size_t total_len, size_t iter_len, size_t iter_advance) { if (total_len >= iter_len) { size_t n = total_len - iter_len; return ((n / iter_advance) * iter_advance) + iter_advance; } return 0; } // ---------------- Numeric Types extern const uint8_t wuffs_private_impl__low_bits_mask__u8[8]; extern const uint16_t wuffs_private_impl__low_bits_mask__u16[16]; extern const uint32_t wuffs_private_impl__low_bits_mask__u32[32]; extern const uint64_t wuffs_private_impl__low_bits_mask__u64[64]; #define WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U8(n) \ (wuffs_private_impl__low_bits_mask__u8[n]) #define WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U16(n) \ (wuffs_private_impl__low_bits_mask__u16[n]) #define WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(n) \ (wuffs_private_impl__low_bits_mask__u32[n]) #define WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64(n) \ (wuffs_private_impl__low_bits_mask__u64[n]) // -------- static inline void // wuffs_private_impl__u8__sat_add_indirect(uint8_t* x, uint8_t y) { *x = wuffs_base__u8__sat_add(*x, y); } static inline void // wuffs_private_impl__u8__sat_sub_indirect(uint8_t* x, uint8_t y) { *x = wuffs_base__u8__sat_sub(*x, y); } static inline void // wuffs_private_impl__u16__sat_add_indirect(uint16_t* x, uint16_t y) { *x = wuffs_base__u16__sat_add(*x, y); } static inline void // wuffs_private_impl__u16__sat_sub_indirect(uint16_t* x, uint16_t y) { *x = wuffs_base__u16__sat_sub(*x, y); } static inline void // wuffs_private_impl__u32__sat_add_indirect(uint32_t* x, uint32_t y) { *x = wuffs_base__u32__sat_add(*x, y); } static inline void // wuffs_private_impl__u32__sat_sub_indirect(uint32_t* x, uint32_t y) { *x = wuffs_base__u32__sat_sub(*x, y); } static inline void // wuffs_private_impl__u64__sat_add_indirect(uint64_t* x, uint64_t y) { *x = wuffs_base__u64__sat_add(*x, y); } static inline void // wuffs_private_impl__u64__sat_sub_indirect(uint64_t* x, uint64_t y) { *x = wuffs_base__u64__sat_sub(*x, y); } // ---------------- Numeric Types (Utility) #define wuffs_base__utility__sign_extend_convert_u8_u32(a) \ ((uint32_t)(int32_t)(int8_t)(a)) #define wuffs_base__utility__sign_extend_convert_u16_u32(a) \ ((uint32_t)(int32_t)(int16_t)(a)) #define wuffs_base__utility__sign_extend_rshift_u32(a, n) \ ((uint32_t)(((int32_t)(a)) >> (n))) #define wuffs_base__utility__sign_extend_rshift_u64(a, n) \ ((uint64_t)(((int64_t)(a)) >> (n))) #define wuffs_base__utility__make_bitvec256(e00, e01, e02, e03) \ wuffs_base__make_bitvec256(e00, e01, e02, e03) #define wuffs_base__utility__make_optional_u63(h, v) \ wuffs_base__make_optional_u63(h, v) // ---------------- Slices and Tables // This function basically returns (ptr + len), except that that expression is // Undefined Behavior in C (but not C++) when ptr is NULL, even if len is zero. // // Precondition: (ptr != NULL) || (len == 0). static inline const uint8_t* // wuffs_private_impl__ptr_u8_plus_len(const uint8_t* ptr, size_t len) { return ptr ? (ptr + len) : NULL; } // -------- // wuffs_private_impl__slice_u8__prefix returns up to the first up_to bytes of // s. static inline wuffs_base__slice_u8 // wuffs_private_impl__slice_u8__prefix(wuffs_base__slice_u8 s, uint64_t up_to) { if (((uint64_t)(s.len)) > up_to) { s.len = ((size_t)up_to); } return s; } // wuffs_private_impl__slice_u8__suffix returns up to the last up_to bytes of // s. static inline wuffs_base__slice_u8 // wuffs_private_impl__slice_u8__suffix(wuffs_base__slice_u8 s, uint64_t up_to) { if (((uint64_t)(s.len)) > up_to) { s.ptr += ((uint64_t)(s.len)) - up_to; s.len = ((size_t)up_to); } return s; } // wuffs_private_impl__slice_u8__copy_from_slice calls memmove(dst.ptr, // src.ptr, len) where len is the minimum of dst.len and src.len. // // Passing a wuffs_base__slice_u8 with all fields NULL or zero (a valid, empty // slice) is valid and results in a no-op. static inline uint64_t // wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src) { size_t len = dst.len < src.len ? dst.len : src.len; if (len > 0) { memmove(dst.ptr, src.ptr, len); } return len; } static inline wuffs_base__empty_struct // wuffs_private_impl__bulk_load_host_endian(void* ptr, size_t len, wuffs_base__slice_u8 src) { if (len && (len <= src.len)) { memmove(ptr, src.ptr, len); } return wuffs_base__make_empty_struct(); } static inline wuffs_base__empty_struct // wuffs_private_impl__bulk_memset(void* ptr, size_t len, uint8_t byte_value) { if (len) { memset(ptr, byte_value, len); } return wuffs_base__make_empty_struct(); } static inline wuffs_base__empty_struct // wuffs_private_impl__bulk_save_host_endian(void* ptr, size_t len, wuffs_base__slice_u8 dst) { if (len && (len <= dst.len)) { memmove(dst.ptr, ptr, len); } return wuffs_base__make_empty_struct(); } // -------- static inline wuffs_base__slice_u8 // wuffs_private_impl__table_u8__row_u32(wuffs_base__table_u8 t, uint32_t y) { if (t.ptr && (y < t.height)) { return wuffs_base__make_slice_u8(t.ptr + (t.stride * y), t.width); } return wuffs_base__empty_slice_u8(); } // ---------------- Slices and Tables (Utility) #define wuffs_base__utility__empty_slice_u8 wuffs_base__empty_slice_u8 // ---------------- Ranges and Rects static inline uint32_t // wuffs_private_impl__range_ii_u32__get_min_incl( const wuffs_base__range_ii_u32* r) { return r->min_incl; } static inline uint32_t // wuffs_private_impl__range_ii_u32__get_max_incl( const wuffs_base__range_ii_u32* r) { return r->max_incl; } static inline uint32_t // wuffs_private_impl__range_ie_u32__get_min_incl( const wuffs_base__range_ie_u32* r) { return r->min_incl; } static inline uint32_t // wuffs_private_impl__range_ie_u32__get_max_excl( const wuffs_base__range_ie_u32* r) { return r->max_excl; } static inline uint64_t // wuffs_private_impl__range_ii_u64__get_min_incl( const wuffs_base__range_ii_u64* r) { return r->min_incl; } static inline uint64_t // wuffs_private_impl__range_ii_u64__get_max_incl( const wuffs_base__range_ii_u64* r) { return r->max_incl; } static inline uint64_t // wuffs_private_impl__range_ie_u64__get_min_incl( const wuffs_base__range_ie_u64* r) { return r->min_incl; } static inline uint64_t // wuffs_private_impl__range_ie_u64__get_max_excl( const wuffs_base__range_ie_u64* r) { return r->max_excl; } // ---------------- Ranges and Rects (Utility) #define wuffs_base__utility__empty_range_ii_u32 wuffs_base__empty_range_ii_u32 #define wuffs_base__utility__empty_range_ie_u32 wuffs_base__empty_range_ie_u32 #define wuffs_base__utility__empty_range_ii_u64 wuffs_base__empty_range_ii_u64 #define wuffs_base__utility__empty_range_ie_u64 wuffs_base__empty_range_ie_u64 #define wuffs_base__utility__empty_rect_ii_u32 wuffs_base__empty_rect_ii_u32 #define wuffs_base__utility__empty_rect_ie_u32 wuffs_base__empty_rect_ie_u32 #define wuffs_base__utility__make_range_ii_u32 wuffs_base__make_range_ii_u32 #define wuffs_base__utility__make_range_ie_u32 wuffs_base__make_range_ie_u32 #define wuffs_base__utility__make_range_ii_u64 wuffs_base__make_range_ii_u64 #define wuffs_base__utility__make_range_ie_u64 wuffs_base__make_range_ie_u64 #define wuffs_base__utility__make_rect_ii_u32 wuffs_base__make_rect_ii_u32 #define wuffs_base__utility__make_rect_ie_u32 wuffs_base__make_rect_ie_u32 // ---------------- I/O static inline uint64_t // wuffs_private_impl__io__count_since(uint64_t mark, uint64_t index) { if (index >= mark) { return index - mark; } return 0; } // TODO: drop the "const" in "const uint8_t* ptr". Some though required about // the base.io_reader.since method returning a mutable "slice base.u8". #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wcast-qual" #endif static inline wuffs_base__slice_u8 // wuffs_private_impl__io__since(uint64_t mark, uint64_t index, const uint8_t* ptr) { if (index >= mark) { return wuffs_base__make_slice_u8(((uint8_t*)ptr) + mark, ((size_t)(index - mark))); } return wuffs_base__empty_slice_u8(); } #if defined(__GNUC__) #pragma GCC diagnostic pop #endif // -------- static inline void // wuffs_private_impl__io_reader__limit(const uint8_t** ptr_io2_r, const uint8_t* iop_r, uint64_t limit) { if (((uint64_t)(*ptr_io2_r - iop_r)) > limit) { *ptr_io2_r = iop_r + limit; } } static inline uint32_t // wuffs_private_impl__io_reader__limited_copy_u32_to_slice( const uint8_t** ptr_iop_r, const uint8_t* io2_r, uint32_t length, wuffs_base__slice_u8 dst) { const uint8_t* iop_r = *ptr_iop_r; size_t n = dst.len; if (n > length) { n = length; } if (n > ((size_t)(io2_r - iop_r))) { n = (size_t)(io2_r - iop_r); } if (n > 0) { memmove(dst.ptr, iop_r, n); *ptr_iop_r += n; } return (uint32_t)(n); } // wuffs_private_impl__io_reader__match7 returns whether the io_reader's // upcoming bytes start with the given prefix (up to 7 bytes long). It is // peek-like, not read-like, in that there are no side-effects. // // The low 3 bits of a hold the prefix length, n. // // The high 56 bits of a hold the prefix itself, in little-endian order. The // first prefix byte is in bits 8..=15, the second prefix byte is in bits // 16..=23, etc. The high (8 * (7 - n)) bits are ignored. // // There are three possible return values: // - 0 means success. // - 1 means inconclusive, equivalent to "$short read". // - 2 means failure. static inline uint32_t // wuffs_private_impl__io_reader__match7(const uint8_t* iop_r, const uint8_t* io2_r, wuffs_base__io_buffer* r, uint64_t a) { uint32_t n = a & 7; a >>= 8; if ((io2_r - iop_r) >= 8) { uint64_t x = wuffs_base__peek_u64le__no_bounds_check(iop_r); uint32_t shift = 8 * (8 - n); return ((a << shift) == (x << shift)) ? 0 : 2; } for (; n > 0; n--) { if (iop_r >= io2_r) { return (r && r->meta.closed) ? 2 : 1; } else if (*iop_r != ((uint8_t)(a))) { return 2; } iop_r++; a >>= 8; } return 0; } static inline wuffs_base__io_buffer* // wuffs_private_impl__io_reader__set(wuffs_base__io_buffer* b, const uint8_t** ptr_iop_r, const uint8_t** ptr_io0_r, const uint8_t** ptr_io1_r, const uint8_t** ptr_io2_r, wuffs_base__slice_u8 data, uint64_t history_position) { b->data = data; b->meta.wi = data.len; b->meta.ri = 0; b->meta.pos = history_position; b->meta.closed = false; *ptr_iop_r = data.ptr; *ptr_io0_r = data.ptr; *ptr_io1_r = data.ptr; *ptr_io2_r = data.ptr + data.len; return b; } // -------- static inline uint64_t // wuffs_private_impl__io_writer__copy_from_slice(uint8_t** ptr_iop_w, uint8_t* io2_w, wuffs_base__slice_u8 src) { uint8_t* iop_w = *ptr_iop_w; size_t n = src.len; if (n > ((size_t)(io2_w - iop_w))) { n = (size_t)(io2_w - iop_w); } if (n > 0) { memmove(iop_w, src.ptr, n); *ptr_iop_w += n; } return (uint64_t)(n); } static inline void // wuffs_private_impl__io_writer__limit(uint8_t** ptr_io2_w, uint8_t* iop_w, uint64_t limit) { if (((uint64_t)(*ptr_io2_w - iop_w)) > limit) { *ptr_io2_w = iop_w + limit; } } static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { if (!distance) { return 0; } uint8_t* p = *ptr_iop_w; if ((size_t)(p - io0_w) < (size_t)(distance)) { return 0; } uint8_t* q = p - distance; size_t n = (size_t)(io2_w - p); if ((size_t)(length) > n) { length = (uint32_t)(n); } else { n = (size_t)(length); } // TODO: unrolling by 3 seems best for the std/deflate benchmarks, but that // is mostly because 3 is the minimum length for the deflate format. This // function implementation shouldn't overfit to that one format. Perhaps the // limited_copy_u32_from_history Wuffs method should also take an unroll hint // argument, and the cgen can look if that argument is the constant // expression '3'. // // See also wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast // below. for (; n >= 3; n -= 3) { *p++ = *q++; *p++ = *q++; *p++ = *q++; } for (; n; n--) { *p++ = *q++; } *ptr_iop_w = p; return length; } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast is like // the wuffs_private_impl__io_writer__limited_copy_u32_from_history function // above, but has stronger pre-conditions. // // The caller needs to prove that: // - length >= 1 // - length <= (io2_w - *ptr_iop_w) // - distance >= 1 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint8_t* q = p - distance; uint32_t n = length; for (; n >= 3; n -= 3) { *p++ = *q++; *p++ = *q++; *p++ = *q++; } for (; n; n--) { *p++ = *q++; } *ptr_iop_w = p; return length; } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast_return_cusp // is like the // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast function, // but also returns the cusp: a byte pair (as a u16le) being the last byte of // and next byte after the copied history. // // For example, if history was [10, 11, 12, 13, 14, 15, 16, 17, 18] then: // - copying l=3, d=8 produces [11, 12, 13] and the cusp is (13, 14). // - copying l=3, d=2 produces [17, 18, 17] and the cusp is (17, 18). // // The caller needs to prove that: // - length >= 1 // - length <= (io2_w - *ptr_iop_w) // - distance >= 1 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast_return_cusp( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint8_t* q = p - distance; uint32_t n = length; for (; n >= 3; n -= 3) { *p++ = *q++; *p++ = *q++; *p++ = *q++; } for (; n; n--) { *p++ = *q++; } *ptr_iop_w = p; return (uint32_t)wuffs_base__peek_u16le__no_bounds_check(q - 1); } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast // copies the previous byte (the one immediately before *ptr_iop_w), copying 8 // byte chunks at a time. Each chunk contains 8 repetitions of the same byte. // // In terms of number of bytes copied, length is rounded up to a multiple of 8. // As a special case, a zero length rounds up to 8 (even though 0 is already a // multiple of 8), since there is always at least one 8 byte chunk copied. // // In terms of advancing *ptr_iop_w, length is not rounded up. // // The caller needs to prove that: // - length >= 1 // - (length + 8) <= (io2_w - *ptr_iop_w) // - distance == 1 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint64_t x = p[-1]; x |= x << 8; x |= x << 16; x |= x << 32; uint32_t n = length; while (1) { wuffs_base__poke_u64le__no_bounds_check(p, x); if (n <= 8) { p += n; break; } p += 8; n -= 8; } *ptr_iop_w = p; return length; } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast_return_cusp // copies the previous byte (the one immediately before *ptr_iop_w), copying 8 // byte chunks at a time. Each chunk contains 8 repetitions of the same byte. // It also returns the cusp: a byte pair (as a u16le) being the last byte of // and next byte after the copied history. // // In terms of number of bytes copied, length is rounded up to a multiple of 8. // As a special case, a zero length rounds up to 8 (even though 0 is already a // multiple of 8), since there is always at least one 8 byte chunk copied. // // In terms of advancing *ptr_iop_w, length is not rounded up. // // The caller needs to prove that: // - length >= 1 // - (length + 8) <= (io2_w - *ptr_iop_w) // - distance == 1 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast_return_cusp( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint8_t* q = p - distance; uint64_t x = p[-1]; x |= x << 8; x |= x << 16; x |= x << 32; uint32_t n = length; while (1) { wuffs_base__poke_u64le__no_bounds_check(p, x); if (n <= 8) { p += n; q += n; break; } p += 8; q += 8; n -= 8; } *ptr_iop_w = p; return (uint32_t)wuffs_base__peek_u16le__no_bounds_check(q - 1); } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast // is like the // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast function // above, but copies 8 byte chunks at a time. // // In terms of number of bytes copied, length is rounded up to a multiple of 8. // As a special case, a zero length rounds up to 8 (even though 0 is already a // multiple of 8), since there is always at least one 8 byte chunk copied. // // In terms of advancing *ptr_iop_w, length is not rounded up. // // The caller needs to prove that: // - length >= 1 // - (length + 8) <= (io2_w - *ptr_iop_w) // - distance >= 8 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint8_t* q = p - distance; uint32_t n = length; while (1) { memcpy(p, q, 8); if (n <= 8) { p += n; break; } p += 8; q += 8; n -= 8; } *ptr_iop_w = p; return length; } // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast_return_cusp // is like the // wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast function // above, but copies 8 byte chunks at a time. It also returns the cusp: a byte // pair (as a u16le) being the last byte of and next byte after the copied // history. // // In terms of number of bytes copied, length is rounded up to a multiple of 8. // As a special case, a zero length rounds up to 8 (even though 0 is already a // multiple of 8), since there is always at least one 8 byte chunk copied. // // In terms of advancing *ptr_iop_w, length is not rounded up. // // The caller needs to prove that: // - length >= 1 // - (length + 8) <= (io2_w - *ptr_iop_w) // - distance >= 8 // - distance <= (*ptr_iop_w - io0_w) static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast_return_cusp( uint8_t** ptr_iop_w, uint8_t* io0_w, uint8_t* io2_w, uint32_t length, uint32_t distance) { uint8_t* p = *ptr_iop_w; uint8_t* q = p - distance; uint32_t n = length; while (1) { memcpy(p, q, 8); if (n <= 8) { p += n; q += n; break; } p += 8; q += 8; n -= 8; } *ptr_iop_w = p; return (uint32_t)wuffs_base__peek_u16le__no_bounds_check(q - 1); } static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_reader( uint8_t** ptr_iop_w, uint8_t* io2_w, uint32_t length, const uint8_t** ptr_iop_r, const uint8_t* io2_r) { uint8_t* iop_w = *ptr_iop_w; size_t n = length; if (n > ((size_t)(io2_w - iop_w))) { n = (size_t)(io2_w - iop_w); } const uint8_t* iop_r = *ptr_iop_r; if (n > ((size_t)(io2_r - iop_r))) { n = (size_t)(io2_r - iop_r); } if (n > 0) { memmove(iop_w, iop_r, n); *ptr_iop_w += n; *ptr_iop_r += n; } return (uint32_t)(n); } static inline uint32_t // wuffs_private_impl__io_writer__limited_copy_u32_from_slice( uint8_t** ptr_iop_w, uint8_t* io2_w, uint32_t length, wuffs_base__slice_u8 src) { uint8_t* iop_w = *ptr_iop_w; size_t n = src.len; if (n > length) { n = length; } if (n > ((size_t)(io2_w - iop_w))) { n = (size_t)(io2_w - iop_w); } if (n > 0) { memmove(iop_w, src.ptr, n); *ptr_iop_w += n; } return (uint32_t)(n); } static inline wuffs_base__io_buffer* // wuffs_private_impl__io_writer__set(wuffs_base__io_buffer* b, uint8_t** ptr_iop_w, uint8_t** ptr_io0_w, uint8_t** ptr_io1_w, uint8_t** ptr_io2_w, wuffs_base__slice_u8 data, uint64_t history_position) { b->data = data; b->meta.wi = 0; b->meta.ri = 0; b->meta.pos = history_position; b->meta.closed = false; *ptr_iop_w = data.ptr; *ptr_io0_w = data.ptr; *ptr_io1_w = data.ptr; *ptr_io2_w = data.ptr + data.len; return b; } // ---------------- I/O (Utility) #define wuffs_base__utility__empty_io_reader wuffs_base__empty_io_reader #define wuffs_base__utility__empty_io_writer wuffs_base__empty_io_writer // ---------------- Tokens // ---------------- Tokens (Utility) // ---------------- Memory Allocation // ---------------- Images WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__limited_swizzle_u32_interleaved_from_reader( const wuffs_base__pixel_swizzler* p, uint32_t up_to_num_pixels, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, const uint8_t** ptr_iop_r, const uint8_t* io2_r); WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_from_reader( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, const uint8_t** ptr_iop_r, const uint8_t* io2_r); WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, uint64_t num_pixels); WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_swizzler__swizzle_ycck( const wuffs_base__pixel_swizzler* p, wuffs_base__pixel_buffer* dst, wuffs_base__slice_u8 dst_palette, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, wuffs_base__slice_u8 src0, wuffs_base__slice_u8 src1, wuffs_base__slice_u8 src2, wuffs_base__slice_u8 src3, uint32_t width0, uint32_t width1, uint32_t width2, uint32_t width3, uint32_t height0, uint32_t height1, uint32_t height2, uint32_t height3, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t stride3, uint8_t h0, uint8_t h1, uint8_t h2, uint8_t h3, uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, bool is_rgb_or_cmyk, bool triangle_filter_for_2to1, wuffs_base__slice_u8 scratch_buffer_2k); // ---------------- Images (Utility) #define wuffs_base__utility__make_pixel_format wuffs_base__make_pixel_format // ---------------- String Conversions // ---------------- Unicode and UTF-8 // ---------------- #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__CORE) const uint8_t wuffs_private_impl__low_bits_mask__u8[8] = { 0x00, 0x01, 0x03, 0x07, 0x0F, 0x1F, 0x3F, 0x7F, }; const uint16_t wuffs_private_impl__low_bits_mask__u16[16] = { 0x0000, 0x0001, 0x0003, 0x0007, 0x000F, 0x001F, 0x003F, 0x007F, 0x00FF, 0x01FF, 0x03FF, 0x07FF, 0x0FFF, 0x1FFF, 0x3FFF, 0x7FFF, }; const uint32_t wuffs_private_impl__low_bits_mask__u32[32] = { 0x00000000, 0x00000001, 0x00000003, 0x00000007, 0x0000000F, 0x0000001F, 0x0000003F, 0x0000007F, 0x000000FF, 0x000001FF, 0x000003FF, 0x000007FF, 0x00000FFF, 0x00001FFF, 0x00003FFF, 0x00007FFF, 0x0000FFFF, 0x0001FFFF, 0x0003FFFF, 0x0007FFFF, 0x000FFFFF, 0x001FFFFF, 0x003FFFFF, 0x007FFFFF, 0x00FFFFFF, 0x01FFFFFF, 0x03FFFFFF, 0x07FFFFFF, 0x0FFFFFFF, 0x1FFFFFFF, 0x3FFFFFFF, 0x7FFFFFFF, }; const uint64_t wuffs_private_impl__low_bits_mask__u64[64] = { 0x0000000000000000, 0x0000000000000001, 0x0000000000000003, 0x0000000000000007, 0x000000000000000F, 0x000000000000001F, 0x000000000000003F, 0x000000000000007F, 0x00000000000000FF, 0x00000000000001FF, 0x00000000000003FF, 0x00000000000007FF, 0x0000000000000FFF, 0x0000000000001FFF, 0x0000000000003FFF, 0x0000000000007FFF, 0x000000000000FFFF, 0x000000000001FFFF, 0x000000000003FFFF, 0x000000000007FFFF, 0x00000000000FFFFF, 0x00000000001FFFFF, 0x00000000003FFFFF, 0x00000000007FFFFF, 0x0000000000FFFFFF, 0x0000000001FFFFFF, 0x0000000003FFFFFF, 0x0000000007FFFFFF, 0x000000000FFFFFFF, 0x000000001FFFFFFF, 0x000000003FFFFFFF, 0x000000007FFFFFFF, 0x00000000FFFFFFFF, 0x00000001FFFFFFFF, 0x00000003FFFFFFFF, 0x00000007FFFFFFFF, 0x0000000FFFFFFFFF, 0x0000001FFFFFFFFF, 0x0000003FFFFFFFFF, 0x0000007FFFFFFFFF, 0x000000FFFFFFFFFF, 0x000001FFFFFFFFFF, 0x000003FFFFFFFFFF, 0x000007FFFFFFFFFF, 0x00000FFFFFFFFFFF, 0x00001FFFFFFFFFFF, 0x00003FFFFFFFFFFF, 0x00007FFFFFFFFFFF, 0x0000FFFFFFFFFFFF, 0x0001FFFFFFFFFFFF, 0x0003FFFFFFFFFFFF, 0x0007FFFFFFFFFFFF, 0x000FFFFFFFFFFFFF, 0x001FFFFFFFFFFFFF, 0x003FFFFFFFFFFFFF, 0x007FFFFFFFFFFFFF, 0x00FFFFFFFFFFFFFF, 0x01FFFFFFFFFFFFFF, 0x03FFFFFFFFFFFFFF, 0x07FFFFFFFFFFFFFF, 0x0FFFFFFFFFFFFFFF, 0x1FFFFFFFFFFFFFFF, 0x3FFFFFFFFFFFFFFF, 0x7FFFFFFFFFFFFFFF, }; const uint32_t wuffs_private_impl__pixel_format__bits_per_channel[16] = { 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x0A, 0x0C, 0x10, 0x18, 0x20, 0x30, 0x40, }; const char wuffs_base__note__i_o_redirect[] = "@base: I/O redirect"; const char wuffs_base__note__end_of_data[] = "@base: end of data"; const char wuffs_base__note__metadata_reported[] = "@base: metadata reported"; const char wuffs_base__suspension__even_more_information[] = "$base: even more information"; const char wuffs_base__suspension__mispositioned_read[] = "$base: mispositioned read"; const char wuffs_base__suspension__mispositioned_write[] = "$base: mispositioned write"; const char wuffs_base__suspension__short_read[] = "$base: short read"; const char wuffs_base__suspension__short_workbuf[] = "$base: short workbuf"; const char wuffs_base__suspension__short_write[] = "$base: short write"; const char wuffs_base__error__bad_i_o_position[] = "#base: bad I/O position"; const char wuffs_base__error__bad_argument_length_too_short[] = "#base: bad argument (length too short)"; const char wuffs_base__error__bad_argument[] = "#base: bad argument"; const char wuffs_base__error__bad_call_sequence[] = "#base: bad call sequence"; const char wuffs_base__error__bad_data[] = "#base: bad data"; const char wuffs_base__error__bad_receiver[] = "#base: bad receiver"; const char wuffs_base__error__bad_restart[] = "#base: bad restart"; const char wuffs_base__error__bad_sizeof_receiver[] = "#base: bad sizeof receiver"; const char wuffs_base__error__bad_vtable[] = "#base: bad vtable"; const char wuffs_base__error__bad_workbuf_length[] = "#base: bad workbuf length"; const char wuffs_base__error__bad_wuffs_version[] = "#base: bad wuffs version"; const char wuffs_base__error__cannot_return_a_suspension[] = "#base: cannot return a suspension"; const char wuffs_base__error__disabled_by_wuffs_config_dst_pixel_format_enable_allowlist[] = "#base: disabled by WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST"; const char wuffs_base__error__disabled_by_previous_error[] = "#base: disabled by previous error"; const char wuffs_base__error__initialize_falsely_claimed_already_zeroed[] = "#base: initialize falsely claimed already zeroed"; const char wuffs_base__error__initialize_not_called[] = "#base: initialize not called"; const char wuffs_base__error__insufficient_history[] = "#base: insufficient history"; const char wuffs_base__error__interleaved_coroutine_calls[] = "#base: interleaved coroutine calls"; const char wuffs_base__error__no_more_information[] = "#base: no more information"; const char wuffs_base__error__not_enough_data[] = "#base: not enough data"; const char wuffs_base__error__out_of_bounds[] = "#base: out of bounds"; const char wuffs_base__error__unsupported_image_dimension[] = "#base: unsupported image dimension"; const char wuffs_base__error__unsupported_method[] = "#base: unsupported method"; const char wuffs_base__error__unsupported_option[] = "#base: unsupported option"; const char wuffs_base__error__unsupported_pixel_swizzler_option[] = "#base: unsupported pixel swizzler option"; const char wuffs_base__error__too_much_data[] = "#base: too much data"; const char wuffs_base__hasher_u32__vtable_name[] = "{vtable}wuffs_base__hasher_u32"; const char wuffs_base__hasher_u64__vtable_name[] = "{vtable}wuffs_base__hasher_u64"; const char wuffs_base__hasher_bitvec256__vtable_name[] = "{vtable}wuffs_base__hasher_bitvec256"; const char wuffs_base__image_decoder__vtable_name[] = "{vtable}wuffs_base__image_decoder"; const char wuffs_base__io_transformer__vtable_name[] = "{vtable}wuffs_base__io_transformer"; const char wuffs_base__token_decoder__vtable_name[] = "{vtable}wuffs_base__token_decoder"; #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__CORE) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__INTERFACES) // ---------------- Interface Definitions. WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__hasher_u32__checksum_u32( const wuffs_base__hasher_u32* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u32__vtable_name) { const wuffs_base__hasher_u32__func_ptrs* func_ptrs = (const wuffs_base__hasher_u32__func_ptrs*)(v->function_pointers); return (*func_ptrs->checksum_u32)(self); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u32__get_quirk( const wuffs_base__hasher_u32* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u32__vtable_name) { const wuffs_base__hasher_u32__func_ptrs* func_ptrs = (const wuffs_base__hasher_u32__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_u32__set_quirk( wuffs_base__hasher_u32* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u32__vtable_name) { const wuffs_base__hasher_u32__func_ptrs* func_ptrs = (const wuffs_base__hasher_u32__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_u32__update( wuffs_base__hasher_u32* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u32__vtable_name) { const wuffs_base__hasher_u32__func_ptrs* func_ptrs = (const wuffs_base__hasher_u32__func_ptrs*)(v->function_pointers); return (*func_ptrs->update)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_empty_struct(); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__hasher_u32__update_u32( wuffs_base__hasher_u32* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u32__vtable_name) { const wuffs_base__hasher_u32__func_ptrs* func_ptrs = (const wuffs_base__hasher_u32__func_ptrs*)(v->function_pointers); return (*func_ptrs->update_u32)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } // -------- WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__checksum_u64( const wuffs_base__hasher_u64* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u64__vtable_name) { const wuffs_base__hasher_u64__func_ptrs* func_ptrs = (const wuffs_base__hasher_u64__func_ptrs*)(v->function_pointers); return (*func_ptrs->checksum_u64)(self); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__get_quirk( const wuffs_base__hasher_u64* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u64__vtable_name) { const wuffs_base__hasher_u64__func_ptrs* func_ptrs = (const wuffs_base__hasher_u64__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_u64__set_quirk( wuffs_base__hasher_u64* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u64__vtable_name) { const wuffs_base__hasher_u64__func_ptrs* func_ptrs = (const wuffs_base__hasher_u64__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_u64__update( wuffs_base__hasher_u64* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u64__vtable_name) { const wuffs_base__hasher_u64__func_ptrs* func_ptrs = (const wuffs_base__hasher_u64__func_ptrs*)(v->function_pointers); return (*func_ptrs->update)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_empty_struct(); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_u64__update_u64( wuffs_base__hasher_u64* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_u64__vtable_name) { const wuffs_base__hasher_u64__func_ptrs* func_ptrs = (const wuffs_base__hasher_u64__func_ptrs*)(v->function_pointers); return (*func_ptrs->update_u64)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } // -------- WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_base__hasher_bitvec256__checksum_bitvec256( const wuffs_base__hasher_bitvec256* self) { if (!self) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_bitvec256__vtable_name) { const wuffs_base__hasher_bitvec256__func_ptrs* func_ptrs = (const wuffs_base__hasher_bitvec256__func_ptrs*)(v->function_pointers); return (*func_ptrs->checksum_bitvec256)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__hasher_bitvec256__get_quirk( const wuffs_base__hasher_bitvec256* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_bitvec256__vtable_name) { const wuffs_base__hasher_bitvec256__func_ptrs* func_ptrs = (const wuffs_base__hasher_bitvec256__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__hasher_bitvec256__set_quirk( wuffs_base__hasher_bitvec256* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_bitvec256__vtable_name) { const wuffs_base__hasher_bitvec256__func_ptrs* func_ptrs = (const wuffs_base__hasher_bitvec256__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__hasher_bitvec256__update( wuffs_base__hasher_bitvec256* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_bitvec256__vtable_name) { const wuffs_base__hasher_bitvec256__func_ptrs* func_ptrs = (const wuffs_base__hasher_bitvec256__func_ptrs*)(v->function_pointers); return (*func_ptrs->update)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_empty_struct(); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_base__hasher_bitvec256__update_bitvec256( wuffs_base__hasher_bitvec256* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__hasher_bitvec256__vtable_name) { const wuffs_base__hasher_bitvec256__func_ptrs* func_ptrs = (const wuffs_base__hasher_bitvec256__func_ptrs*)(v->function_pointers); return (*func_ptrs->update_bitvec256)(self, a_x); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } // -------- WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_frame( wuffs_base__image_decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->decode_frame)(self, a_dst, a_src, a_blend, a_workbuf, a_opts); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_frame_config( wuffs_base__image_decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->decode_frame_config)(self, a_dst, a_src); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__decode_image_config( wuffs_base__image_decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->decode_image_config)(self, a_dst, a_src); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_base__image_decoder__frame_dirty_rect( const wuffs_base__image_decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->frame_dirty_rect)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__empty_rect_ie_u32(); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__get_quirk( const wuffs_base__image_decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_base__image_decoder__num_animation_loops( const wuffs_base__image_decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->num_animation_loops)(self); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__num_decoded_frame_configs( const wuffs_base__image_decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->num_decoded_frame_configs)(self); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__image_decoder__num_decoded_frames( const wuffs_base__image_decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->num_decoded_frames)(self); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__restart_frame( wuffs_base__image_decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->restart_frame)(self, a_index, a_io_position); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__set_quirk( wuffs_base__image_decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_base__image_decoder__set_report_metadata( wuffs_base__image_decoder* self, uint32_t a_fourcc, bool a_report) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_report_metadata)(self, a_fourcc, a_report); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_empty_struct(); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__image_decoder__tell_me_more( wuffs_base__image_decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->tell_me_more)(self, a_dst, a_minfo, a_src); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__image_decoder__workbuf_len( const wuffs_base__image_decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__image_decoder__vtable_name) { const wuffs_base__image_decoder__func_ptrs* func_ptrs = (const wuffs_base__image_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->workbuf_len)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__empty_range_ii_u64(); } // -------- WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_base__io_transformer__dst_history_retain_length( const wuffs_base__io_transformer* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__io_transformer__vtable_name) { const wuffs_base__io_transformer__func_ptrs* func_ptrs = (const wuffs_base__io_transformer__func_ptrs*)(v->function_pointers); return (*func_ptrs->dst_history_retain_length)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__make_optional_u63(false, 0u); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__io_transformer__get_quirk( const wuffs_base__io_transformer* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__io_transformer__vtable_name) { const wuffs_base__io_transformer__func_ptrs* func_ptrs = (const wuffs_base__io_transformer__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__io_transformer__set_quirk( wuffs_base__io_transformer* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__io_transformer__vtable_name) { const wuffs_base__io_transformer__func_ptrs* func_ptrs = (const wuffs_base__io_transformer__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__io_transformer__transform_io( wuffs_base__io_transformer* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__io_transformer__vtable_name) { const wuffs_base__io_transformer__func_ptrs* func_ptrs = (const wuffs_base__io_transformer__func_ptrs*)(v->function_pointers); return (*func_ptrs->transform_io)(self, a_dst, a_src, a_workbuf); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__io_transformer__workbuf_len( const wuffs_base__io_transformer* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__io_transformer__vtable_name) { const wuffs_base__io_transformer__func_ptrs* func_ptrs = (const wuffs_base__io_transformer__func_ptrs*)(v->function_pointers); return (*func_ptrs->workbuf_len)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__empty_range_ii_u64(); } // -------- WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__token_decoder__decode_tokens( wuffs_base__token_decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__token_decoder__vtable_name) { const wuffs_base__token_decoder__func_ptrs* func_ptrs = (const wuffs_base__token_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->decode_tokens)(self, a_dst, a_src, a_workbuf); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_base__token_decoder__get_quirk( const wuffs_base__token_decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__token_decoder__vtable_name) { const wuffs_base__token_decoder__func_ptrs* func_ptrs = (const wuffs_base__token_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->get_quirk)(self, a_key); } else if (v->vtable_name == NULL) { break; } v++; } return 0; } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_base__token_decoder__set_quirk( wuffs_base__token_decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__token_decoder__vtable_name) { const wuffs_base__token_decoder__func_ptrs* func_ptrs = (const wuffs_base__token_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->set_quirk)(self, a_key, a_value); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__make_status(wuffs_base__error__bad_vtable); } WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_base__token_decoder__workbuf_len( const wuffs_base__token_decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } const wuffs_base__vtable* v = &self->private_impl.first_vtable; int i; for (i = 0; i < 63; i++) { if (v->vtable_name == wuffs_base__token_decoder__vtable_name) { const wuffs_base__token_decoder__func_ptrs* func_ptrs = (const wuffs_base__token_decoder__func_ptrs*)(v->function_pointers); return (*func_ptrs->workbuf_len)(self); } else if (v->vtable_name == NULL) { break; } v++; } return wuffs_base__utility__empty_range_ii_u64(); } #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__INTERFACES) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__FLOATCONV) // ---------------- IEEE 754 Floating Point // The etc__hpd_left_shift and etc__powers_of_5 tables were printed by // script/print-hpd-left-shift.go. That script has an optional -comments flag, // whose output is not copied here, which prints further detail. // // These tables are used in // wuffs_private_impl__high_prec_dec__lshift_num_new_digits. // wuffs_private_impl__hpd_left_shift[i] encodes the number of new digits // created after multiplying a positive integer by (1 << i): the additional // length in the decimal representation. For example, shifting "234" by 3 // (equivalent to multiplying by 8) will produce "1872". Going from a 3-length // string to a 4-length string means that 1 new digit was added (and existing // digits may have changed). // // Shifting by i can add either N or N-1 new digits, depending on whether the // original positive integer compares >= or < to the i'th power of 5 (as 10 // equals 2 * 5). Comparison is lexicographic, not numerical. // // For example, shifting by 4 (i.e. multiplying by 16) can add 1 or 2 new // digits, depending on a lexicographic comparison to (5 ** 4), i.e. "625": // - ("1" << 4) is "16", which adds 1 new digit. // - ("5678" << 4) is "90848", which adds 1 new digit. // - ("624" << 4) is "9984", which adds 1 new digit. // - ("62498" << 4) is "999968", which adds 1 new digit. // - ("625" << 4) is "10000", which adds 2 new digits. // - ("625001" << 4) is "10000016", which adds 2 new digits. // - ("7008" << 4) is "112128", which adds 2 new digits. // - ("99" << 4) is "1584", which adds 2 new digits. // // Thus, when i is 4, N is 2 and (5 ** i) is "625". This etc__hpd_left_shift // array encodes this as: // - etc__hpd_left_shift[4] is 0x1006 = (2 << 11) | 0x0006. // - etc__hpd_left_shift[5] is 0x1009 = (? << 11) | 0x0009. // where the ? isn't relevant for i == 4. // // The high 5 bits of etc__hpd_left_shift[i] is N, the higher of the two // possible number of new digits. The low 11 bits are an offset into the // etc__powers_of_5 array (of length 0x051C, so offsets fit in 11 bits). When i // is 4, its offset and the next one is 6 and 9, and etc__powers_of_5[6 .. 9] // is the string "\x06\x02\x05", so the relevant power of 5 is "625". // // Thanks to Ken Thompson for the original idea. static const uint16_t wuffs_private_impl__hpd_left_shift[65] = { 0x0000, 0x0800, 0x0801, 0x0803, 0x1006, 0x1009, 0x100D, 0x1812, 0x1817, 0x181D, 0x2024, 0x202B, 0x2033, 0x203C, 0x2846, 0x2850, 0x285B, 0x3067, 0x3073, 0x3080, 0x388E, 0x389C, 0x38AB, 0x38BB, 0x40CC, 0x40DD, 0x40EF, 0x4902, 0x4915, 0x4929, 0x513E, 0x5153, 0x5169, 0x5180, 0x5998, 0x59B0, 0x59C9, 0x61E3, 0x61FD, 0x6218, 0x6A34, 0x6A50, 0x6A6D, 0x6A8B, 0x72AA, 0x72C9, 0x72E9, 0x7B0A, 0x7B2B, 0x7B4D, 0x8370, 0x8393, 0x83B7, 0x83DC, 0x8C02, 0x8C28, 0x8C4F, 0x9477, 0x949F, 0x94C8, 0x9CF2, 0x051C, 0x051C, 0x051C, 0x051C, }; // wuffs_private_impl__powers_of_5 contains the powers of 5, concatenated // together: "5", "25", "125", "625", "3125", etc. static const uint8_t wuffs_private_impl__powers_of_5[0x051C] = { 5, 2, 5, 1, 2, 5, 6, 2, 5, 3, 1, 2, 5, 1, 5, 6, 2, 5, 7, 8, 1, 2, 5, 3, 9, 0, 6, 2, 5, 1, 9, 5, 3, 1, 2, 5, 9, 7, 6, 5, 6, 2, 5, 4, 8, 8, 2, 8, 1, 2, 5, 2, 4, 4, 1, 4, 0, 6, 2, 5, 1, 2, 2, 0, 7, 0, 3, 1, 2, 5, 6, 1, 0, 3, 5, 1, 5, 6, 2, 5, 3, 0, 5, 1, 7, 5, 7, 8, 1, 2, 5, 1, 5, 2, 5, 8, 7, 8, 9, 0, 6, 2, 5, 7, 6, 2, 9, 3, 9, 4, 5, 3, 1, 2, 5, 3, 8, 1, 4, 6, 9, 7, 2, 6, 5, 6, 2, 5, 1, 9, 0, 7, 3, 4, 8, 6, 3, 2, 8, 1, 2, 5, 9, 5, 3, 6, 7, 4, 3, 1, 6, 4, 0, 6, 2, 5, 4, 7, 6, 8, 3, 7, 1, 5, 8, 2, 0, 3, 1, 2, 5, 2, 3, 8, 4, 1, 8, 5, 7, 9, 1, 0, 1, 5, 6, 2, 5, 1, 1, 9, 2, 0, 9, 2, 8, 9, 5, 5, 0, 7, 8, 1, 2, 5, 5, 9, 6, 0, 4, 6, 4, 4, 7, 7, 5, 3, 9, 0, 6, 2, 5, 2, 9, 8, 0, 2, 3, 2, 2, 3, 8, 7, 6, 9, 5, 3, 1, 2, 5, 1, 4, 9, 0, 1, 1, 6, 1, 1, 9, 3, 8, 4, 7, 6, 5, 6, 2, 5, 7, 4, 5, 0, 5, 8, 0, 5, 9, 6, 9, 2, 3, 8, 2, 8, 1, 2, 5, 3, 7, 2, 5, 2, 9, 0, 2, 9, 8, 4, 6, 1, 9, 1, 4, 0, 6, 2, 5, 1, 8, 6, 2, 6, 4, 5, 1, 4, 9, 2, 3, 0, 9, 5, 7, 0, 3, 1, 2, 5, 9, 3, 1, 3, 2, 2, 5, 7, 4, 6, 1, 5, 4, 7, 8, 5, 1, 5, 6, 2, 5, 4, 6, 5, 6, 6, 1, 2, 8, 7, 3, 0, 7, 7, 3, 9, 2, 5, 7, 8, 1, 2, 5, 2, 3, 2, 8, 3, 0, 6, 4, 3, 6, 5, 3, 8, 6, 9, 6, 2, 8, 9, 0, 6, 2, 5, 1, 1, 6, 4, 1, 5, 3, 2, 1, 8, 2, 6, 9, 3, 4, 8, 1, 4, 4, 5, 3, 1, 2, 5, 5, 8, 2, 0, 7, 6, 6, 0, 9, 1, 3, 4, 6, 7, 4, 0, 7, 2, 2, 6, 5, 6, 2, 5, 2, 9, 1, 0, 3, 8, 3, 0, 4, 5, 6, 7, 3, 3, 7, 0, 3, 6, 1, 3, 2, 8, 1, 2, 5, 1, 4, 5, 5, 1, 9, 1, 5, 2, 2, 8, 3, 6, 6, 8, 5, 1, 8, 0, 6, 6, 4, 0, 6, 2, 5, 7, 2, 7, 5, 9, 5, 7, 6, 1, 4, 1, 8, 3, 4, 2, 5, 9, 0, 3, 3, 2, 0, 3, 1, 2, 5, 3, 6, 3, 7, 9, 7, 8, 8, 0, 7, 0, 9, 1, 7, 1, 2, 9, 5, 1, 6, 6, 0, 1, 5, 6, 2, 5, 1, 8, 1, 8, 9, 8, 9, 4, 0, 3, 5, 4, 5, 8, 5, 6, 4, 7, 5, 8, 3, 0, 0, 7, 8, 1, 2, 5, 9, 0, 9, 4, 9, 4, 7, 0, 1, 7, 7, 2, 9, 2, 8, 2, 3, 7, 9, 1, 5, 0, 3, 9, 0, 6, 2, 5, 4, 5, 4, 7, 4, 7, 3, 5, 0, 8, 8, 6, 4, 6, 4, 1, 1, 8, 9, 5, 7, 5, 1, 9, 5, 3, 1, 2, 5, 2, 2, 7, 3, 7, 3, 6, 7, 5, 4, 4, 3, 2, 3, 2, 0, 5, 9, 4, 7, 8, 7, 5, 9, 7, 6, 5, 6, 2, 5, 1, 1, 3, 6, 8, 6, 8, 3, 7, 7, 2, 1, 6, 1, 6, 0, 2, 9, 7, 3, 9, 3, 7, 9, 8, 8, 2, 8, 1, 2, 5, 5, 6, 8, 4, 3, 4, 1, 8, 8, 6, 0, 8, 0, 8, 0, 1, 4, 8, 6, 9, 6, 8, 9, 9, 4, 1, 4, 0, 6, 2, 5, 2, 8, 4, 2, 1, 7, 0, 9, 4, 3, 0, 4, 0, 4, 0, 0, 7, 4, 3, 4, 8, 4, 4, 9, 7, 0, 7, 0, 3, 1, 2, 5, 1, 4, 2, 1, 0, 8, 5, 4, 7, 1, 5, 2, 0, 2, 0, 0, 3, 7, 1, 7, 4, 2, 2, 4, 8, 5, 3, 5, 1, 5, 6, 2, 5, 7, 1, 0, 5, 4, 2, 7, 3, 5, 7, 6, 0, 1, 0, 0, 1, 8, 5, 8, 7, 1, 1, 2, 4, 2, 6, 7, 5, 7, 8, 1, 2, 5, 3, 5, 5, 2, 7, 1, 3, 6, 7, 8, 8, 0, 0, 5, 0, 0, 9, 2, 9, 3, 5, 5, 6, 2, 1, 3, 3, 7, 8, 9, 0, 6, 2, 5, 1, 7, 7, 6, 3, 5, 6, 8, 3, 9, 4, 0, 0, 2, 5, 0, 4, 6, 4, 6, 7, 7, 8, 1, 0, 6, 6, 8, 9, 4, 5, 3, 1, 2, 5, 8, 8, 8, 1, 7, 8, 4, 1, 9, 7, 0, 0, 1, 2, 5, 2, 3, 2, 3, 3, 8, 9, 0, 5, 3, 3, 4, 4, 7, 2, 6, 5, 6, 2, 5, 4, 4, 4, 0, 8, 9, 2, 0, 9, 8, 5, 0, 0, 6, 2, 6, 1, 6, 1, 6, 9, 4, 5, 2, 6, 6, 7, 2, 3, 6, 3, 2, 8, 1, 2, 5, 2, 2, 2, 0, 4, 4, 6, 0, 4, 9, 2, 5, 0, 3, 1, 3, 0, 8, 0, 8, 4, 7, 2, 6, 3, 3, 3, 6, 1, 8, 1, 6, 4, 0, 6, 2, 5, 1, 1, 1, 0, 2, 2, 3, 0, 2, 4, 6, 2, 5, 1, 5, 6, 5, 4, 0, 4, 2, 3, 6, 3, 1, 6, 6, 8, 0, 9, 0, 8, 2, 0, 3, 1, 2, 5, 5, 5, 5, 1, 1, 1, 5, 1, 2, 3, 1, 2, 5, 7, 8, 2, 7, 0, 2, 1, 1, 8, 1, 5, 8, 3, 4, 0, 4, 5, 4, 1, 0, 1, 5, 6, 2, 5, 2, 7, 7, 5, 5, 5, 7, 5, 6, 1, 5, 6, 2, 8, 9, 1, 3, 5, 1, 0, 5, 9, 0, 7, 9, 1, 7, 0, 2, 2, 7, 0, 5, 0, 7, 8, 1, 2, 5, 1, 3, 8, 7, 7, 7, 8, 7, 8, 0, 7, 8, 1, 4, 4, 5, 6, 7, 5, 5, 2, 9, 5, 3, 9, 5, 8, 5, 1, 1, 3, 5, 2, 5, 3, 9, 0, 6, 2, 5, 6, 9, 3, 8, 8, 9, 3, 9, 0, 3, 9, 0, 7, 2, 2, 8, 3, 7, 7, 6, 4, 7, 6, 9, 7, 9, 2, 5, 5, 6, 7, 6, 2, 6, 9, 5, 3, 1, 2, 5, 3, 4, 6, 9, 4, 4, 6, 9, 5, 1, 9, 5, 3, 6, 1, 4, 1, 8, 8, 8, 2, 3, 8, 4, 8, 9, 6, 2, 7, 8, 3, 8, 1, 3, 4, 7, 6, 5, 6, 2, 5, 1, 7, 3, 4, 7, 2, 3, 4, 7, 5, 9, 7, 6, 8, 0, 7, 0, 9, 4, 4, 1, 1, 9, 2, 4, 4, 8, 1, 3, 9, 1, 9, 0, 6, 7, 3, 8, 2, 8, 1, 2, 5, 8, 6, 7, 3, 6, 1, 7, 3, 7, 9, 8, 8, 4, 0, 3, 5, 4, 7, 2, 0, 5, 9, 6, 2, 2, 4, 0, 6, 9, 5, 9, 5, 3, 3, 6, 9, 1, 4, 0, 6, 2, 5, }; // -------- // wuffs_private_impl__powers_of_10 contains truncated approximations to the // powers of 10, ranging from 1e-307 to 1e+288 inclusive, as 596 pairs of // uint64_t values (a 128-bit mantissa). // // There's also an implicit third column (implied by a linear formula involving // the base-10 exponent) that is the base-2 exponent, biased by a magic // constant. That constant (1214 or 0x04BE) equals 1023 + 191. 1023 is the bias // for IEEE 754 double-precision floating point. 191 is ((3 * 64) - 1) and // wuffs_private_impl__parse_number_f64_eisel_lemire works with // multiples-of-64-bit mantissas. // // For example, the third row holds the approximation to 1e-305: // 0xE0B62E29_29ABA83C_331ACDAB_FE94DE87 * (2 ** (0x0049 - 0x04BE)) // // Similarly, 1e+4 is approximated by: // 0x9C400000_00000000_00000000_00000000 * (2 ** (0x044C - 0x04BE)) // // Similarly, 1e+68 is approximated by: // 0xED63A231_D4C4FB27_4CA7AAA8_63EE4BDD * (2 ** (0x0520 - 0x04BE)) // // This table was generated by by script/print-mpb-powers-of-10.go static const uint64_t wuffs_private_impl__powers_of_10[596][2] = { {0xA5D3B6D479F8E056, 0x8FD0C16206306BAB}, // 1e-307 {0x8F48A4899877186C, 0xB3C4F1BA87BC8696}, // 1e-306 {0x331ACDABFE94DE87, 0xE0B62E2929ABA83C}, // 1e-305 {0x9FF0C08B7F1D0B14, 0x8C71DCD9BA0B4925}, // 1e-304 {0x07ECF0AE5EE44DD9, 0xAF8E5410288E1B6F}, // 1e-303 {0xC9E82CD9F69D6150, 0xDB71E91432B1A24A}, // 1e-302 {0xBE311C083A225CD2, 0x892731AC9FAF056E}, // 1e-301 {0x6DBD630A48AAF406, 0xAB70FE17C79AC6CA}, // 1e-300 {0x092CBBCCDAD5B108, 0xD64D3D9DB981787D}, // 1e-299 {0x25BBF56008C58EA5, 0x85F0468293F0EB4E}, // 1e-298 {0xAF2AF2B80AF6F24E, 0xA76C582338ED2621}, // 1e-297 {0x1AF5AF660DB4AEE1, 0xD1476E2C07286FAA}, // 1e-296 {0x50D98D9FC890ED4D, 0x82CCA4DB847945CA}, // 1e-295 {0xE50FF107BAB528A0, 0xA37FCE126597973C}, // 1e-294 {0x1E53ED49A96272C8, 0xCC5FC196FEFD7D0C}, // 1e-293 {0x25E8E89C13BB0F7A, 0xFF77B1FCBEBCDC4F}, // 1e-292 {0x77B191618C54E9AC, 0x9FAACF3DF73609B1}, // 1e-291 {0xD59DF5B9EF6A2417, 0xC795830D75038C1D}, // 1e-290 {0x4B0573286B44AD1D, 0xF97AE3D0D2446F25}, // 1e-289 {0x4EE367F9430AEC32, 0x9BECCE62836AC577}, // 1e-288 {0x229C41F793CDA73F, 0xC2E801FB244576D5}, // 1e-287 {0x6B43527578C1110F, 0xF3A20279ED56D48A}, // 1e-286 {0x830A13896B78AAA9, 0x9845418C345644D6}, // 1e-285 {0x23CC986BC656D553, 0xBE5691EF416BD60C}, // 1e-284 {0x2CBFBE86B7EC8AA8, 0xEDEC366B11C6CB8F}, // 1e-283 {0x7BF7D71432F3D6A9, 0x94B3A202EB1C3F39}, // 1e-282 {0xDAF5CCD93FB0CC53, 0xB9E08A83A5E34F07}, // 1e-281 {0xD1B3400F8F9CFF68, 0xE858AD248F5C22C9}, // 1e-280 {0x23100809B9C21FA1, 0x91376C36D99995BE}, // 1e-279 {0xABD40A0C2832A78A, 0xB58547448FFFFB2D}, // 1e-278 {0x16C90C8F323F516C, 0xE2E69915B3FFF9F9}, // 1e-277 {0xAE3DA7D97F6792E3, 0x8DD01FAD907FFC3B}, // 1e-276 {0x99CD11CFDF41779C, 0xB1442798F49FFB4A}, // 1e-275 {0x40405643D711D583, 0xDD95317F31C7FA1D}, // 1e-274 {0x482835EA666B2572, 0x8A7D3EEF7F1CFC52}, // 1e-273 {0xDA3243650005EECF, 0xAD1C8EAB5EE43B66}, // 1e-272 {0x90BED43E40076A82, 0xD863B256369D4A40}, // 1e-271 {0x5A7744A6E804A291, 0x873E4F75E2224E68}, // 1e-270 {0x711515D0A205CB36, 0xA90DE3535AAAE202}, // 1e-269 {0x0D5A5B44CA873E03, 0xD3515C2831559A83}, // 1e-268 {0xE858790AFE9486C2, 0x8412D9991ED58091}, // 1e-267 {0x626E974DBE39A872, 0xA5178FFF668AE0B6}, // 1e-266 {0xFB0A3D212DC8128F, 0xCE5D73FF402D98E3}, // 1e-265 {0x7CE66634BC9D0B99, 0x80FA687F881C7F8E}, // 1e-264 {0x1C1FFFC1EBC44E80, 0xA139029F6A239F72}, // 1e-263 {0xA327FFB266B56220, 0xC987434744AC874E}, // 1e-262 {0x4BF1FF9F0062BAA8, 0xFBE9141915D7A922}, // 1e-261 {0x6F773FC3603DB4A9, 0x9D71AC8FADA6C9B5}, // 1e-260 {0xCB550FB4384D21D3, 0xC4CE17B399107C22}, // 1e-259 {0x7E2A53A146606A48, 0xF6019DA07F549B2B}, // 1e-258 {0x2EDA7444CBFC426D, 0x99C102844F94E0FB}, // 1e-257 {0xFA911155FEFB5308, 0xC0314325637A1939}, // 1e-256 {0x793555AB7EBA27CA, 0xF03D93EEBC589F88}, // 1e-255 {0x4BC1558B2F3458DE, 0x96267C7535B763B5}, // 1e-254 {0x9EB1AAEDFB016F16, 0xBBB01B9283253CA2}, // 1e-253 {0x465E15A979C1CADC, 0xEA9C227723EE8BCB}, // 1e-252 {0x0BFACD89EC191EC9, 0x92A1958A7675175F}, // 1e-251 {0xCEF980EC671F667B, 0xB749FAED14125D36}, // 1e-250 {0x82B7E12780E7401A, 0xE51C79A85916F484}, // 1e-249 {0xD1B2ECB8B0908810, 0x8F31CC0937AE58D2}, // 1e-248 {0x861FA7E6DCB4AA15, 0xB2FE3F0B8599EF07}, // 1e-247 {0x67A791E093E1D49A, 0xDFBDCECE67006AC9}, // 1e-246 {0xE0C8BB2C5C6D24E0, 0x8BD6A141006042BD}, // 1e-245 {0x58FAE9F773886E18, 0xAECC49914078536D}, // 1e-244 {0xAF39A475506A899E, 0xDA7F5BF590966848}, // 1e-243 {0x6D8406C952429603, 0x888F99797A5E012D}, // 1e-242 {0xC8E5087BA6D33B83, 0xAAB37FD7D8F58178}, // 1e-241 {0xFB1E4A9A90880A64, 0xD5605FCDCF32E1D6}, // 1e-240 {0x5CF2EEA09A55067F, 0x855C3BE0A17FCD26}, // 1e-239 {0xF42FAA48C0EA481E, 0xA6B34AD8C9DFC06F}, // 1e-238 {0xF13B94DAF124DA26, 0xD0601D8EFC57B08B}, // 1e-237 {0x76C53D08D6B70858, 0x823C12795DB6CE57}, // 1e-236 {0x54768C4B0C64CA6E, 0xA2CB1717B52481ED}, // 1e-235 {0xA9942F5DCF7DFD09, 0xCB7DDCDDA26DA268}, // 1e-234 {0xD3F93B35435D7C4C, 0xFE5D54150B090B02}, // 1e-233 {0xC47BC5014A1A6DAF, 0x9EFA548D26E5A6E1}, // 1e-232 {0x359AB6419CA1091B, 0xC6B8E9B0709F109A}, // 1e-231 {0xC30163D203C94B62, 0xF867241C8CC6D4C0}, // 1e-230 {0x79E0DE63425DCF1D, 0x9B407691D7FC44F8}, // 1e-229 {0x985915FC12F542E4, 0xC21094364DFB5636}, // 1e-228 {0x3E6F5B7B17B2939D, 0xF294B943E17A2BC4}, // 1e-227 {0xA705992CEECF9C42, 0x979CF3CA6CEC5B5A}, // 1e-226 {0x50C6FF782A838353, 0xBD8430BD08277231}, // 1e-225 {0xA4F8BF5635246428, 0xECE53CEC4A314EBD}, // 1e-224 {0x871B7795E136BE99, 0x940F4613AE5ED136}, // 1e-223 {0x28E2557B59846E3F, 0xB913179899F68584}, // 1e-222 {0x331AEADA2FE589CF, 0xE757DD7EC07426E5}, // 1e-221 {0x3FF0D2C85DEF7621, 0x9096EA6F3848984F}, // 1e-220 {0x0FED077A756B53A9, 0xB4BCA50B065ABE63}, // 1e-219 {0xD3E8495912C62894, 0xE1EBCE4DC7F16DFB}, // 1e-218 {0x64712DD7ABBBD95C, 0x8D3360F09CF6E4BD}, // 1e-217 {0xBD8D794D96AACFB3, 0xB080392CC4349DEC}, // 1e-216 {0xECF0D7A0FC5583A0, 0xDCA04777F541C567}, // 1e-215 {0xF41686C49DB57244, 0x89E42CAAF9491B60}, // 1e-214 {0x311C2875C522CED5, 0xAC5D37D5B79B6239}, // 1e-213 {0x7D633293366B828B, 0xD77485CB25823AC7}, // 1e-212 {0xAE5DFF9C02033197, 0x86A8D39EF77164BC}, // 1e-211 {0xD9F57F830283FDFC, 0xA8530886B54DBDEB}, // 1e-210 {0xD072DF63C324FD7B, 0xD267CAA862A12D66}, // 1e-209 {0x4247CB9E59F71E6D, 0x8380DEA93DA4BC60}, // 1e-208 {0x52D9BE85F074E608, 0xA46116538D0DEB78}, // 1e-207 {0x67902E276C921F8B, 0xCD795BE870516656}, // 1e-206 {0x00BA1CD8A3DB53B6, 0x806BD9714632DFF6}, // 1e-205 {0x80E8A40ECCD228A4, 0xA086CFCD97BF97F3}, // 1e-204 {0x6122CD128006B2CD, 0xC8A883C0FDAF7DF0}, // 1e-203 {0x796B805720085F81, 0xFAD2A4B13D1B5D6C}, // 1e-202 {0xCBE3303674053BB0, 0x9CC3A6EEC6311A63}, // 1e-201 {0xBEDBFC4411068A9C, 0xC3F490AA77BD60FC}, // 1e-200 {0xEE92FB5515482D44, 0xF4F1B4D515ACB93B}, // 1e-199 {0x751BDD152D4D1C4A, 0x991711052D8BF3C5}, // 1e-198 {0xD262D45A78A0635D, 0xBF5CD54678EEF0B6}, // 1e-197 {0x86FB897116C87C34, 0xEF340A98172AACE4}, // 1e-196 {0xD45D35E6AE3D4DA0, 0x9580869F0E7AAC0E}, // 1e-195 {0x8974836059CCA109, 0xBAE0A846D2195712}, // 1e-194 {0x2BD1A438703FC94B, 0xE998D258869FACD7}, // 1e-193 {0x7B6306A34627DDCF, 0x91FF83775423CC06}, // 1e-192 {0x1A3BC84C17B1D542, 0xB67F6455292CBF08}, // 1e-191 {0x20CABA5F1D9E4A93, 0xE41F3D6A7377EECA}, // 1e-190 {0x547EB47B7282EE9C, 0x8E938662882AF53E}, // 1e-189 {0xE99E619A4F23AA43, 0xB23867FB2A35B28D}, // 1e-188 {0x6405FA00E2EC94D4, 0xDEC681F9F4C31F31}, // 1e-187 {0xDE83BC408DD3DD04, 0x8B3C113C38F9F37E}, // 1e-186 {0x9624AB50B148D445, 0xAE0B158B4738705E}, // 1e-185 {0x3BADD624DD9B0957, 0xD98DDAEE19068C76}, // 1e-184 {0xE54CA5D70A80E5D6, 0x87F8A8D4CFA417C9}, // 1e-183 {0x5E9FCF4CCD211F4C, 0xA9F6D30A038D1DBC}, // 1e-182 {0x7647C3200069671F, 0xD47487CC8470652B}, // 1e-181 {0x29ECD9F40041E073, 0x84C8D4DFD2C63F3B}, // 1e-180 {0xF468107100525890, 0xA5FB0A17C777CF09}, // 1e-179 {0x7182148D4066EEB4, 0xCF79CC9DB955C2CC}, // 1e-178 {0xC6F14CD848405530, 0x81AC1FE293D599BF}, // 1e-177 {0xB8ADA00E5A506A7C, 0xA21727DB38CB002F}, // 1e-176 {0xA6D90811F0E4851C, 0xCA9CF1D206FDC03B}, // 1e-175 {0x908F4A166D1DA663, 0xFD442E4688BD304A}, // 1e-174 {0x9A598E4E043287FE, 0x9E4A9CEC15763E2E}, // 1e-173 {0x40EFF1E1853F29FD, 0xC5DD44271AD3CDBA}, // 1e-172 {0xD12BEE59E68EF47C, 0xF7549530E188C128}, // 1e-171 {0x82BB74F8301958CE, 0x9A94DD3E8CF578B9}, // 1e-170 {0xE36A52363C1FAF01, 0xC13A148E3032D6E7}, // 1e-169 {0xDC44E6C3CB279AC1, 0xF18899B1BC3F8CA1}, // 1e-168 {0x29AB103A5EF8C0B9, 0x96F5600F15A7B7E5}, // 1e-167 {0x7415D448F6B6F0E7, 0xBCB2B812DB11A5DE}, // 1e-166 {0x111B495B3464AD21, 0xEBDF661791D60F56}, // 1e-165 {0xCAB10DD900BEEC34, 0x936B9FCEBB25C995}, // 1e-164 {0x3D5D514F40EEA742, 0xB84687C269EF3BFB}, // 1e-163 {0x0CB4A5A3112A5112, 0xE65829B3046B0AFA}, // 1e-162 {0x47F0E785EABA72AB, 0x8FF71A0FE2C2E6DC}, // 1e-161 {0x59ED216765690F56, 0xB3F4E093DB73A093}, // 1e-160 {0x306869C13EC3532C, 0xE0F218B8D25088B8}, // 1e-159 {0x1E414218C73A13FB, 0x8C974F7383725573}, // 1e-158 {0xE5D1929EF90898FA, 0xAFBD2350644EEACF}, // 1e-157 {0xDF45F746B74ABF39, 0xDBAC6C247D62A583}, // 1e-156 {0x6B8BBA8C328EB783, 0x894BC396CE5DA772}, // 1e-155 {0x066EA92F3F326564, 0xAB9EB47C81F5114F}, // 1e-154 {0xC80A537B0EFEFEBD, 0xD686619BA27255A2}, // 1e-153 {0xBD06742CE95F5F36, 0x8613FD0145877585}, // 1e-152 {0x2C48113823B73704, 0xA798FC4196E952E7}, // 1e-151 {0xF75A15862CA504C5, 0xD17F3B51FCA3A7A0}, // 1e-150 {0x9A984D73DBE722FB, 0x82EF85133DE648C4}, // 1e-149 {0xC13E60D0D2E0EBBA, 0xA3AB66580D5FDAF5}, // 1e-148 {0x318DF905079926A8, 0xCC963FEE10B7D1B3}, // 1e-147 {0xFDF17746497F7052, 0xFFBBCFE994E5C61F}, // 1e-146 {0xFEB6EA8BEDEFA633, 0x9FD561F1FD0F9BD3}, // 1e-145 {0xFE64A52EE96B8FC0, 0xC7CABA6E7C5382C8}, // 1e-144 {0x3DFDCE7AA3C673B0, 0xF9BD690A1B68637B}, // 1e-143 {0x06BEA10CA65C084E, 0x9C1661A651213E2D}, // 1e-142 {0x486E494FCFF30A62, 0xC31BFA0FE5698DB8}, // 1e-141 {0x5A89DBA3C3EFCCFA, 0xF3E2F893DEC3F126}, // 1e-140 {0xF89629465A75E01C, 0x986DDB5C6B3A76B7}, // 1e-139 {0xF6BBB397F1135823, 0xBE89523386091465}, // 1e-138 {0x746AA07DED582E2C, 0xEE2BA6C0678B597F}, // 1e-137 {0xA8C2A44EB4571CDC, 0x94DB483840B717EF}, // 1e-136 {0x92F34D62616CE413, 0xBA121A4650E4DDEB}, // 1e-135 {0x77B020BAF9C81D17, 0xE896A0D7E51E1566}, // 1e-134 {0x0ACE1474DC1D122E, 0x915E2486EF32CD60}, // 1e-133 {0x0D819992132456BA, 0xB5B5ADA8AAFF80B8}, // 1e-132 {0x10E1FFF697ED6C69, 0xE3231912D5BF60E6}, // 1e-131 {0xCA8D3FFA1EF463C1, 0x8DF5EFABC5979C8F}, // 1e-130 {0xBD308FF8A6B17CB2, 0xB1736B96B6FD83B3}, // 1e-129 {0xAC7CB3F6D05DDBDE, 0xDDD0467C64BCE4A0}, // 1e-128 {0x6BCDF07A423AA96B, 0x8AA22C0DBEF60EE4}, // 1e-127 {0x86C16C98D2C953C6, 0xAD4AB7112EB3929D}, // 1e-126 {0xE871C7BF077BA8B7, 0xD89D64D57A607744}, // 1e-125 {0x11471CD764AD4972, 0x87625F056C7C4A8B}, // 1e-124 {0xD598E40D3DD89BCF, 0xA93AF6C6C79B5D2D}, // 1e-123 {0x4AFF1D108D4EC2C3, 0xD389B47879823479}, // 1e-122 {0xCEDF722A585139BA, 0x843610CB4BF160CB}, // 1e-121 {0xC2974EB4EE658828, 0xA54394FE1EEDB8FE}, // 1e-120 {0x733D226229FEEA32, 0xCE947A3DA6A9273E}, // 1e-119 {0x0806357D5A3F525F, 0x811CCC668829B887}, // 1e-118 {0xCA07C2DCB0CF26F7, 0xA163FF802A3426A8}, // 1e-117 {0xFC89B393DD02F0B5, 0xC9BCFF6034C13052}, // 1e-116 {0xBBAC2078D443ACE2, 0xFC2C3F3841F17C67}, // 1e-115 {0xD54B944B84AA4C0D, 0x9D9BA7832936EDC0}, // 1e-114 {0x0A9E795E65D4DF11, 0xC5029163F384A931}, // 1e-113 {0x4D4617B5FF4A16D5, 0xF64335BCF065D37D}, // 1e-112 {0x504BCED1BF8E4E45, 0x99EA0196163FA42E}, // 1e-111 {0xE45EC2862F71E1D6, 0xC06481FB9BCF8D39}, // 1e-110 {0x5D767327BB4E5A4C, 0xF07DA27A82C37088}, // 1e-109 {0x3A6A07F8D510F86F, 0x964E858C91BA2655}, // 1e-108 {0x890489F70A55368B, 0xBBE226EFB628AFEA}, // 1e-107 {0x2B45AC74CCEA842E, 0xEADAB0ABA3B2DBE5}, // 1e-106 {0x3B0B8BC90012929D, 0x92C8AE6B464FC96F}, // 1e-105 {0x09CE6EBB40173744, 0xB77ADA0617E3BBCB}, // 1e-104 {0xCC420A6A101D0515, 0xE55990879DDCAABD}, // 1e-103 {0x9FA946824A12232D, 0x8F57FA54C2A9EAB6}, // 1e-102 {0x47939822DC96ABF9, 0xB32DF8E9F3546564}, // 1e-101 {0x59787E2B93BC56F7, 0xDFF9772470297EBD}, // 1e-100 {0x57EB4EDB3C55B65A, 0x8BFBEA76C619EF36}, // 1e-99 {0xEDE622920B6B23F1, 0xAEFAE51477A06B03}, // 1e-98 {0xE95FAB368E45ECED, 0xDAB99E59958885C4}, // 1e-97 {0x11DBCB0218EBB414, 0x88B402F7FD75539B}, // 1e-96 {0xD652BDC29F26A119, 0xAAE103B5FCD2A881}, // 1e-95 {0x4BE76D3346F0495F, 0xD59944A37C0752A2}, // 1e-94 {0x6F70A4400C562DDB, 0x857FCAE62D8493A5}, // 1e-93 {0xCB4CCD500F6BB952, 0xA6DFBD9FB8E5B88E}, // 1e-92 {0x7E2000A41346A7A7, 0xD097AD07A71F26B2}, // 1e-91 {0x8ED400668C0C28C8, 0x825ECC24C873782F}, // 1e-90 {0x728900802F0F32FA, 0xA2F67F2DFA90563B}, // 1e-89 {0x4F2B40A03AD2FFB9, 0xCBB41EF979346BCA}, // 1e-88 {0xE2F610C84987BFA8, 0xFEA126B7D78186BC}, // 1e-87 {0x0DD9CA7D2DF4D7C9, 0x9F24B832E6B0F436}, // 1e-86 {0x91503D1C79720DBB, 0xC6EDE63FA05D3143}, // 1e-85 {0x75A44C6397CE912A, 0xF8A95FCF88747D94}, // 1e-84 {0xC986AFBE3EE11ABA, 0x9B69DBE1B548CE7C}, // 1e-83 {0xFBE85BADCE996168, 0xC24452DA229B021B}, // 1e-82 {0xFAE27299423FB9C3, 0xF2D56790AB41C2A2}, // 1e-81 {0xDCCD879FC967D41A, 0x97C560BA6B0919A5}, // 1e-80 {0x5400E987BBC1C920, 0xBDB6B8E905CB600F}, // 1e-79 {0x290123E9AAB23B68, 0xED246723473E3813}, // 1e-78 {0xF9A0B6720AAF6521, 0x9436C0760C86E30B}, // 1e-77 {0xF808E40E8D5B3E69, 0xB94470938FA89BCE}, // 1e-76 {0xB60B1D1230B20E04, 0xE7958CB87392C2C2}, // 1e-75 {0xB1C6F22B5E6F48C2, 0x90BD77F3483BB9B9}, // 1e-74 {0x1E38AEB6360B1AF3, 0xB4ECD5F01A4AA828}, // 1e-73 {0x25C6DA63C38DE1B0, 0xE2280B6C20DD5232}, // 1e-72 {0x579C487E5A38AD0E, 0x8D590723948A535F}, // 1e-71 {0x2D835A9DF0C6D851, 0xB0AF48EC79ACE837}, // 1e-70 {0xF8E431456CF88E65, 0xDCDB1B2798182244}, // 1e-69 {0x1B8E9ECB641B58FF, 0x8A08F0F8BF0F156B}, // 1e-68 {0xE272467E3D222F3F, 0xAC8B2D36EED2DAC5}, // 1e-67 {0x5B0ED81DCC6ABB0F, 0xD7ADF884AA879177}, // 1e-66 {0x98E947129FC2B4E9, 0x86CCBB52EA94BAEA}, // 1e-65 {0x3F2398D747B36224, 0xA87FEA27A539E9A5}, // 1e-64 {0x8EEC7F0D19A03AAD, 0xD29FE4B18E88640E}, // 1e-63 {0x1953CF68300424AC, 0x83A3EEEEF9153E89}, // 1e-62 {0x5FA8C3423C052DD7, 0xA48CEAAAB75A8E2B}, // 1e-61 {0x3792F412CB06794D, 0xCDB02555653131B6}, // 1e-60 {0xE2BBD88BBEE40BD0, 0x808E17555F3EBF11}, // 1e-59 {0x5B6ACEAEAE9D0EC4, 0xA0B19D2AB70E6ED6}, // 1e-58 {0xF245825A5A445275, 0xC8DE047564D20A8B}, // 1e-57 {0xEED6E2F0F0D56712, 0xFB158592BE068D2E}, // 1e-56 {0x55464DD69685606B, 0x9CED737BB6C4183D}, // 1e-55 {0xAA97E14C3C26B886, 0xC428D05AA4751E4C}, // 1e-54 {0xD53DD99F4B3066A8, 0xF53304714D9265DF}, // 1e-53 {0xE546A8038EFE4029, 0x993FE2C6D07B7FAB}, // 1e-52 {0xDE98520472BDD033, 0xBF8FDB78849A5F96}, // 1e-51 {0x963E66858F6D4440, 0xEF73D256A5C0F77C}, // 1e-50 {0xDDE7001379A44AA8, 0x95A8637627989AAD}, // 1e-49 {0x5560C018580D5D52, 0xBB127C53B17EC159}, // 1e-48 {0xAAB8F01E6E10B4A6, 0xE9D71B689DDE71AF}, // 1e-47 {0xCAB3961304CA70E8, 0x9226712162AB070D}, // 1e-46 {0x3D607B97C5FD0D22, 0xB6B00D69BB55C8D1}, // 1e-45 {0x8CB89A7DB77C506A, 0xE45C10C42A2B3B05}, // 1e-44 {0x77F3608E92ADB242, 0x8EB98A7A9A5B04E3}, // 1e-43 {0x55F038B237591ED3, 0xB267ED1940F1C61C}, // 1e-42 {0x6B6C46DEC52F6688, 0xDF01E85F912E37A3}, // 1e-41 {0x2323AC4B3B3DA015, 0x8B61313BBABCE2C6}, // 1e-40 {0xABEC975E0A0D081A, 0xAE397D8AA96C1B77}, // 1e-39 {0x96E7BD358C904A21, 0xD9C7DCED53C72255}, // 1e-38 {0x7E50D64177DA2E54, 0x881CEA14545C7575}, // 1e-37 {0xDDE50BD1D5D0B9E9, 0xAA242499697392D2}, // 1e-36 {0x955E4EC64B44E864, 0xD4AD2DBFC3D07787}, // 1e-35 {0xBD5AF13BEF0B113E, 0x84EC3C97DA624AB4}, // 1e-34 {0xECB1AD8AEACDD58E, 0xA6274BBDD0FADD61}, // 1e-33 {0x67DE18EDA5814AF2, 0xCFB11EAD453994BA}, // 1e-32 {0x80EACF948770CED7, 0x81CEB32C4B43FCF4}, // 1e-31 {0xA1258379A94D028D, 0xA2425FF75E14FC31}, // 1e-30 {0x096EE45813A04330, 0xCAD2F7F5359A3B3E}, // 1e-29 {0x8BCA9D6E188853FC, 0xFD87B5F28300CA0D}, // 1e-28 {0x775EA264CF55347D, 0x9E74D1B791E07E48}, // 1e-27 {0x95364AFE032A819D, 0xC612062576589DDA}, // 1e-26 {0x3A83DDBD83F52204, 0xF79687AED3EEC551}, // 1e-25 {0xC4926A9672793542, 0x9ABE14CD44753B52}, // 1e-24 {0x75B7053C0F178293, 0xC16D9A0095928A27}, // 1e-23 {0x5324C68B12DD6338, 0xF1C90080BAF72CB1}, // 1e-22 {0xD3F6FC16EBCA5E03, 0x971DA05074DA7BEE}, // 1e-21 {0x88F4BB1CA6BCF584, 0xBCE5086492111AEA}, // 1e-20 {0x2B31E9E3D06C32E5, 0xEC1E4A7DB69561A5}, // 1e-19 {0x3AFF322E62439FCF, 0x9392EE8E921D5D07}, // 1e-18 {0x09BEFEB9FAD487C2, 0xB877AA3236A4B449}, // 1e-17 {0x4C2EBE687989A9B3, 0xE69594BEC44DE15B}, // 1e-16 {0x0F9D37014BF60A10, 0x901D7CF73AB0ACD9}, // 1e-15 {0x538484C19EF38C94, 0xB424DC35095CD80F}, // 1e-14 {0x2865A5F206B06FB9, 0xE12E13424BB40E13}, // 1e-13 {0xF93F87B7442E45D3, 0x8CBCCC096F5088CB}, // 1e-12 {0xF78F69A51539D748, 0xAFEBFF0BCB24AAFE}, // 1e-11 {0xB573440E5A884D1B, 0xDBE6FECEBDEDD5BE}, // 1e-10 {0x31680A88F8953030, 0x89705F4136B4A597}, // 1e-9 {0xFDC20D2B36BA7C3D, 0xABCC77118461CEFC}, // 1e-8 {0x3D32907604691B4C, 0xD6BF94D5E57A42BC}, // 1e-7 {0xA63F9A49C2C1B10F, 0x8637BD05AF6C69B5}, // 1e-6 {0x0FCF80DC33721D53, 0xA7C5AC471B478423}, // 1e-5 {0xD3C36113404EA4A8, 0xD1B71758E219652B}, // 1e-4 {0x645A1CAC083126E9, 0x83126E978D4FDF3B}, // 1e-3 {0x3D70A3D70A3D70A3, 0xA3D70A3D70A3D70A}, // 1e-2 {0xCCCCCCCCCCCCCCCC, 0xCCCCCCCCCCCCCCCC}, // 1e-1 {0x0000000000000000, 0x8000000000000000}, // 1e0 {0x0000000000000000, 0xA000000000000000}, // 1e1 {0x0000000000000000, 0xC800000000000000}, // 1e2 {0x0000000000000000, 0xFA00000000000000}, // 1e3 {0x0000000000000000, 0x9C40000000000000}, // 1e4 {0x0000000000000000, 0xC350000000000000}, // 1e5 {0x0000000000000000, 0xF424000000000000}, // 1e6 {0x0000000000000000, 0x9896800000000000}, // 1e7 {0x0000000000000000, 0xBEBC200000000000}, // 1e8 {0x0000000000000000, 0xEE6B280000000000}, // 1e9 {0x0000000000000000, 0x9502F90000000000}, // 1e10 {0x0000000000000000, 0xBA43B74000000000}, // 1e11 {0x0000000000000000, 0xE8D4A51000000000}, // 1e12 {0x0000000000000000, 0x9184E72A00000000}, // 1e13 {0x0000000000000000, 0xB5E620F480000000}, // 1e14 {0x0000000000000000, 0xE35FA931A0000000}, // 1e15 {0x0000000000000000, 0x8E1BC9BF04000000}, // 1e16 {0x0000000000000000, 0xB1A2BC2EC5000000}, // 1e17 {0x0000000000000000, 0xDE0B6B3A76400000}, // 1e18 {0x0000000000000000, 0x8AC7230489E80000}, // 1e19 {0x0000000000000000, 0xAD78EBC5AC620000}, // 1e20 {0x0000000000000000, 0xD8D726B7177A8000}, // 1e21 {0x0000000000000000, 0x878678326EAC9000}, // 1e22 {0x0000000000000000, 0xA968163F0A57B400}, // 1e23 {0x0000000000000000, 0xD3C21BCECCEDA100}, // 1e24 {0x0000000000000000, 0x84595161401484A0}, // 1e25 {0x0000000000000000, 0xA56FA5B99019A5C8}, // 1e26 {0x0000000000000000, 0xCECB8F27F4200F3A}, // 1e27 {0x4000000000000000, 0x813F3978F8940984}, // 1e28 {0x5000000000000000, 0xA18F07D736B90BE5}, // 1e29 {0xA400000000000000, 0xC9F2C9CD04674EDE}, // 1e30 {0x4D00000000000000, 0xFC6F7C4045812296}, // 1e31 {0xF020000000000000, 0x9DC5ADA82B70B59D}, // 1e32 {0x6C28000000000000, 0xC5371912364CE305}, // 1e33 {0xC732000000000000, 0xF684DF56C3E01BC6}, // 1e34 {0x3C7F400000000000, 0x9A130B963A6C115C}, // 1e35 {0x4B9F100000000000, 0xC097CE7BC90715B3}, // 1e36 {0x1E86D40000000000, 0xF0BDC21ABB48DB20}, // 1e37 {0x1314448000000000, 0x96769950B50D88F4}, // 1e38 {0x17D955A000000000, 0xBC143FA4E250EB31}, // 1e39 {0x5DCFAB0800000000, 0xEB194F8E1AE525FD}, // 1e40 {0x5AA1CAE500000000, 0x92EFD1B8D0CF37BE}, // 1e41 {0xF14A3D9E40000000, 0xB7ABC627050305AD}, // 1e42 {0x6D9CCD05D0000000, 0xE596B7B0C643C719}, // 1e43 {0xE4820023A2000000, 0x8F7E32CE7BEA5C6F}, // 1e44 {0xDDA2802C8A800000, 0xB35DBF821AE4F38B}, // 1e45 {0xD50B2037AD200000, 0xE0352F62A19E306E}, // 1e46 {0x4526F422CC340000, 0x8C213D9DA502DE45}, // 1e47 {0x9670B12B7F410000, 0xAF298D050E4395D6}, // 1e48 {0x3C0CDD765F114000, 0xDAF3F04651D47B4C}, // 1e49 {0xA5880A69FB6AC800, 0x88D8762BF324CD0F}, // 1e50 {0x8EEA0D047A457A00, 0xAB0E93B6EFEE0053}, // 1e51 {0x72A4904598D6D880, 0xD5D238A4ABE98068}, // 1e52 {0x47A6DA2B7F864750, 0x85A36366EB71F041}, // 1e53 {0x999090B65F67D924, 0xA70C3C40A64E6C51}, // 1e54 {0xFFF4B4E3F741CF6D, 0xD0CF4B50CFE20765}, // 1e55 {0xBFF8F10E7A8921A4, 0x82818F1281ED449F}, // 1e56 {0xAFF72D52192B6A0D, 0xA321F2D7226895C7}, // 1e57 {0x9BF4F8A69F764490, 0xCBEA6F8CEB02BB39}, // 1e58 {0x02F236D04753D5B4, 0xFEE50B7025C36A08}, // 1e59 {0x01D762422C946590, 0x9F4F2726179A2245}, // 1e60 {0x424D3AD2B7B97EF5, 0xC722F0EF9D80AAD6}, // 1e61 {0xD2E0898765A7DEB2, 0xF8EBAD2B84E0D58B}, // 1e62 {0x63CC55F49F88EB2F, 0x9B934C3B330C8577}, // 1e63 {0x3CBF6B71C76B25FB, 0xC2781F49FFCFA6D5}, // 1e64 {0x8BEF464E3945EF7A, 0xF316271C7FC3908A}, // 1e65 {0x97758BF0E3CBB5AC, 0x97EDD871CFDA3A56}, // 1e66 {0x3D52EEED1CBEA317, 0xBDE94E8E43D0C8EC}, // 1e67 {0x4CA7AAA863EE4BDD, 0xED63A231D4C4FB27}, // 1e68 {0x8FE8CAA93E74EF6A, 0x945E455F24FB1CF8}, // 1e69 {0xB3E2FD538E122B44, 0xB975D6B6EE39E436}, // 1e70 {0x60DBBCA87196B616, 0xE7D34C64A9C85D44}, // 1e71 {0xBC8955E946FE31CD, 0x90E40FBEEA1D3A4A}, // 1e72 {0x6BABAB6398BDBE41, 0xB51D13AEA4A488DD}, // 1e73 {0xC696963C7EED2DD1, 0xE264589A4DCDAB14}, // 1e74 {0xFC1E1DE5CF543CA2, 0x8D7EB76070A08AEC}, // 1e75 {0x3B25A55F43294BCB, 0xB0DE65388CC8ADA8}, // 1e76 {0x49EF0EB713F39EBE, 0xDD15FE86AFFAD912}, // 1e77 {0x6E3569326C784337, 0x8A2DBF142DFCC7AB}, // 1e78 {0x49C2C37F07965404, 0xACB92ED9397BF996}, // 1e79 {0xDC33745EC97BE906, 0xD7E77A8F87DAF7FB}, // 1e80 {0x69A028BB3DED71A3, 0x86F0AC99B4E8DAFD}, // 1e81 {0xC40832EA0D68CE0C, 0xA8ACD7C0222311BC}, // 1e82 {0xF50A3FA490C30190, 0xD2D80DB02AABD62B}, // 1e83 {0x792667C6DA79E0FA, 0x83C7088E1AAB65DB}, // 1e84 {0x577001B891185938, 0xA4B8CAB1A1563F52}, // 1e85 {0xED4C0226B55E6F86, 0xCDE6FD5E09ABCF26}, // 1e86 {0x544F8158315B05B4, 0x80B05E5AC60B6178}, // 1e87 {0x696361AE3DB1C721, 0xA0DC75F1778E39D6}, // 1e88 {0x03BC3A19CD1E38E9, 0xC913936DD571C84C}, // 1e89 {0x04AB48A04065C723, 0xFB5878494ACE3A5F}, // 1e90 {0x62EB0D64283F9C76, 0x9D174B2DCEC0E47B}, // 1e91 {0x3BA5D0BD324F8394, 0xC45D1DF942711D9A}, // 1e92 {0xCA8F44EC7EE36479, 0xF5746577930D6500}, // 1e93 {0x7E998B13CF4E1ECB, 0x9968BF6ABBE85F20}, // 1e94 {0x9E3FEDD8C321A67E, 0xBFC2EF456AE276E8}, // 1e95 {0xC5CFE94EF3EA101E, 0xEFB3AB16C59B14A2}, // 1e96 {0xBBA1F1D158724A12, 0x95D04AEE3B80ECE5}, // 1e97 {0x2A8A6E45AE8EDC97, 0xBB445DA9CA61281F}, // 1e98 {0xF52D09D71A3293BD, 0xEA1575143CF97226}, // 1e99 {0x593C2626705F9C56, 0x924D692CA61BE758}, // 1e100 {0x6F8B2FB00C77836C, 0xB6E0C377CFA2E12E}, // 1e101 {0x0B6DFB9C0F956447, 0xE498F455C38B997A}, // 1e102 {0x4724BD4189BD5EAC, 0x8EDF98B59A373FEC}, // 1e103 {0x58EDEC91EC2CB657, 0xB2977EE300C50FE7}, // 1e104 {0x2F2967B66737E3ED, 0xDF3D5E9BC0F653E1}, // 1e105 {0xBD79E0D20082EE74, 0x8B865B215899F46C}, // 1e106 {0xECD8590680A3AA11, 0xAE67F1E9AEC07187}, // 1e107 {0xE80E6F4820CC9495, 0xDA01EE641A708DE9}, // 1e108 {0x3109058D147FDCDD, 0x884134FE908658B2}, // 1e109 {0xBD4B46F0599FD415, 0xAA51823E34A7EEDE}, // 1e110 {0x6C9E18AC7007C91A, 0xD4E5E2CDC1D1EA96}, // 1e111 {0x03E2CF6BC604DDB0, 0x850FADC09923329E}, // 1e112 {0x84DB8346B786151C, 0xA6539930BF6BFF45}, // 1e113 {0xE612641865679A63, 0xCFE87F7CEF46FF16}, // 1e114 {0x4FCB7E8F3F60C07E, 0x81F14FAE158C5F6E}, // 1e115 {0xE3BE5E330F38F09D, 0xA26DA3999AEF7749}, // 1e116 {0x5CADF5BFD3072CC5, 0xCB090C8001AB551C}, // 1e117 {0x73D9732FC7C8F7F6, 0xFDCB4FA002162A63}, // 1e118 {0x2867E7FDDCDD9AFA, 0x9E9F11C4014DDA7E}, // 1e119 {0xB281E1FD541501B8, 0xC646D63501A1511D}, // 1e120 {0x1F225A7CA91A4226, 0xF7D88BC24209A565}, // 1e121 {0x3375788DE9B06958, 0x9AE757596946075F}, // 1e122 {0x0052D6B1641C83AE, 0xC1A12D2FC3978937}, // 1e123 {0xC0678C5DBD23A49A, 0xF209787BB47D6B84}, // 1e124 {0xF840B7BA963646E0, 0x9745EB4D50CE6332}, // 1e125 {0xB650E5A93BC3D898, 0xBD176620A501FBFF}, // 1e126 {0xA3E51F138AB4CEBE, 0xEC5D3FA8CE427AFF}, // 1e127 {0xC66F336C36B10137, 0x93BA47C980E98CDF}, // 1e128 {0xB80B0047445D4184, 0xB8A8D9BBE123F017}, // 1e129 {0xA60DC059157491E5, 0xE6D3102AD96CEC1D}, // 1e130 {0x87C89837AD68DB2F, 0x9043EA1AC7E41392}, // 1e131 {0x29BABE4598C311FB, 0xB454E4A179DD1877}, // 1e132 {0xF4296DD6FEF3D67A, 0xE16A1DC9D8545E94}, // 1e133 {0x1899E4A65F58660C, 0x8CE2529E2734BB1D}, // 1e134 {0x5EC05DCFF72E7F8F, 0xB01AE745B101E9E4}, // 1e135 {0x76707543F4FA1F73, 0xDC21A1171D42645D}, // 1e136 {0x6A06494A791C53A8, 0x899504AE72497EBA}, // 1e137 {0x0487DB9D17636892, 0xABFA45DA0EDBDE69}, // 1e138 {0x45A9D2845D3C42B6, 0xD6F8D7509292D603}, // 1e139 {0x0B8A2392BA45A9B2, 0x865B86925B9BC5C2}, // 1e140 {0x8E6CAC7768D7141E, 0xA7F26836F282B732}, // 1e141 {0x3207D795430CD926, 0xD1EF0244AF2364FF}, // 1e142 {0x7F44E6BD49E807B8, 0x8335616AED761F1F}, // 1e143 {0x5F16206C9C6209A6, 0xA402B9C5A8D3A6E7}, // 1e144 {0x36DBA887C37A8C0F, 0xCD036837130890A1}, // 1e145 {0xC2494954DA2C9789, 0x802221226BE55A64}, // 1e146 {0xF2DB9BAA10B7BD6C, 0xA02AA96B06DEB0FD}, // 1e147 {0x6F92829494E5ACC7, 0xC83553C5C8965D3D}, // 1e148 {0xCB772339BA1F17F9, 0xFA42A8B73ABBF48C}, // 1e149 {0xFF2A760414536EFB, 0x9C69A97284B578D7}, // 1e150 {0xFEF5138519684ABA, 0xC38413CF25E2D70D}, // 1e151 {0x7EB258665FC25D69, 0xF46518C2EF5B8CD1}, // 1e152 {0xEF2F773FFBD97A61, 0x98BF2F79D5993802}, // 1e153 {0xAAFB550FFACFD8FA, 0xBEEEFB584AFF8603}, // 1e154 {0x95BA2A53F983CF38, 0xEEAABA2E5DBF6784}, // 1e155 {0xDD945A747BF26183, 0x952AB45CFA97A0B2}, // 1e156 {0x94F971119AEEF9E4, 0xBA756174393D88DF}, // 1e157 {0x7A37CD5601AAB85D, 0xE912B9D1478CEB17}, // 1e158 {0xAC62E055C10AB33A, 0x91ABB422CCB812EE}, // 1e159 {0x577B986B314D6009, 0xB616A12B7FE617AA}, // 1e160 {0xED5A7E85FDA0B80B, 0xE39C49765FDF9D94}, // 1e161 {0x14588F13BE847307, 0x8E41ADE9FBEBC27D}, // 1e162 {0x596EB2D8AE258FC8, 0xB1D219647AE6B31C}, // 1e163 {0x6FCA5F8ED9AEF3BB, 0xDE469FBD99A05FE3}, // 1e164 {0x25DE7BB9480D5854, 0x8AEC23D680043BEE}, // 1e165 {0xAF561AA79A10AE6A, 0xADA72CCC20054AE9}, // 1e166 {0x1B2BA1518094DA04, 0xD910F7FF28069DA4}, // 1e167 {0x90FB44D2F05D0842, 0x87AA9AFF79042286}, // 1e168 {0x353A1607AC744A53, 0xA99541BF57452B28}, // 1e169 {0x42889B8997915CE8, 0xD3FA922F2D1675F2}, // 1e170 {0x69956135FEBADA11, 0x847C9B5D7C2E09B7}, // 1e171 {0x43FAB9837E699095, 0xA59BC234DB398C25}, // 1e172 {0x94F967E45E03F4BB, 0xCF02B2C21207EF2E}, // 1e173 {0x1D1BE0EEBAC278F5, 0x8161AFB94B44F57D}, // 1e174 {0x6462D92A69731732, 0xA1BA1BA79E1632DC}, // 1e175 {0x7D7B8F7503CFDCFE, 0xCA28A291859BBF93}, // 1e176 {0x5CDA735244C3D43E, 0xFCB2CB35E702AF78}, // 1e177 {0x3A0888136AFA64A7, 0x9DEFBF01B061ADAB}, // 1e178 {0x088AAA1845B8FDD0, 0xC56BAEC21C7A1916}, // 1e179 {0x8AAD549E57273D45, 0xF6C69A72A3989F5B}, // 1e180 {0x36AC54E2F678864B, 0x9A3C2087A63F6399}, // 1e181 {0x84576A1BB416A7DD, 0xC0CB28A98FCF3C7F}, // 1e182 {0x656D44A2A11C51D5, 0xF0FDF2D3F3C30B9F}, // 1e183 {0x9F644AE5A4B1B325, 0x969EB7C47859E743}, // 1e184 {0x873D5D9F0DDE1FEE, 0xBC4665B596706114}, // 1e185 {0xA90CB506D155A7EA, 0xEB57FF22FC0C7959}, // 1e186 {0x09A7F12442D588F2, 0x9316FF75DD87CBD8}, // 1e187 {0x0C11ED6D538AEB2F, 0xB7DCBF5354E9BECE}, // 1e188 {0x8F1668C8A86DA5FA, 0xE5D3EF282A242E81}, // 1e189 {0xF96E017D694487BC, 0x8FA475791A569D10}, // 1e190 {0x37C981DCC395A9AC, 0xB38D92D760EC4455}, // 1e191 {0x85BBE253F47B1417, 0xE070F78D3927556A}, // 1e192 {0x93956D7478CCEC8E, 0x8C469AB843B89562}, // 1e193 {0x387AC8D1970027B2, 0xAF58416654A6BABB}, // 1e194 {0x06997B05FCC0319E, 0xDB2E51BFE9D0696A}, // 1e195 {0x441FECE3BDF81F03, 0x88FCF317F22241E2}, // 1e196 {0xD527E81CAD7626C3, 0xAB3C2FDDEEAAD25A}, // 1e197 {0x8A71E223D8D3B074, 0xD60B3BD56A5586F1}, // 1e198 {0xF6872D5667844E49, 0x85C7056562757456}, // 1e199 {0xB428F8AC016561DB, 0xA738C6BEBB12D16C}, // 1e200 {0xE13336D701BEBA52, 0xD106F86E69D785C7}, // 1e201 {0xECC0024661173473, 0x82A45B450226B39C}, // 1e202 {0x27F002D7F95D0190, 0xA34D721642B06084}, // 1e203 {0x31EC038DF7B441F4, 0xCC20CE9BD35C78A5}, // 1e204 {0x7E67047175A15271, 0xFF290242C83396CE}, // 1e205 {0x0F0062C6E984D386, 0x9F79A169BD203E41}, // 1e206 {0x52C07B78A3E60868, 0xC75809C42C684DD1}, // 1e207 {0xA7709A56CCDF8A82, 0xF92E0C3537826145}, // 1e208 {0x88A66076400BB691, 0x9BBCC7A142B17CCB}, // 1e209 {0x6ACFF893D00EA435, 0xC2ABF989935DDBFE}, // 1e210 {0x0583F6B8C4124D43, 0xF356F7EBF83552FE}, // 1e211 {0xC3727A337A8B704A, 0x98165AF37B2153DE}, // 1e212 {0x744F18C0592E4C5C, 0xBE1BF1B059E9A8D6}, // 1e213 {0x1162DEF06F79DF73, 0xEDA2EE1C7064130C}, // 1e214 {0x8ADDCB5645AC2BA8, 0x9485D4D1C63E8BE7}, // 1e215 {0x6D953E2BD7173692, 0xB9A74A0637CE2EE1}, // 1e216 {0xC8FA8DB6CCDD0437, 0xE8111C87C5C1BA99}, // 1e217 {0x1D9C9892400A22A2, 0x910AB1D4DB9914A0}, // 1e218 {0x2503BEB6D00CAB4B, 0xB54D5E4A127F59C8}, // 1e219 {0x2E44AE64840FD61D, 0xE2A0B5DC971F303A}, // 1e220 {0x5CEAECFED289E5D2, 0x8DA471A9DE737E24}, // 1e221 {0x7425A83E872C5F47, 0xB10D8E1456105DAD}, // 1e222 {0xD12F124E28F77719, 0xDD50F1996B947518}, // 1e223 {0x82BD6B70D99AAA6F, 0x8A5296FFE33CC92F}, // 1e224 {0x636CC64D1001550B, 0xACE73CBFDC0BFB7B}, // 1e225 {0x3C47F7E05401AA4E, 0xD8210BEFD30EFA5A}, // 1e226 {0x65ACFAEC34810A71, 0x8714A775E3E95C78}, // 1e227 {0x7F1839A741A14D0D, 0xA8D9D1535CE3B396}, // 1e228 {0x1EDE48111209A050, 0xD31045A8341CA07C}, // 1e229 {0x934AED0AAB460432, 0x83EA2B892091E44D}, // 1e230 {0xF81DA84D5617853F, 0xA4E4B66B68B65D60}, // 1e231 {0x36251260AB9D668E, 0xCE1DE40642E3F4B9}, // 1e232 {0xC1D72B7C6B426019, 0x80D2AE83E9CE78F3}, // 1e233 {0xB24CF65B8612F81F, 0xA1075A24E4421730}, // 1e234 {0xDEE033F26797B627, 0xC94930AE1D529CFC}, // 1e235 {0x169840EF017DA3B1, 0xFB9B7CD9A4A7443C}, // 1e236 {0x8E1F289560EE864E, 0x9D412E0806E88AA5}, // 1e237 {0xF1A6F2BAB92A27E2, 0xC491798A08A2AD4E}, // 1e238 {0xAE10AF696774B1DB, 0xF5B5D7EC8ACB58A2}, // 1e239 {0xACCA6DA1E0A8EF29, 0x9991A6F3D6BF1765}, // 1e240 {0x17FD090A58D32AF3, 0xBFF610B0CC6EDD3F}, // 1e241 {0xDDFC4B4CEF07F5B0, 0xEFF394DCFF8A948E}, // 1e242 {0x4ABDAF101564F98E, 0x95F83D0A1FB69CD9}, // 1e243 {0x9D6D1AD41ABE37F1, 0xBB764C4CA7A4440F}, // 1e244 {0x84C86189216DC5ED, 0xEA53DF5FD18D5513}, // 1e245 {0x32FD3CF5B4E49BB4, 0x92746B9BE2F8552C}, // 1e246 {0x3FBC8C33221DC2A1, 0xB7118682DBB66A77}, // 1e247 {0x0FABAF3FEAA5334A, 0xE4D5E82392A40515}, // 1e248 {0x29CB4D87F2A7400E, 0x8F05B1163BA6832D}, // 1e249 {0x743E20E9EF511012, 0xB2C71D5BCA9023F8}, // 1e250 {0x914DA9246B255416, 0xDF78E4B2BD342CF6}, // 1e251 {0x1AD089B6C2F7548E, 0x8BAB8EEFB6409C1A}, // 1e252 {0xA184AC2473B529B1, 0xAE9672ABA3D0C320}, // 1e253 {0xC9E5D72D90A2741E, 0xDA3C0F568CC4F3E8}, // 1e254 {0x7E2FA67C7A658892, 0x8865899617FB1871}, // 1e255 {0xDDBB901B98FEEAB7, 0xAA7EEBFB9DF9DE8D}, // 1e256 {0x552A74227F3EA565, 0xD51EA6FA85785631}, // 1e257 {0xD53A88958F87275F, 0x8533285C936B35DE}, // 1e258 {0x8A892ABAF368F137, 0xA67FF273B8460356}, // 1e259 {0x2D2B7569B0432D85, 0xD01FEF10A657842C}, // 1e260 {0x9C3B29620E29FC73, 0x8213F56A67F6B29B}, // 1e261 {0x8349F3BA91B47B8F, 0xA298F2C501F45F42}, // 1e262 {0x241C70A936219A73, 0xCB3F2F7642717713}, // 1e263 {0xED238CD383AA0110, 0xFE0EFB53D30DD4D7}, // 1e264 {0xF4363804324A40AA, 0x9EC95D1463E8A506}, // 1e265 {0xB143C6053EDCD0D5, 0xC67BB4597CE2CE48}, // 1e266 {0xDD94B7868E94050A, 0xF81AA16FDC1B81DA}, // 1e267 {0xCA7CF2B4191C8326, 0x9B10A4E5E9913128}, // 1e268 {0xFD1C2F611F63A3F0, 0xC1D4CE1F63F57D72}, // 1e269 {0xBC633B39673C8CEC, 0xF24A01A73CF2DCCF}, // 1e270 {0xD5BE0503E085D813, 0x976E41088617CA01}, // 1e271 {0x4B2D8644D8A74E18, 0xBD49D14AA79DBC82}, // 1e272 {0xDDF8E7D60ED1219E, 0xEC9C459D51852BA2}, // 1e273 {0xCABB90E5C942B503, 0x93E1AB8252F33B45}, // 1e274 {0x3D6A751F3B936243, 0xB8DA1662E7B00A17}, // 1e275 {0x0CC512670A783AD4, 0xE7109BFBA19C0C9D}, // 1e276 {0x27FB2B80668B24C5, 0x906A617D450187E2}, // 1e277 {0xB1F9F660802DEDF6, 0xB484F9DC9641E9DA}, // 1e278 {0x5E7873F8A0396973, 0xE1A63853BBD26451}, // 1e279 {0xDB0B487B6423E1E8, 0x8D07E33455637EB2}, // 1e280 {0x91CE1A9A3D2CDA62, 0xB049DC016ABC5E5F}, // 1e281 {0x7641A140CC7810FB, 0xDC5C5301C56B75F7}, // 1e282 {0xA9E904C87FCB0A9D, 0x89B9B3E11B6329BA}, // 1e283 {0x546345FA9FBDCD44, 0xAC2820D9623BF429}, // 1e284 {0xA97C177947AD4095, 0xD732290FBACAF133}, // 1e285 {0x49ED8EABCCCC485D, 0x867F59A9D4BED6C0}, // 1e286 {0x5C68F256BFFF5A74, 0xA81F301449EE8C70}, // 1e287 {0x73832EEC6FFF3111, 0xD226FC195C6A2F8C}, // 1e288 }; // wuffs_private_impl__f64_powers_of_10 holds powers of 10 that can be exactly // represented by a float64 (what C calls a double). static const double wuffs_private_impl__f64_powers_of_10[23] = { 1e0, 1e1, 1e2, 1e3, 1e4, 1e5, 1e6, 1e7, 1e8, 1e9, 1e10, 1e11, 1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19, 1e20, 1e21, 1e22, }; // ---------------- IEEE 754 Floating Point WUFFS_BASE__MAYBE_STATIC wuffs_base__lossy_value_u16 // wuffs_base__ieee_754_bit_representation__from_f64_to_u16_truncate(double f) { uint64_t u = 0; if (sizeof(uint64_t) == sizeof(double)) { memcpy(&u, &f, sizeof(uint64_t)); } uint16_t neg = ((uint16_t)((u >> 63) << 15)); u &= 0x7FFFFFFFFFFFFFFF; uint64_t exp = u >> 52; uint64_t man = u & 0x000FFFFFFFFFFFFF; if (exp == 0x7FF) { if (man == 0) { // Infinity. wuffs_base__lossy_value_u16 ret; ret.value = neg | 0x7C00; ret.lossy = false; return ret; } // NaN. Shift the 52 mantissa bits to 10 mantissa bits, keeping the most // significant mantissa bit (quiet vs signaling NaNs). Also set the low 9 // bits of ret.value so that the 10-bit mantissa is non-zero. wuffs_base__lossy_value_u16 ret; ret.value = neg | 0x7DFF | ((uint16_t)(man >> 42)); ret.lossy = false; return ret; } else if (exp > 0x40E) { // Truncate to the largest finite f16. wuffs_base__lossy_value_u16 ret; ret.value = neg | 0x7BFF; ret.lossy = true; return ret; } else if (exp <= 0x3E6) { // Truncate to zero. wuffs_base__lossy_value_u16 ret; ret.value = neg; ret.lossy = (u != 0); return ret; } else if (exp <= 0x3F0) { // Normal f64, subnormal f16. // Convert from a 53-bit mantissa (after realizing the implicit bit) to a // 10-bit mantissa and then adjust for the exponent. man |= 0x0010000000000000; uint32_t shift = ((uint32_t)(1051 - exp)); // 1051 = 0x3F0 + 53 - 10. uint64_t shifted_man = man >> shift; wuffs_base__lossy_value_u16 ret; ret.value = neg | ((uint16_t)shifted_man); ret.lossy = (shifted_man << shift) != man; return ret; } // Normal f64, normal f16. // Re-bias from 1023 to 15 and shift above f16's 10 mantissa bits. exp = (exp - 1008) << 10; // 1008 = 1023 - 15 = 0x3FF - 0xF. // Convert from a 52-bit mantissa (excluding the implicit bit) to a 10-bit // mantissa (again excluding the implicit bit). We lose some information if // any of the bottom 42 bits are non-zero. wuffs_base__lossy_value_u16 ret; ret.value = neg | ((uint16_t)exp) | ((uint16_t)(man >> 42)); ret.lossy = (man << 22) != 0; return ret; } WUFFS_BASE__MAYBE_STATIC wuffs_base__lossy_value_u32 // wuffs_base__ieee_754_bit_representation__from_f64_to_u32_truncate(double f) { uint64_t u = 0; if (sizeof(uint64_t) == sizeof(double)) { memcpy(&u, &f, sizeof(uint64_t)); } uint32_t neg = ((uint32_t)(u >> 63)) << 31; u &= 0x7FFFFFFFFFFFFFFF; uint64_t exp = u >> 52; uint64_t man = u & 0x000FFFFFFFFFFFFF; if (exp == 0x7FF) { if (man == 0) { // Infinity. wuffs_base__lossy_value_u32 ret; ret.value = neg | 0x7F800000; ret.lossy = false; return ret; } // NaN. Shift the 52 mantissa bits to 23 mantissa bits, keeping the most // significant mantissa bit (quiet vs signaling NaNs). Also set the low 22 // bits of ret.value so that the 23-bit mantissa is non-zero. wuffs_base__lossy_value_u32 ret; ret.value = neg | 0x7FBFFFFF | ((uint32_t)(man >> 29)); ret.lossy = false; return ret; } else if (exp > 0x47E) { // Truncate to the largest finite f32. wuffs_base__lossy_value_u32 ret; ret.value = neg | 0x7F7FFFFF; ret.lossy = true; return ret; } else if (exp <= 0x369) { // Truncate to zero. wuffs_base__lossy_value_u32 ret; ret.value = neg; ret.lossy = (u != 0); return ret; } else if (exp <= 0x380) { // Normal f64, subnormal f32. // Convert from a 53-bit mantissa (after realizing the implicit bit) to a // 23-bit mantissa and then adjust for the exponent. man |= 0x0010000000000000; uint32_t shift = ((uint32_t)(926 - exp)); // 926 = 0x380 + 53 - 23. uint64_t shifted_man = man >> shift; wuffs_base__lossy_value_u32 ret; ret.value = neg | ((uint32_t)shifted_man); ret.lossy = (shifted_man << shift) != man; return ret; } // Normal f64, normal f32. // Re-bias from 1023 to 127 and shift above f32's 23 mantissa bits. exp = (exp - 896) << 23; // 896 = 1023 - 127 = 0x3FF - 0x7F. // Convert from a 52-bit mantissa (excluding the implicit bit) to a 23-bit // mantissa (again excluding the implicit bit). We lose some information if // any of the bottom 29 bits are non-zero. wuffs_base__lossy_value_u32 ret; ret.value = neg | ((uint32_t)exp) | ((uint32_t)(man >> 29)); ret.lossy = (man << 35) != 0; return ret; } // -------- #define WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE 2047 #define WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION 800 // WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL is the largest N such that // ((10 << N) < (1 << 64)). #define WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL 60 // wuffs_private_impl__high_prec_dec (abbreviated as HPD) is a fixed precision // floating point decimal number, augmented with ±infinity values, but it // cannot represent NaN (Not a Number). // // "High precision" means that the mantissa holds 800 decimal digits. 800 is // WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION. // // An HPD isn't for general purpose arithmetic, only for conversions to and // from IEEE 754 double-precision floating point, where the largest and // smallest positive, finite values are approximately 1.8e+308 and 4.9e-324. // HPD exponents above +2047 mean infinity, below -2047 mean zero. The ±2047 // bounds are further away from zero than ±(324 + 800), where 800 and 2047 is // WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION and // WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE. // // digits[.. num_digits] are the number's digits in big-endian order. The // uint8_t values are in the range [0 ..= 9], not ['0' ..= '9'], where e.g. '7' // is the ASCII value 0x37. // // decimal_point is the index (within digits) of the decimal point. It may be // negative or be larger than num_digits, in which case the explicit digits are // padded with implicit zeroes. // // For example, if num_digits is 3 and digits is "\x07\x08\x09": // - A decimal_point of -2 means ".00789" // - A decimal_point of -1 means ".0789" // - A decimal_point of +0 means ".789" // - A decimal_point of +1 means "7.89" // - A decimal_point of +2 means "78.9" // - A decimal_point of +3 means "789." // - A decimal_point of +4 means "7890." // - A decimal_point of +5 means "78900." // // As above, a decimal_point higher than +2047 means that the overall value is // infinity, lower than -2047 means zero. // // negative is a sign bit. An HPD can distinguish positive and negative zero. // // truncated is whether there are more than // WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION digits, and at least one of those // extra digits are non-zero. The existence of long-tail digits can affect // rounding. // // The "all fields are zero" value is valid, and represents the number +0. typedef struct wuffs_private_impl__high_prec_dec__struct { uint32_t num_digits; int32_t decimal_point; bool negative; bool truncated; uint8_t digits[WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION]; } wuffs_private_impl__high_prec_dec; // wuffs_private_impl__high_prec_dec__trim trims trailing zeroes from the // h->digits[.. h->num_digits] slice. They have no benefit, since we explicitly // track h->decimal_point. // // Preconditions: // - h is non-NULL. static inline void // wuffs_private_impl__high_prec_dec__trim(wuffs_private_impl__high_prec_dec* h) { while ((h->num_digits > 0) && (h->digits[h->num_digits - 1] == 0)) { h->num_digits--; } } // wuffs_private_impl__high_prec_dec__assign sets h to represent the number x. // // Preconditions: // - h is non-NULL. static void // wuffs_private_impl__high_prec_dec__assign(wuffs_private_impl__high_prec_dec* h, uint64_t x, bool negative) { uint32_t n = 0; // Set h->digits. if (x > 0) { // Calculate the digits, working right-to-left. After we determine n (how // many digits there are), copy from buf to h->digits. // // UINT64_MAX, 18446744073709551615, is 20 digits long. It can be faster to // copy a constant number of bytes than a variable number (20 instead of // n). Make buf large enough (and start writing to it from the middle) so // that can we always copy 20 bytes: the slice buf[(20-n) .. (40-n)]. uint8_t buf[40] = {0}; uint8_t* ptr = &buf[20]; do { uint64_t remaining = x / 10; x -= remaining * 10; ptr--; *ptr = (uint8_t)x; n++; x = remaining; } while (x > 0); memcpy(h->digits, ptr, 20); } // Set h's other fields. h->num_digits = n; h->decimal_point = (int32_t)n; h->negative = negative; h->truncated = false; wuffs_private_impl__high_prec_dec__trim(h); } static wuffs_base__status // wuffs_private_impl__high_prec_dec__parse(wuffs_private_impl__high_prec_dec* h, wuffs_base__slice_u8 s, uint32_t options) { if (!h) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } h->num_digits = 0; h->decimal_point = 0; h->negative = false; h->truncated = false; uint8_t* p = s.ptr; uint8_t* q = s.ptr + s.len; if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (;; p++) { if (p >= q) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } else if (*p != '_') { break; } } } // Parse sign. do { if (*p == '+') { p++; } else if (*p == '-') { h->negative = true; p++; } else { break; } if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (;; p++) { if (p >= q) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } else if (*p != '_') { break; } } } } while (0); // Parse digits, up to (and including) a '.', 'E' or 'e'. Examples for each // limb in this if-else chain: // - "0.789" // - "1002.789" // - ".789" // - Other (invalid input). uint32_t nd = 0; int32_t dp = 0; bool no_digits_before_separator = false; if (('0' == *p) && !(options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_MULTIPLE_LEADING_ZEROES)) { p++; for (;; p++) { if (p >= q) { goto after_all; } else if (*p == ((options & WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.')) { p++; goto after_sep; } else if ((*p == 'E') || (*p == 'e')) { p++; goto after_exp; } else if ((*p != '_') || !(options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } } else if (('0' <= *p) && (*p <= '9')) { if (*p == '0') { for (; (p < q) && (*p == '0'); p++) { } } else { h->digits[nd++] = (uint8_t)(*p - '0'); dp = (int32_t)nd; p++; } for (;; p++) { if (p >= q) { goto after_all; } else if (('0' <= *p) && (*p <= '9')) { if (nd < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[nd++] = (uint8_t)(*p - '0'); dp = (int32_t)nd; } else if ('0' != *p) { // Long-tail non-zeroes set the truncated bit. h->truncated = true; } } else if (*p == ((options & WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.')) { p++; goto after_sep; } else if ((*p == 'E') || (*p == 'e')) { p++; goto after_exp; } else if ((*p != '_') || !(options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } } else if (*p == ((options & WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.')) { p++; no_digits_before_separator = true; } else { return wuffs_base__make_status(wuffs_base__error__bad_argument); } after_sep: for (;; p++) { if (p >= q) { goto after_all; } else if ('0' == *p) { if (nd == 0) { // Track leading zeroes implicitly. dp--; } else if (nd < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[nd++] = (uint8_t)(*p - '0'); } } else if (('0' < *p) && (*p <= '9')) { if (nd < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[nd++] = (uint8_t)(*p - '0'); } else { // Long-tail non-zeroes set the truncated bit. h->truncated = true; } } else if ((*p == 'E') || (*p == 'e')) { p++; goto after_exp; } else if ((*p != '_') || !(options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } after_exp: do { if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (;; p++) { if (p >= q) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } else if (*p != '_') { break; } } } int32_t exp_sign = +1; if (*p == '+') { p++; } else if (*p == '-') { exp_sign = -1; p++; } int32_t exp = 0; const int32_t exp_large = WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE + WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION; bool saw_exp_digits = false; for (; p < q; p++) { if ((*p == '_') && (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { // No-op. } else if (('0' <= *p) && (*p <= '9')) { saw_exp_digits = true; if (exp < exp_large) { exp = (10 * exp) + ((int32_t)(*p - '0')); } } else { break; } } if (!saw_exp_digits) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } dp += exp_sign * exp; } while (0); after_all: if (p != q) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } h->num_digits = nd; if (nd == 0) { if (no_digits_before_separator) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } h->decimal_point = 0; } else if (dp < -WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) { h->decimal_point = -WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE - 1; } else if (dp > +WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) { h->decimal_point = +WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE + 1; } else { h->decimal_point = dp; } wuffs_private_impl__high_prec_dec__trim(h); return wuffs_base__make_status(NULL); } // -------- // wuffs_private_impl__high_prec_dec__lshift_num_new_digits returns the number // of additional decimal digits when left-shifting by shift. // // See below for preconditions. static uint32_t // wuffs_private_impl__high_prec_dec__lshift_num_new_digits( wuffs_private_impl__high_prec_dec* h, uint32_t shift) { // Masking with 0x3F should be unnecessary (assuming the preconditions) but // it's cheap and ensures that we don't overflow the // wuffs_private_impl__hpd_left_shift array. shift &= 63; uint32_t x_a = wuffs_private_impl__hpd_left_shift[shift]; uint32_t x_b = wuffs_private_impl__hpd_left_shift[shift + 1]; uint32_t num_new_digits = x_a >> 11; uint32_t pow5_a = 0x7FF & x_a; uint32_t pow5_b = 0x7FF & x_b; const uint8_t* pow5 = &wuffs_private_impl__powers_of_5[pow5_a]; uint32_t i = 0; uint32_t n = pow5_b - pow5_a; for (; i < n; i++) { if (i >= h->num_digits) { return num_new_digits - 1; } else if (h->digits[i] == pow5[i]) { continue; } else if (h->digits[i] < pow5[i]) { return num_new_digits - 1; } else { return num_new_digits; } } return num_new_digits; } // -------- // wuffs_private_impl__high_prec_dec__rounded_integer returns the integral // (non-fractional) part of h, provided that it is 18 or fewer decimal digits. // For 19 or more digits, it returns UINT64_MAX. Note that: // - (1 << 53) is 9007199254740992, which has 16 decimal digits. // - (1 << 56) is 72057594037927936, which has 17 decimal digits. // - (1 << 59) is 576460752303423488, which has 18 decimal digits. // - (1 << 63) is 9223372036854775808, which has 19 decimal digits. // and that IEEE 754 double precision has 52 mantissa bits. // // That integral part is rounded-to-even: rounding 7.5 or 8.5 both give 8. // // h's negative bit is ignored: rounding -8.6 returns 9. // // See below for preconditions. static uint64_t // wuffs_private_impl__high_prec_dec__rounded_integer( wuffs_private_impl__high_prec_dec* h) { if ((h->num_digits == 0) || (h->decimal_point < 0)) { return 0; } else if (h->decimal_point > 18) { return UINT64_MAX; } uint32_t dp = (uint32_t)(h->decimal_point); uint64_t n = 0; uint32_t i = 0; for (; i < dp; i++) { n = (10 * n) + ((i < h->num_digits) ? h->digits[i] : 0); } bool round_up = false; if (dp < h->num_digits) { round_up = h->digits[dp] >= 5; if ((h->digits[dp] == 5) && (dp + 1 == h->num_digits)) { // We are exactly halfway. If we're truncated, round up, otherwise round // to even. round_up = h->truncated || // ((dp > 0) && (1 & h->digits[dp - 1])); } } if (round_up) { n++; } return n; } // wuffs_private_impl__high_prec_dec__small_xshift shifts h's number (where 'x' // is 'l' or 'r' for left or right) by a small shift value. // // Preconditions: // - h is non-NULL. // - h->decimal_point is "not extreme". // - shift is non-zero. // - shift is "a small shift". // // "Not extreme" means within ±WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE. // // "A small shift" means not more than // WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL. // // wuffs_private_impl__high_prec_dec__rounded_integer and // wuffs_private_impl__high_prec_dec__lshift_num_new_digits have the same // preconditions. // // wuffs_private_impl__high_prec_dec__lshift keeps the first two preconditions // but not the last two. Its shift argument is signed and does not need to be // "small": zero is a no-op, positive means left shift and negative means right // shift. static void // wuffs_private_impl__high_prec_dec__small_lshift( wuffs_private_impl__high_prec_dec* h, uint32_t shift) { if (h->num_digits == 0) { return; } uint32_t num_new_digits = wuffs_private_impl__high_prec_dec__lshift_num_new_digits(h, shift); uint32_t rx = h->num_digits - 1; // Read index. uint32_t wx = h->num_digits - 1 + num_new_digits; // Write index. uint64_t n = 0; // Repeat: pick up a digit, put down a digit, right to left. while (((int32_t)rx) >= 0) { n += ((uint64_t)(h->digits[rx])) << shift; uint64_t quo = n / 10; uint64_t rem = n - (10 * quo); if (wx < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[wx] = (uint8_t)rem; } else if (rem > 0) { h->truncated = true; } n = quo; wx--; rx--; } // Put down leading digits, right to left. while (n > 0) { uint64_t quo = n / 10; uint64_t rem = n - (10 * quo); if (wx < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[wx] = (uint8_t)rem; } else if (rem > 0) { h->truncated = true; } n = quo; wx--; } // Finish. h->num_digits += num_new_digits; if (h->num_digits > WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->num_digits = WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION; } h->decimal_point += (int32_t)num_new_digits; wuffs_private_impl__high_prec_dec__trim(h); } static void // wuffs_private_impl__high_prec_dec__small_rshift( wuffs_private_impl__high_prec_dec* h, uint32_t shift) { uint32_t rx = 0; // Read index. uint32_t wx = 0; // Write index. uint64_t n = 0; // Pick up enough leading digits to cover the first shift. while ((n >> shift) == 0) { if (rx < h->num_digits) { // Read a digit. n = (10 * n) + h->digits[rx++]; } else if (n == 0) { // h's number used to be zero and remains zero. return; } else { // Read sufficient implicit trailing zeroes. while ((n >> shift) == 0) { n = 10 * n; rx++; } break; } } h->decimal_point -= ((int32_t)(rx - 1)); if (h->decimal_point < -WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) { // After the shift, h's number is effectively zero. h->num_digits = 0; h->decimal_point = 0; h->truncated = false; return; } // Repeat: pick up a digit, put down a digit, left to right. uint64_t mask = (((uint64_t)(1)) << shift) - 1; while (rx < h->num_digits) { uint8_t new_digit = ((uint8_t)(n >> shift)); n = (10 * (n & mask)) + h->digits[rx++]; h->digits[wx++] = new_digit; } // Put down trailing digits, left to right. while (n > 0) { uint8_t new_digit = ((uint8_t)(n >> shift)); n = 10 * (n & mask); if (wx < WUFFS_PRIVATE_IMPL__HPD__DIGITS_PRECISION) { h->digits[wx++] = new_digit; } else if (new_digit > 0) { h->truncated = true; } } // Finish. h->num_digits = wx; wuffs_private_impl__high_prec_dec__trim(h); } static void // wuffs_private_impl__high_prec_dec__lshift(wuffs_private_impl__high_prec_dec* h, int32_t shift) { if (shift > 0) { while (shift > +WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL) { wuffs_private_impl__high_prec_dec__small_lshift( h, WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL); shift -= WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL; } wuffs_private_impl__high_prec_dec__small_lshift(h, ((uint32_t)(+shift))); } else if (shift < 0) { while (shift < -WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL) { wuffs_private_impl__high_prec_dec__small_rshift( h, WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL); shift += WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL; } wuffs_private_impl__high_prec_dec__small_rshift(h, ((uint32_t)(-shift))); } } // -------- // wuffs_private_impl__high_prec_dec__round_etc rounds h's number. For those // functions that take an n argument, rounding produces at most n digits (which // is not necessarily at most n decimal places). Negative n values are ignored, // as well as any n greater than or equal to h's number of digits. The // etc__round_just_enough function implicitly chooses an n to implement // WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION. // // Preconditions: // - h is non-NULL. // - h->decimal_point is "not extreme". // // "Not extreme" means within ±WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE. static void // wuffs_private_impl__high_prec_dec__round_down( wuffs_private_impl__high_prec_dec* h, int32_t n) { if ((n < 0) || (h->num_digits <= (uint32_t)n)) { return; } h->num_digits = (uint32_t)(n); wuffs_private_impl__high_prec_dec__trim(h); } static void // wuffs_private_impl__high_prec_dec__round_up( wuffs_private_impl__high_prec_dec* h, int32_t n) { if ((n < 0) || (h->num_digits <= (uint32_t)n)) { return; } for (n--; n >= 0; n--) { if (h->digits[n] < 9) { h->digits[n]++; h->num_digits = (uint32_t)(n + 1); return; } } // The number is all 9s. Change to a single 1 and adjust the decimal point. h->digits[0] = 1; h->num_digits = 1; h->decimal_point++; } static void // wuffs_private_impl__high_prec_dec__round_nearest( wuffs_private_impl__high_prec_dec* h, int32_t n) { if ((n < 0) || (h->num_digits <= (uint32_t)n)) { return; } bool up = h->digits[n] >= 5; if ((h->digits[n] == 5) && ((n + 1) == ((int32_t)(h->num_digits)))) { up = h->truncated || // ((n > 0) && ((h->digits[n - 1] & 1) != 0)); } if (up) { wuffs_private_impl__high_prec_dec__round_up(h, n); } else { wuffs_private_impl__high_prec_dec__round_down(h, n); } } static void // wuffs_private_impl__high_prec_dec__round_just_enough( wuffs_private_impl__high_prec_dec* h, int32_t exp2, uint64_t mantissa) { // The magic numbers 52 and 53 in this function are because IEEE 754 double // precision has 52 mantissa bits. // // Let f be the floating point number represented by exp2 and mantissa (and // also the number in h): the number (mantissa * (2 ** (exp2 - 52))). // // If f is zero or a small integer, we can return early. if ((mantissa == 0) || ((exp2 < 53) && (h->decimal_point >= ((int32_t)(h->num_digits))))) { return; } // The smallest normal f has an exp2 of -1022 and a mantissa of (1 << 52). // Subnormal numbers have the same exp2 but a smaller mantissa. static const int32_t min_incl_normal_exp2 = -1022; static const uint64_t min_incl_normal_mantissa = 0x0010000000000000ul; // Compute lower and upper bounds such that any number between them (possibly // inclusive) will round to f. First, the lower bound. Our number f is: // ((mantissa + 0) * (2 ** ( exp2 - 52))) // // The next lowest floating point number is: // ((mantissa - 1) * (2 ** ( exp2 - 52))) // unless (mantissa - 1) drops the (1 << 52) bit and exp2 is not the // min_incl_normal_exp2. Either way, call it: // ((l_mantissa) * (2 ** (l_exp2 - 52))) // // The lower bound is halfway between them (noting that 52 became 53): // (((2 * l_mantissa) + 1) * (2 ** (l_exp2 - 53))) int32_t l_exp2 = exp2; uint64_t l_mantissa = mantissa - 1; if ((exp2 > min_incl_normal_exp2) && (mantissa <= min_incl_normal_mantissa)) { l_exp2 = exp2 - 1; l_mantissa = (2 * mantissa) - 1; } wuffs_private_impl__high_prec_dec lower; wuffs_private_impl__high_prec_dec__assign(&lower, (2 * l_mantissa) + 1, false); wuffs_private_impl__high_prec_dec__lshift(&lower, l_exp2 - 53); // Next, the upper bound. Our number f is: // ((mantissa + 0) * (2 ** (exp2 - 52))) // // The next highest floating point number is: // ((mantissa + 1) * (2 ** (exp2 - 52))) // // The upper bound is halfway between them (noting that 52 became 53): // (((2 * mantissa) + 1) * (2 ** (exp2 - 53))) wuffs_private_impl__high_prec_dec upper; wuffs_private_impl__high_prec_dec__assign(&upper, (2 * mantissa) + 1, false); wuffs_private_impl__high_prec_dec__lshift(&upper, exp2 - 53); // The lower and upper bounds are possible outputs only if the original // mantissa is even, so that IEEE round-to-even would round to the original // mantissa and not its neighbors. bool inclusive = (mantissa & 1) == 0; // As we walk the digits, we want to know whether rounding up would fall // within the upper bound. This is tracked by upper_delta: // - When -1, the digits of h and upper are the same so far. // - When +0, we saw a difference of 1 between h and upper on a previous // digit and subsequently only 9s for h and 0s for upper. Thus, rounding // up may fall outside of the bound if !inclusive. // - When +1, the difference is greater than 1 and we know that rounding up // falls within the bound. // // This is a state machine with three states. The numerical value for each // state (-1, +0 or +1) isn't important, other than their order. int upper_delta = -1; // We can now figure out the shortest number of digits required. Walk the // digits until h has distinguished itself from lower or upper. // // The zi and zd variables are indexes and digits, for z in l (lower), h (the // number) and u (upper). // // The lower, h and upper numbers may have their decimal points at different // places. In this case, upper is the longest, so we iterate ui starting from // 0 and iterate li and hi starting from either 0 or -1. int32_t ui = 0; for (;; ui++) { // Calculate hd, the middle number's digit. int32_t hi = ui - upper.decimal_point + h->decimal_point; if (hi >= ((int32_t)(h->num_digits))) { break; } uint8_t hd = (((uint32_t)hi) < h->num_digits) ? h->digits[hi] : 0; // Calculate ld, the lower bound's digit. int32_t li = ui - upper.decimal_point + lower.decimal_point; uint8_t ld = (((uint32_t)li) < lower.num_digits) ? lower.digits[li] : 0; // We can round down (truncate) if lower has a different digit than h or if // lower is inclusive and is exactly the result of rounding down (i.e. we // have reached the final digit of lower). bool can_round_down = (ld != hd) || // (inclusive && ((li + 1) == ((int32_t)(lower.num_digits)))); // Calculate ud, the upper bound's digit, and update upper_delta. uint8_t ud = (((uint32_t)ui) < upper.num_digits) ? upper.digits[ui] : 0; if (upper_delta < 0) { if ((hd + 1) < ud) { // For example: // h = 12345??? // upper = 12347??? upper_delta = +1; } else if (hd != ud) { // For example: // h = 12345??? // upper = 12346??? upper_delta = +0; } } else if (upper_delta == 0) { if ((hd != 9) || (ud != 0)) { // For example: // h = 1234598? // upper = 1234600? upper_delta = +1; } } // We can round up if upper has a different digit than h and either upper // is inclusive or upper is bigger than the result of rounding up. bool can_round_up = (upper_delta > 0) || // ((upper_delta == 0) && // (inclusive || ((ui + 1) < ((int32_t)(upper.num_digits))))); // If we can round either way, round to nearest. If we can round only one // way, do it. If we can't round, continue the loop. if (can_round_down) { if (can_round_up) { wuffs_private_impl__high_prec_dec__round_nearest(h, hi + 1); return; } else { wuffs_private_impl__high_prec_dec__round_down(h, hi + 1); return; } } else { if (can_round_up) { wuffs_private_impl__high_prec_dec__round_up(h, hi + 1); return; } } } } // -------- // wuffs_private_impl__parse_number_f64_eisel_lemire produces the IEEE 754 // double-precision value for an exact mantissa and base-10 exponent. For // example: // - when parsing "12345.678e+02", man is 12345678 and exp10 is -1. // - when parsing "-12", man is 12 and exp10 is 0. Processing the leading // minus sign is the responsibility of the caller, not this function. // // On success, it returns a non-negative int64_t such that the low 63 bits hold // the 11-bit exponent and 52-bit mantissa. // // On failure, it returns a negative value. // // The algorithm is based on an original idea by Michael Eisel that was refined // by Daniel Lemire. See // https://lemire.me/blog/2020/03/10/fast-float-parsing-in-practice/ // and // https://nigeltao.github.io/blog/2020/eisel-lemire.html // // Preconditions: // - man is non-zero. // - exp10 is in the range [-307 ..= 288], the same range of the // wuffs_private_impl__powers_of_10 array. // // The exp10 range (and the fact that man is in the range [1 ..= UINT64_MAX], // approximately [1 ..= 1.85e+19]) means that (man * (10 ** exp10)) is in the // range [1e-307 ..= 1.85e+307]. This is entirely within the range of normal // (neither subnormal nor non-finite) f64 values: DBL_MIN and DBL_MAX are // approximately 2.23e–308 and 1.80e+308. static int64_t // wuffs_private_impl__parse_number_f64_eisel_lemire(uint64_t man, int32_t exp10) { // Look up the (possibly truncated) base-2 representation of (10 ** exp10). // The look-up table was constructed so that it is already normalized: the // table entry's mantissa's MSB (most significant bit) is on. const uint64_t* po10 = &wuffs_private_impl__powers_of_10[exp10 + 307][0]; // Normalize the man argument. The (man != 0) precondition means that a // non-zero bit exists. uint32_t clz = wuffs_base__count_leading_zeroes_u64(man); man <<= clz; // Calculate the return value's base-2 exponent. We might tweak it by ±1 // later, but its initial value comes from a linear scaling of exp10, // converting from power-of-10 to power-of-2, and adjusting by clz. // // The magic constants are: // - 1087 = 1023 + 64. The 1023 is the f64 exponent bias. The 64 is because // the look-up table uses 64-bit mantissas. // - 217706 is such that the ratio 217706 / 65536 ≈ 3.321930 is close enough // (over the practical range of exp10) to log(10) / log(2) ≈ 3.321928. // - 65536 = 1<<16 is arbitrary but a power of 2, so division is a shift. // // Equality of the linearly-scaled value and the actual power-of-2, over the // range of exp10 arguments that this function accepts, is confirmed by // script/print-mpb-powers-of-10.go uint64_t ret_exp2 = ((uint64_t)(((217706 * exp10) >> 16) + 1087)) - ((uint64_t)clz); // Multiply the two mantissas. Normalization means that both mantissas are at // least (1<<63), so the 128-bit product must be at least (1<<126). The high // 64 bits of the product, x_hi, must therefore be at least (1<<62). // // As a consequence, x_hi has either 0 or 1 leading zeroes. Shifting x_hi // right by either 9 or 10 bits (depending on x_hi's MSB) will therefore // leave the top 10 MSBs (bits 54 ..= 63) off and the 11th MSB (bit 53) on. wuffs_base__multiply_u64__output x = wuffs_base__multiply_u64(man, po10[1]); uint64_t x_hi = x.hi; uint64_t x_lo = x.lo; // Before we shift right by at least 9 bits, recall that the look-up table // entry was possibly truncated. We have so far only calculated a lower bound // for the product (man * e), where e is (10 ** exp10). The upper bound would // add a further (man * 1) to the 128-bit product, which overflows the lower // 64-bit limb if ((x_lo + man) < man). // // If overflow occurs, that adds 1 to x_hi. Since we're about to shift right // by at least 9 bits, that carried 1 can be ignored unless the higher 64-bit // limb's low 9 bits are all on. // // For example, parsing "9999999999999999999" will take the if-true branch // here, since: // - x_hi = 0x4563918244F3FFFF // - x_lo = 0x8000000000000000 // - man = 0x8AC7230489E7FFFF if (((x_hi & 0x1FF) == 0x1FF) && ((x_lo + man) < man)) { // Refine our calculation of (man * e). Before, our approximation of e used // a "low resolution" 64-bit mantissa. Now use a "high resolution" 128-bit // mantissa. We've already calculated x = (man * bits_0_to_63_incl_of_e). // Now calculate y = (man * bits_64_to_127_incl_of_e). wuffs_base__multiply_u64__output y = wuffs_base__multiply_u64(man, po10[0]); uint64_t y_hi = y.hi; uint64_t y_lo = y.lo; // Merge the 128-bit x and 128-bit y, which overlap by 64 bits, to // calculate the 192-bit product of the 64-bit man by the 128-bit e. // As we exit this if-block, we only care about the high 128 bits // (merged_hi and merged_lo) of that 192-bit product. // // For example, parsing "1.234e-45" will take the if-true branch here, // since: // - x_hi = 0x70B7E3696DB29FFF // - x_lo = 0xE040000000000000 // - y_hi = 0x33718BBEAB0E0D7A // - y_lo = 0xA880000000000000 uint64_t merged_hi = x_hi; uint64_t merged_lo = x_lo + y_hi; if (merged_lo < x_lo) { merged_hi++; // Carry the overflow bit. } // The "high resolution" approximation of e is still a lower bound. Once // again, see if the upper bound is large enough to produce a different // result. This time, if it does, give up instead of reaching for an even // more precise approximation to e. // // This three-part check is similar to the two-part check that guarded the // if block that we're now in, but it has an extra term for the middle 64 // bits (checking that adding 1 to merged_lo would overflow). // // For example, parsing "5.9604644775390625e-8" will take the if-true // branch here, since: // - merged_hi = 0x7FFFFFFFFFFFFFFF // - merged_lo = 0xFFFFFFFFFFFFFFFF // - y_lo = 0x4DB3FFC120988200 // - man = 0xD3C21BCECCEDA100 if (((merged_hi & 0x1FF) == 0x1FF) && ((merged_lo + 1) == 0) && (y_lo + man < man)) { return -1; } // Replace the 128-bit x with merged. x_hi = merged_hi; x_lo = merged_lo; } // As mentioned above, shifting x_hi right by either 9 or 10 bits will leave // the top 10 MSBs (bits 54 ..= 63) off and the 11th MSB (bit 53) on. If the // MSB (before shifting) was on, adjust ret_exp2 for the larger shift. // // Having bit 53 on (and higher bits off) means that ret_mantissa is a 54-bit // number. uint64_t msb = x_hi >> 63; uint64_t ret_mantissa = x_hi >> (msb + 9); ret_exp2 -= 1 ^ msb; // IEEE 754 rounds to-nearest with ties rounded to-even. Rounding to-even can // be tricky. If we're half-way between two exactly representable numbers // (x's low 73 bits are zero and the next 2 bits that matter are "01"), give // up instead of trying to pick the winner. // // Technically, we could tighten the condition by changing "73" to "73 or 74, // depending on msb", but a flat "73" is simpler. // // For example, parsing "1e+23" will take the if-true branch here, since: // - x_hi = 0x54B40B1F852BDA00 // - ret_mantissa = 0x002A5A058FC295ED if ((x_lo == 0) && ((x_hi & 0x1FF) == 0) && ((ret_mantissa & 3) == 1)) { return -1; } // If we're not halfway then it's rounding to-nearest. Starting with a 54-bit // number, carry the lowest bit (bit 0) up if it's on. Regardless of whether // it was on or off, shifting right by one then produces a 53-bit number. If // carrying up overflowed, shift again. ret_mantissa += ret_mantissa & 1; ret_mantissa >>= 1; // This if block is equivalent to (but benchmarks slightly faster than) the // following branchless form: // uint64_t overflow_adjustment = ret_mantissa >> 53; // ret_mantissa >>= overflow_adjustment; // ret_exp2 += overflow_adjustment; // // For example, parsing "7.2057594037927933e+16" will take the if-true // branch here, since: // - x_hi = 0x7FFFFFFFFFFFFE80 // - ret_mantissa = 0x0020000000000000 if ((ret_mantissa >> 53) > 0) { ret_mantissa >>= 1; ret_exp2++; } // Starting with a 53-bit number, IEEE 754 double-precision normal numbers // have an implicit mantissa bit. Mask that away and keep the low 52 bits. ret_mantissa &= 0x000FFFFFFFFFFFFF; // Pack the bits and return. return ((int64_t)(ret_mantissa | (ret_exp2 << 52))); } // -------- static wuffs_base__result_f64 // wuffs_private_impl__parse_number_f64_special(wuffs_base__slice_u8 s, uint32_t options) { do { if (options & WUFFS_BASE__PARSE_NUMBER_FXX__REJECT_INF_AND_NAN) { goto fail; } uint8_t* p = s.ptr; uint8_t* q = s.ptr + s.len; for (; (p < q) && (*p == '_'); p++) { } if (p >= q) { goto fail; } // Parse sign. bool negative = false; do { if (*p == '+') { p++; } else if (*p == '-') { negative = true; p++; } else { break; } for (; (p < q) && (*p == '_'); p++) { } } while (0); if (p >= q) { goto fail; } bool nan = false; switch (p[0]) { case 'I': case 'i': if (((q - p) < 3) || // ((p[1] != 'N') && (p[1] != 'n')) || // ((p[2] != 'F') && (p[2] != 'f'))) { goto fail; } p += 3; if ((p >= q) || (*p == '_')) { break; } else if (((q - p) < 5) || // ((p[0] != 'I') && (p[0] != 'i')) || // ((p[1] != 'N') && (p[1] != 'n')) || // ((p[2] != 'I') && (p[2] != 'i')) || // ((p[3] != 'T') && (p[3] != 't')) || // ((p[4] != 'Y') && (p[4] != 'y'))) { goto fail; } p += 5; if ((p >= q) || (*p == '_')) { break; } goto fail; case 'N': case 'n': if (((q - p) < 3) || // ((p[1] != 'A') && (p[1] != 'a')) || // ((p[2] != 'N') && (p[2] != 'n'))) { goto fail; } p += 3; if ((p >= q) || (*p == '_')) { nan = true; break; } goto fail; default: goto fail; } // Finish. for (; (p < q) && (*p == '_'); p++) { } if (p != q) { goto fail; } wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64( (nan ? 0x7FFFFFFFFFFFFFFF : 0x7FF0000000000000) | (negative ? 0x8000000000000000 : 0)); return ret; } while (0); fail: do { wuffs_base__result_f64 ret; ret.status.repr = wuffs_base__error__bad_argument; ret.value = 0; return ret; } while (0); } WUFFS_BASE__MAYBE_STATIC wuffs_base__result_f64 // wuffs_private_impl__high_prec_dec__to_f64(wuffs_private_impl__high_prec_dec* h, uint32_t options) { do { // powers converts decimal powers of 10 to binary powers of 2. For example, // (10000 >> 13) is 1. It stops before the elements exceed 60, also known // as WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL. // // This rounds down (1<<13 is a lower bound for 1e4). Adding 1 to the array // element value rounds up (1<<14 is an upper bound for 1e4) while staying // at or below WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL. // // When starting in the range [1e+1 .. 1e+2] (i.e. h->decimal_point == +2), // powers[2] == 6 and so: // - Right shifting by 6+0 produces the range [10/64 .. 100/64] = // [0.156250 .. 1.56250]. The resultant h->decimal_point is +0 or +1. // - Right shifting by 6+1 produces the range [10/128 .. 100/128] = // [0.078125 .. 0.78125]. The resultant h->decimal_point is -1 or -0. // // When starting in the range [1e-3 .. 1e-2] (i.e. h->decimal_point == -2), // powers[2] == 6 and so: // - Left shifting by 6+0 produces the range [0.001*64 .. 0.01*64] = // [0.064 .. 0.64]. The resultant h->decimal_point is -1 or -0. // - Left shifting by 6+1 produces the range [0.001*128 .. 0.01*128] = // [0.128 .. 1.28]. The resultant h->decimal_point is +0 or +1. // // Thus, when targeting h->decimal_point being +0 or +1, use (powers[n]+0) // when right shifting but (powers[n]+1) when left shifting. static const uint32_t num_powers = 19; static const uint8_t powers[19] = { 0, 3, 6, 9, 13, 16, 19, 23, 26, 29, // 33, 36, 39, 43, 46, 49, 53, 56, 59, // }; // Handle zero and obvious extremes. The largest and smallest positive // finite f64 values are approximately 1.8e+308 and 4.9e-324. if ((h->num_digits == 0) || (h->decimal_point < -326)) { goto zero; } else if (h->decimal_point > 310) { goto infinity; } // Try the fast Eisel-Lemire algorithm again. Calculating the (man, exp10) // pair from the high_prec_dec h is more correct but slower than the // approach taken in wuffs_base__parse_number_f64. The latter is optimized // for the common cases (e.g. assuming no underscores or a leading '+' // sign) rather than the full set of cases allowed by the Wuffs API. // // When we have 19 or fewer mantissa digits, run Eisel-Lemire once (trying // for an exact result). When we have more than 19 mantissa digits, run it // twice to get a lower and upper bound. We still have an exact result // (within f64's rounding margin) if both bounds are equal (and valid). uint32_t i_max = h->num_digits; if (i_max > 19) { i_max = 19; } int32_t exp10 = h->decimal_point - ((int32_t)i_max); if ((-307 <= exp10) && (exp10 <= 288)) { uint64_t man = 0; uint32_t i; for (i = 0; i < i_max; i++) { man = (10 * man) + h->digits[i]; } while (man != 0) { // The 'while' is just an 'if' that we can 'break'. int64_t r0 = wuffs_private_impl__parse_number_f64_eisel_lemire(man + 0, exp10); if (r0 < 0) { break; } else if (h->num_digits > 19) { int64_t r1 = wuffs_private_impl__parse_number_f64_eisel_lemire(man + 1, exp10); if (r1 != r0) { break; } } wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64( ((uint64_t)r0) | (((uint64_t)(h->negative)) << 63)); return ret; } } // When Eisel-Lemire fails, fall back to Simple Decimal Conversion. See // https://nigeltao.github.io/blog/2020/parse-number-f64-simple.html // // Scale by powers of 2 until we're in the range [0.1 .. 10]. Equivalently, // that h->decimal_point is +0 or +1. // // First we shift right while at or above 10... const int32_t f64_bias = -1023; int32_t exp2 = 0; while (h->decimal_point > 1) { uint32_t n = (uint32_t)(+h->decimal_point); uint32_t shift = (n < num_powers) ? powers[n] : WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL; wuffs_private_impl__high_prec_dec__small_rshift(h, shift); if (h->decimal_point < -WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) { goto zero; } exp2 += (int32_t)shift; } // ...then we shift left while below 0.1. while (h->decimal_point < 0) { uint32_t shift; uint32_t n = (uint32_t)(-h->decimal_point); shift = (n < num_powers) // The +1 is per "when targeting h->decimal_point being +0 or // +1... when left shifting" in the powers comment above. ? (powers[n] + 1u) : WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL; wuffs_private_impl__high_prec_dec__small_lshift(h, shift); if (h->decimal_point > +WUFFS_PRIVATE_IMPL__HPD__DECIMAL_POINT__RANGE) { goto infinity; } exp2 -= (int32_t)shift; } // To get from "in the range [0.1 .. 10]" to "in the range [1 .. 2]" (which // will give us our exponent in base-2), the mantissa's first 3 digits will // determine the final left shift, equal to 52 (the number of explicit f64 // bits) plus an additional adjustment. int man3 = (100 * h->digits[0]) + ((h->num_digits > 1) ? (10 * h->digits[1]) : 0) + ((h->num_digits > 2) ? h->digits[2] : 0); int32_t additional_lshift = 0; if (h->decimal_point == 0) { // The value is in [0.1 .. 1]. if (man3 < 125) { additional_lshift = +4; } else if (man3 < 250) { additional_lshift = +3; } else if (man3 < 500) { additional_lshift = +2; } else { additional_lshift = +1; } } else { // The value is in [1 .. 10]. if (man3 < 200) { additional_lshift = -0; } else if (man3 < 400) { additional_lshift = -1; } else if (man3 < 800) { additional_lshift = -2; } else { additional_lshift = -3; } } exp2 -= additional_lshift; uint32_t final_lshift = (uint32_t)(52 + additional_lshift); // The minimum normal exponent is (f64_bias + 1). while ((f64_bias + 1) > exp2) { uint32_t n = (uint32_t)((f64_bias + 1) - exp2); if (n > WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL) { n = WUFFS_PRIVATE_IMPL__HPD__SHIFT__MAX_INCL; } wuffs_private_impl__high_prec_dec__small_rshift(h, n); exp2 += (int32_t)n; } // Check for overflow. if ((exp2 - f64_bias) >= 0x07FF) { // (1 << 11) - 1. goto infinity; } // Extract 53 bits for the mantissa (in base-2). wuffs_private_impl__high_prec_dec__small_lshift(h, final_lshift); uint64_t man2 = wuffs_private_impl__high_prec_dec__rounded_integer(h); // Rounding might have added one bit. If so, shift and re-check overflow. if ((man2 >> 53) != 0) { man2 >>= 1; exp2++; if ((exp2 - f64_bias) >= 0x07FF) { // (1 << 11) - 1. goto infinity; } } // Handle subnormal numbers. if ((man2 >> 52) == 0) { exp2 = f64_bias; } // Pack the bits and return. uint64_t exp2_bits = (uint64_t)((exp2 - f64_bias) & 0x07FF); // (1 << 11) - 1. uint64_t bits = (man2 & 0x000FFFFFFFFFFFFF) | // (1 << 52) - 1. (exp2_bits << 52) | // (h->negative ? 0x8000000000000000 : 0); // (1 << 63). wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64(bits); return ret; } while (0); zero: do { uint64_t bits = h->negative ? 0x8000000000000000 : 0; wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64(bits); return ret; } while (0); infinity: do { if (options & WUFFS_BASE__PARSE_NUMBER_FXX__REJECT_INF_AND_NAN) { wuffs_base__result_f64 ret; ret.status.repr = wuffs_base__error__bad_argument; ret.value = 0; return ret; } uint64_t bits = h->negative ? 0xFFF0000000000000 : 0x7FF0000000000000; wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64(bits); return ret; } while (0); } static inline bool // wuffs_private_impl__is_decimal_digit(uint8_t c) { return ('0' <= c) && (c <= '9'); } WUFFS_BASE__MAYBE_STATIC wuffs_base__result_f64 // wuffs_base__parse_number_f64(wuffs_base__slice_u8 s, uint32_t options) { // In practice, almost all "dd.ddddE±xxx" numbers can be represented // losslessly by a uint64_t mantissa "dddddd" and an int32_t base-10 // exponent, adjusting "xxx" for the position (if present) of the decimal // separator '.' or ','. // // This (u64 man, i32 exp10) data structure is superficially similar to the // "Do It Yourself Floating Point" type from Loitsch (†), but the exponent // here is base-10, not base-2. // // If s's number fits in a (man, exp10), parse that pair with the // Eisel-Lemire algorithm. If not, or if Eisel-Lemire fails, parsing s with // the fallback algorithm is slower but comprehensive. // // † "Printing Floating-Point Numbers Quickly and Accurately with Integers" // (https://www.cs.tufts.edu/~nr/cs257/archive/florian-loitsch/printf.pdf). // Florian Loitsch is also the primary contributor to // https://github.com/google/double-conversion do { // Calculating that (man, exp10) pair needs to stay within s's bounds. // Provided that s isn't extremely long, work on a NUL-terminated copy of // s's contents. The NUL byte isn't a valid part of "±dd.ddddE±xxx". // // As the pointer p walks the contents, it's faster to repeatedly check "is // *p a valid digit" than "is p within bounds and *p a valid digit". if (s.len >= 256) { goto fallback; } uint8_t z[256]; memcpy(&z[0], s.ptr, s.len); z[s.len] = 0; const uint8_t* p = &z[0]; // Look for a leading minus sign. Technically, we could also look for an // optional plus sign, but the "script/process-json-numbers.c with -p" // benchmark is noticably slower if we do. It's optional and, in practice, // usually absent. Let the fallback catch it. bool negative = (*p == '-'); if (negative) { p++; } // After walking "dd.dddd", comparing p later with p now will produce the // number of "d"s and "."s. const uint8_t* const start_of_digits_ptr = p; // Walk the "d"s before a '.', 'E', NUL byte, etc. If it starts with '0', // it must be a single '0'. If it starts with a non-zero decimal digit, it // can be a sequence of decimal digits. // // Update the man variable during the walk. It's OK if man overflows now. // We'll detect that later. uint64_t man; if (*p == '0') { man = 0; p++; if (wuffs_private_impl__is_decimal_digit(*p)) { goto fallback; } } else if (wuffs_private_impl__is_decimal_digit(*p)) { man = ((uint8_t)(*p - '0')); p++; for (; wuffs_private_impl__is_decimal_digit(*p); p++) { man = (10 * man) + ((uint8_t)(*p - '0')); } } else { goto fallback; } // Walk the "d"s after the optional decimal separator ('.' or ','), // updating the man and exp10 variables. int32_t exp10 = 0; if (*p == ((options & WUFFS_BASE__PARSE_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.')) { p++; const uint8_t* first_after_separator_ptr = p; if (!wuffs_private_impl__is_decimal_digit(*p)) { goto fallback; } man = (10 * man) + ((uint8_t)(*p - '0')); p++; for (; wuffs_private_impl__is_decimal_digit(*p); p++) { man = (10 * man) + ((uint8_t)(*p - '0')); } exp10 = ((int32_t)(first_after_separator_ptr - p)); } // Count the number of digits: // - for an input of "314159", digit_count is 6. // - for an input of "3.14159", digit_count is 7. // // This is off-by-one if there is a decimal separator. That's OK for now. // We'll correct for that later. The "script/process-json-numbers.c with // -p" benchmark is noticably slower if we try to correct for that now. uint32_t digit_count = (uint32_t)(p - start_of_digits_ptr); // Update exp10 for the optional exponent, starting with 'E' or 'e'. if ((*p | 0x20) == 'e') { p++; int32_t exp_sign = +1; if (*p == '-') { p++; exp_sign = -1; } else if (*p == '+') { p++; } if (!wuffs_private_impl__is_decimal_digit(*p)) { goto fallback; } int32_t exp_num = ((uint8_t)(*p - '0')); p++; // The rest of the exp_num walking has a peculiar control flow but, once // again, the "script/process-json-numbers.c with -p" benchmark is // sensitive to alternative formulations. if (wuffs_private_impl__is_decimal_digit(*p)) { exp_num = (10 * exp_num) + ((uint8_t)(*p - '0')); p++; } if (wuffs_private_impl__is_decimal_digit(*p)) { exp_num = (10 * exp_num) + ((uint8_t)(*p - '0')); p++; } while (wuffs_private_impl__is_decimal_digit(*p)) { if (exp_num > 0x1000000) { goto fallback; } exp_num = (10 * exp_num) + ((uint8_t)(*p - '0')); p++; } exp10 += exp_sign * exp_num; } // The Wuffs API is that the original slice has no trailing data. It also // allows underscores, which we don't catch here but the fallback should. if (p != &z[s.len]) { goto fallback; } // Check that the uint64_t typed man variable has not overflowed, based on // digit_count. // // For reference: // - (1 << 63) is 9223372036854775808, which has 19 decimal digits. // - (1 << 64) is 18446744073709551616, which has 20 decimal digits. // - 19 nines, 9999999999999999999, is 0x8AC7230489E7FFFF, which has 64 // bits and 16 hexadecimal digits. // - 20 nines, 99999999999999999999, is 0x56BC75E2D630FFFFF, which has 67 // bits and 17 hexadecimal digits. if (digit_count > 19) { // Even if we have more than 19 pseudo-digits, it's not yet definitely an // overflow. Recall that digit_count might be off-by-one (too large) if // there's a decimal separator. It will also over-report the number of // meaningful digits if the input looks something like "0.000dddExxx". // // We adjust by the number of leading '0's and '.'s and re-compare to 19. // Once again, technically, we could skip ','s too, but that perturbs the // "script/process-json-numbers.c with -p" benchmark. const uint8_t* q = start_of_digits_ptr; for (; (*q == '0') || (*q == '.'); q++) { } digit_count -= (uint32_t)(q - start_of_digits_ptr); if (digit_count > 19) { goto fallback; } } // The wuffs_private_impl__parse_number_f64_eisel_lemire preconditions // include that exp10 is in the range [-307 ..= 288]. if ((exp10 < -307) || (288 < exp10)) { goto fallback; } // If both man and (10 ** exp10) are exactly representable by a double, we // don't need to run the Eisel-Lemire algorithm. if ((-22 <= exp10) && (exp10 <= 22) && ((man >> 53) == 0)) { double d = (double)man; if (exp10 >= 0) { d *= wuffs_private_impl__f64_powers_of_10[+exp10]; } else { d /= wuffs_private_impl__f64_powers_of_10[-exp10]; } wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = negative ? -d : +d; return ret; } // The wuffs_private_impl__parse_number_f64_eisel_lemire preconditions // include that man is non-zero. Parsing "0" should be caught by the "If // both man and (10 ** exp10)" above, but "0e99" might not. if (man == 0) { goto fallback; } // Our man and exp10 are in range. Run the Eisel-Lemire algorithm. int64_t r = wuffs_private_impl__parse_number_f64_eisel_lemire(man, exp10); if (r < 0) { goto fallback; } wuffs_base__result_f64 ret; ret.status.repr = NULL; ret.value = wuffs_base__ieee_754_bit_representation__from_u64_to_f64( ((uint64_t)r) | (((uint64_t)negative) << 63)); return ret; } while (0); fallback: do { wuffs_private_impl__high_prec_dec h; wuffs_base__status status = wuffs_private_impl__high_prec_dec__parse(&h, s, options); if (status.repr) { return wuffs_private_impl__parse_number_f64_special(s, options); } return wuffs_private_impl__high_prec_dec__to_f64(&h, options); } while (0); } // -------- static inline size_t // wuffs_private_impl__render_inf(wuffs_base__slice_u8 dst, bool neg, uint32_t options) { if (neg) { if (dst.len < 4) { return 0; } wuffs_base__poke_u32le__no_bounds_check(dst.ptr, 0x666E492D); // '-Inf'le. return 4; } if (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN) { if (dst.len < 4) { return 0; } wuffs_base__poke_u32le__no_bounds_check(dst.ptr, 0x666E492B); // '+Inf'le. return 4; } if (dst.len < 3) { return 0; } wuffs_base__poke_u24le__no_bounds_check(dst.ptr, 0x666E49); // 'Inf'le. return 3; } static inline size_t // wuffs_private_impl__render_nan(wuffs_base__slice_u8 dst) { if (dst.len < 3) { return 0; } wuffs_base__poke_u24le__no_bounds_check(dst.ptr, 0x4E614E); // 'NaN'le. return 3; } static size_t // wuffs_private_impl__high_prec_dec__render_exponent_absent( wuffs_base__slice_u8 dst, wuffs_private_impl__high_prec_dec* h, uint32_t precision, uint32_t options) { size_t n = (h->negative || (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN)) ? 1 : 0; if (h->decimal_point <= 0) { n += 1; } else { n += (size_t)(h->decimal_point); } if (precision > 0) { n += precision + 1; // +1 for the '.'. } // Don't modify dst if the formatted number won't fit. if (n > dst.len) { return 0; } // Align-left or align-right. uint8_t* ptr = (options & WUFFS_BASE__RENDER_NUMBER_XXX__ALIGN_RIGHT) ? &dst.ptr[dst.len - n] : &dst.ptr[0]; // Leading "±". if (h->negative) { *ptr++ = '-'; } else if (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN) { *ptr++ = '+'; } // Integral digits. if (h->decimal_point <= 0) { *ptr++ = '0'; } else { uint32_t m = wuffs_base__u32__min(h->num_digits, (uint32_t)(h->decimal_point)); uint32_t i = 0; for (; i < m; i++) { *ptr++ = (uint8_t)('0' | h->digits[i]); } for (; i < (uint32_t)(h->decimal_point); i++) { *ptr++ = '0'; } } // Separator and then fractional digits. if (precision > 0) { *ptr++ = (options & WUFFS_BASE__RENDER_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.'; uint32_t i = 0; for (; i < precision; i++) { uint32_t j = ((uint32_t)(h->decimal_point)) + i; *ptr++ = (uint8_t)('0' | ((j < h->num_digits) ? h->digits[j] : 0)); } } return n; } static size_t // wuffs_private_impl__high_prec_dec__render_exponent_present( wuffs_base__slice_u8 dst, wuffs_private_impl__high_prec_dec* h, uint32_t precision, uint32_t options) { int32_t exp = 0; if (h->num_digits > 0) { exp = h->decimal_point - 1; } bool negative_exp = exp < 0; if (negative_exp) { exp = -exp; } size_t n = (h->negative || (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN)) ? 4 : 3; // Mininum 3 bytes: first digit and then "e±". if (precision > 0) { n += precision + 1; // +1 for the '.'. } n += (exp < 100) ? 2 : 3; // Don't modify dst if the formatted number won't fit. if (n > dst.len) { return 0; } // Align-left or align-right. uint8_t* ptr = (options & WUFFS_BASE__RENDER_NUMBER_XXX__ALIGN_RIGHT) ? &dst.ptr[dst.len - n] : &dst.ptr[0]; // Leading "±". if (h->negative) { *ptr++ = '-'; } else if (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN) { *ptr++ = '+'; } // Integral digit. if (h->num_digits > 0) { *ptr++ = (uint8_t)('0' | h->digits[0]); } else { *ptr++ = '0'; } // Separator and then fractional digits. if (precision > 0) { *ptr++ = (options & WUFFS_BASE__RENDER_NUMBER_FXX__DECIMAL_SEPARATOR_IS_A_COMMA) ? ',' : '.'; uint32_t i = 1; uint32_t j = wuffs_base__u32__min(h->num_digits, precision + 1); for (; i < j; i++) { *ptr++ = (uint8_t)('0' | h->digits[i]); } for (; i <= precision; i++) { *ptr++ = '0'; } } // Exponent: "e±" and then 2 or 3 digits. *ptr++ = 'e'; *ptr++ = negative_exp ? '-' : '+'; if (exp < 10) { *ptr++ = '0'; *ptr++ = (uint8_t)('0' | exp); } else if (exp < 100) { *ptr++ = (uint8_t)('0' | (exp / 10)); *ptr++ = (uint8_t)('0' | (exp % 10)); } else { int32_t e = exp / 100; exp -= e * 100; *ptr++ = (uint8_t)('0' | e); *ptr++ = (uint8_t)('0' | (exp / 10)); *ptr++ = (uint8_t)('0' | (exp % 10)); } return n; } WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_f64(wuffs_base__slice_u8 dst, double x, uint32_t precision, uint32_t options) { // Decompose x (64 bits) into negativity (1 bit), base-2 exponent (11 bits // with a -1023 bias) and mantissa (52 bits). uint64_t bits = wuffs_base__ieee_754_bit_representation__from_f64_to_u64(x); bool neg = (bits >> 63) != 0; int32_t exp2 = ((int32_t)(bits >> 52)) & 0x7FF; uint64_t man = bits & 0x000FFFFFFFFFFFFFul; // Apply the exponent bias and set the implicit top bit of the mantissa, // unless x is subnormal. Also take care of Inf and NaN. if (exp2 == 0x7FF) { if (man != 0) { return wuffs_private_impl__render_nan(dst); } return wuffs_private_impl__render_inf(dst, neg, options); } else if (exp2 == 0) { exp2 = -1022; } else { exp2 -= 1023; man |= 0x0010000000000000ul; } // Ensure that precision isn't too large. if (precision > 4095) { precision = 4095; } // Convert from the (neg, exp2, man) tuple to an HPD. wuffs_private_impl__high_prec_dec h; wuffs_private_impl__high_prec_dec__assign(&h, man, neg); if (h.num_digits > 0) { wuffs_private_impl__high_prec_dec__lshift(&h, exp2 - 52); // 52 mantissa bits. } // Handle the "%e" and "%f" formats. switch (options & (WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_ABSENT | WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_PRESENT)) { case WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_ABSENT: // The "%"f" format. if (options & WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION) { wuffs_private_impl__high_prec_dec__round_just_enough(&h, exp2, man); int32_t p = ((int32_t)(h.num_digits)) - h.decimal_point; precision = ((uint32_t)(wuffs_base__i32__max(0, p))); } else { wuffs_private_impl__high_prec_dec__round_nearest( &h, ((int32_t)precision) + h.decimal_point); } return wuffs_private_impl__high_prec_dec__render_exponent_absent( dst, &h, precision, options); case WUFFS_BASE__RENDER_NUMBER_FXX__EXPONENT_PRESENT: // The "%e" format. if (options & WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION) { wuffs_private_impl__high_prec_dec__round_just_enough(&h, exp2, man); precision = (h.num_digits > 0) ? (h.num_digits - 1) : 0; } else { wuffs_private_impl__high_prec_dec__round_nearest( &h, ((int32_t)precision) + 1); } return wuffs_private_impl__high_prec_dec__render_exponent_present( dst, &h, precision, options); } // We have the "%g" format and so precision means the number of significant // digits, not the number of digits after the decimal separator. Perform // rounding and determine whether to use "%e" or "%f". int32_t e_threshold = 0; if (options & WUFFS_BASE__RENDER_NUMBER_FXX__JUST_ENOUGH_PRECISION) { wuffs_private_impl__high_prec_dec__round_just_enough(&h, exp2, man); precision = h.num_digits; e_threshold = 6; } else { if (precision == 0) { precision = 1; } wuffs_private_impl__high_prec_dec__round_nearest(&h, ((int32_t)precision)); e_threshold = ((int32_t)precision); int32_t nd = ((int32_t)(h.num_digits)); if ((e_threshold > nd) && (nd >= h.decimal_point)) { e_threshold = nd; } } // Use the "%e" format if the exponent is large. int32_t e = h.decimal_point - 1; if ((e < -4) || (e_threshold <= e)) { uint32_t p = wuffs_base__u32__min(precision, h.num_digits); return wuffs_private_impl__high_prec_dec__render_exponent_present( dst, &h, (p > 0) ? (p - 1) : 0, options); } // Use the "%f" format otherwise. int32_t p = ((int32_t)precision); if (p > h.decimal_point) { p = ((int32_t)(h.num_digits)); } precision = ((uint32_t)(wuffs_base__i32__max(0, p - h.decimal_point))); return wuffs_private_impl__high_prec_dec__render_exponent_absent( dst, &h, precision, options); } #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__FLOATCONV) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__INTCONV) // ---------------- Integer // wuffs_base__parse_number__foo_digits entries are 0x00 for invalid digits, // and (0x80 | v) for valid digits, where v is the 4 bit value. static const uint8_t wuffs_base__parse_number__decimal_digits[256] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x00 ..= 0x07. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x08 ..= 0x0F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x10 ..= 0x17. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x18 ..= 0x1F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x20 ..= 0x27. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x28 ..= 0x2F. 0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, // 0x30 ..= 0x37. '0'-'7'. 0x88, 0x89, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x38 ..= 0x3F. '8'-'9'. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x40 ..= 0x47. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x48 ..= 0x4F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x50 ..= 0x57. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x58 ..= 0x5F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x60 ..= 0x67. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x68 ..= 0x6F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x70 ..= 0x77. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x78 ..= 0x7F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x80 ..= 0x87. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x88 ..= 0x8F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x90 ..= 0x97. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x98 ..= 0x9F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xA0 ..= 0xA7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xA8 ..= 0xAF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xB0 ..= 0xB7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xB8 ..= 0xBF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xC0 ..= 0xC7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xC8 ..= 0xCF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xD0 ..= 0xD7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xD8 ..= 0xDF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xE0 ..= 0xE7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xE8 ..= 0xEF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xF0 ..= 0xF7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xF8 ..= 0xFF. // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F }; static const uint8_t wuffs_base__parse_number__hexadecimal_digits[256] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x00 ..= 0x07. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x08 ..= 0x0F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x10 ..= 0x17. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x18 ..= 0x1F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x20 ..= 0x27. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x28 ..= 0x2F. 0x80, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87, // 0x30 ..= 0x37. '0'-'7'. 0x88, 0x89, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x38 ..= 0x3F. '8'-'9'. 0x00, 0x8A, 0x8B, 0x8C, 0x8D, 0x8E, 0x8F, 0x00, // 0x40 ..= 0x47. 'A'-'F'. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x48 ..= 0x4F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x50 ..= 0x57. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x58 ..= 0x5F. 0x00, 0x8A, 0x8B, 0x8C, 0x8D, 0x8E, 0x8F, 0x00, // 0x60 ..= 0x67. 'a'-'f'. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x68 ..= 0x6F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x70 ..= 0x77. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x78 ..= 0x7F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x80 ..= 0x87. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x88 ..= 0x8F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x90 ..= 0x97. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x98 ..= 0x9F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xA0 ..= 0xA7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xA8 ..= 0xAF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xB0 ..= 0xB7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xB8 ..= 0xBF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xC0 ..= 0xC7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xC8 ..= 0xCF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xD0 ..= 0xD7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xD8 ..= 0xDF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xE0 ..= 0xE7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xE8 ..= 0xEF. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xF0 ..= 0xF7. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0xF8 ..= 0xFF. // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F }; static const uint8_t wuffs_private_impl__encode_base16[16] = { 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, // 0x00 ..= 0x07. 0x38, 0x39, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, // 0x08 ..= 0x0F. }; // -------- WUFFS_BASE__MAYBE_STATIC wuffs_base__result_i64 // wuffs_base__parse_number_i64(wuffs_base__slice_u8 s, uint32_t options) { uint8_t* p = s.ptr; uint8_t* q = s.ptr + s.len; if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (; (p < q) && (*p == '_'); p++) { } } bool negative = false; if (p >= q) { goto fail_bad_argument; } else if (*p == '-') { p++; negative = true; } else if (*p == '+') { p++; } do { wuffs_base__result_u64 r = wuffs_base__parse_number_u64( wuffs_base__make_slice_u8(p, (size_t)(q - p)), options); if (r.status.repr != NULL) { wuffs_base__result_i64 ret; ret.status.repr = r.status.repr; ret.value = 0; return ret; } else if (negative) { if (r.value < 0x8000000000000000) { wuffs_base__result_i64 ret; ret.status.repr = NULL; ret.value = -(int64_t)(r.value); return ret; } else if (r.value == 0x8000000000000000) { wuffs_base__result_i64 ret; ret.status.repr = NULL; ret.value = INT64_MIN; return ret; } goto fail_out_of_bounds; } else if (r.value > 0x7FFFFFFFFFFFFFFF) { goto fail_out_of_bounds; } else { wuffs_base__result_i64 ret; ret.status.repr = NULL; ret.value = +(int64_t)(r.value); return ret; } } while (0); fail_bad_argument: do { wuffs_base__result_i64 ret; ret.status.repr = wuffs_base__error__bad_argument; ret.value = 0; return ret; } while (0); fail_out_of_bounds: do { wuffs_base__result_i64 ret; ret.status.repr = wuffs_base__error__out_of_bounds; ret.value = 0; return ret; } while (0); } WUFFS_BASE__MAYBE_STATIC wuffs_base__result_u64 // wuffs_base__parse_number_u64(wuffs_base__slice_u8 s, uint32_t options) { uint8_t* p = s.ptr; uint8_t* q = s.ptr + s.len; if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (; (p < q) && (*p == '_'); p++) { } } if (p >= q) { goto fail_bad_argument; } else if (*p == '0') { p++; if (p >= q) { goto ok_zero; } if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { if (*p == '_') { p++; for (; p < q; p++) { if (*p != '_') { if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_MULTIPLE_LEADING_ZEROES) { goto decimal; } goto fail_bad_argument; } } goto ok_zero; } } if ((*p == 'x') || (*p == 'X')) { p++; if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (; (p < q) && (*p == '_'); p++) { } } if (p < q) { goto hexadecimal; } } else if ((*p == 'd') || (*p == 'D')) { p++; if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES) { for (; (p < q) && (*p == '_'); p++) { } } if (p < q) { goto decimal; } } if (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_MULTIPLE_LEADING_ZEROES) { goto decimal; } goto fail_bad_argument; } decimal: do { uint64_t v = wuffs_base__parse_number__decimal_digits[*p++]; if (v == 0) { goto fail_bad_argument; } v &= 0x0F; // UINT64_MAX is 18446744073709551615, which is ((10 * max10) + max1). const uint64_t max10 = 1844674407370955161u; const uint8_t max1 = 5; for (; p < q; p++) { if ((*p == '_') && (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { continue; } uint8_t digit = wuffs_base__parse_number__decimal_digits[*p]; if (digit == 0) { goto fail_bad_argument; } digit &= 0x0F; if ((v > max10) || ((v == max10) && (digit > max1))) { goto fail_out_of_bounds; } v = (10 * v) + ((uint64_t)(digit)); } wuffs_base__result_u64 ret; ret.status.repr = NULL; ret.value = v; return ret; } while (0); hexadecimal: do { uint64_t v = wuffs_base__parse_number__hexadecimal_digits[*p++]; if (v == 0) { goto fail_bad_argument; } v &= 0x0F; for (; p < q; p++) { if ((*p == '_') && (options & WUFFS_BASE__PARSE_NUMBER_XXX__ALLOW_UNDERSCORES)) { continue; } uint8_t digit = wuffs_base__parse_number__hexadecimal_digits[*p]; if (digit == 0) { goto fail_bad_argument; } digit &= 0x0F; if ((v >> 60) != 0) { goto fail_out_of_bounds; } v = (v << 4) | ((uint64_t)(digit)); } wuffs_base__result_u64 ret; ret.status.repr = NULL; ret.value = v; return ret; } while (0); ok_zero: do { wuffs_base__result_u64 ret; ret.status.repr = NULL; ret.value = 0; return ret; } while (0); fail_bad_argument: do { wuffs_base__result_u64 ret; ret.status.repr = wuffs_base__error__bad_argument; ret.value = 0; return ret; } while (0); fail_out_of_bounds: do { wuffs_base__result_u64 ret; ret.status.repr = wuffs_base__error__out_of_bounds; ret.value = 0; return ret; } while (0); } // -------- // wuffs_base__render_number__first_hundred contains the decimal encodings of // the first one hundred numbers [0 ..= 99]. static const uint8_t wuffs_base__render_number__first_hundred[200] = { '0', '0', '0', '1', '0', '2', '0', '3', '0', '4', // '0', '5', '0', '6', '0', '7', '0', '8', '0', '9', // '1', '0', '1', '1', '1', '2', '1', '3', '1', '4', // '1', '5', '1', '6', '1', '7', '1', '8', '1', '9', // '2', '0', '2', '1', '2', '2', '2', '3', '2', '4', // '2', '5', '2', '6', '2', '7', '2', '8', '2', '9', // '3', '0', '3', '1', '3', '2', '3', '3', '3', '4', // '3', '5', '3', '6', '3', '7', '3', '8', '3', '9', // '4', '0', '4', '1', '4', '2', '4', '3', '4', '4', // '4', '5', '4', '6', '4', '7', '4', '8', '4', '9', // '5', '0', '5', '1', '5', '2', '5', '3', '5', '4', // '5', '5', '5', '6', '5', '7', '5', '8', '5', '9', // '6', '0', '6', '1', '6', '2', '6', '3', '6', '4', // '6', '5', '6', '6', '6', '7', '6', '8', '6', '9', // '7', '0', '7', '1', '7', '2', '7', '3', '7', '4', // '7', '5', '7', '6', '7', '7', '7', '8', '7', '9', // '8', '0', '8', '1', '8', '2', '8', '3', '8', '4', // '8', '5', '8', '6', '8', '7', '8', '8', '8', '9', // '9', '0', '9', '1', '9', '2', '9', '3', '9', '4', // '9', '5', '9', '6', '9', '7', '9', '8', '9', '9', // }; static size_t // wuffs_private_impl__render_number_u64(wuffs_base__slice_u8 dst, uint64_t x, uint32_t options, bool neg) { uint8_t buf[WUFFS_BASE__U64__BYTE_LENGTH__MAX_INCL]; uint8_t* ptr = &buf[0] + sizeof(buf); while (x >= 100) { size_t index = ((size_t)((x % 100) * 2)); x /= 100; uint8_t s0 = wuffs_base__render_number__first_hundred[index + 0]; uint8_t s1 = wuffs_base__render_number__first_hundred[index + 1]; ptr -= 2; ptr[0] = s0; ptr[1] = s1; } if (x < 10) { ptr -= 1; ptr[0] = (uint8_t)('0' + x); } else { size_t index = ((size_t)(x * 2)); uint8_t s0 = wuffs_base__render_number__first_hundred[index + 0]; uint8_t s1 = wuffs_base__render_number__first_hundred[index + 1]; ptr -= 2; ptr[0] = s0; ptr[1] = s1; } if (neg) { ptr -= 1; ptr[0] = '-'; } else if (options & WUFFS_BASE__RENDER_NUMBER_XXX__LEADING_PLUS_SIGN) { ptr -= 1; ptr[0] = '+'; } size_t n = sizeof(buf) - ((size_t)(ptr - &buf[0])); if (n > dst.len) { return 0; } memcpy(dst.ptr + ((options & WUFFS_BASE__RENDER_NUMBER_XXX__ALIGN_RIGHT) ? (dst.len - n) : 0), ptr, n); return n; } WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_i64(wuffs_base__slice_u8 dst, int64_t x, uint32_t options) { uint64_t u = (uint64_t)x; bool neg = x < 0; if (neg) { u = 1 + ~u; } return wuffs_private_impl__render_number_u64(dst, u, options, neg); } WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__render_number_u64(wuffs_base__slice_u8 dst, uint64_t x, uint32_t options) { return wuffs_private_impl__render_number_u64(dst, x, options, false); } // ---------------- Base-16 WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__decode2(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { wuffs_base__transform__output o; size_t src_len2 = src.len / 2; size_t len; if (dst.len < src_len2) { len = dst.len; o.status.repr = wuffs_base__suspension__short_write; } else { len = src_len2; if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; } else if (src.len & 1) { o.status.repr = wuffs_base__error__bad_data; } else { o.status.repr = NULL; } } uint8_t* d = dst.ptr; uint8_t* s = src.ptr; size_t n = len; while (n--) { *d = (uint8_t)((wuffs_base__parse_number__hexadecimal_digits[s[0]] << 4) | (wuffs_base__parse_number__hexadecimal_digits[s[1]] & 0x0F)); d += 1; s += 2; } o.num_dst = len; o.num_src = len * 2; return o; } WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__decode4(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { wuffs_base__transform__output o; size_t src_len4 = src.len / 4; size_t len = dst.len < src_len4 ? dst.len : src_len4; if (dst.len < src_len4) { len = dst.len; o.status.repr = wuffs_base__suspension__short_write; } else { len = src_len4; if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; } else if (src.len & 1) { o.status.repr = wuffs_base__error__bad_data; } else { o.status.repr = NULL; } } uint8_t* d = dst.ptr; uint8_t* s = src.ptr; size_t n = len; while (n--) { *d = (uint8_t)((wuffs_base__parse_number__hexadecimal_digits[s[2]] << 4) | (wuffs_base__parse_number__hexadecimal_digits[s[3]] & 0x0F)); d += 1; s += 4; } o.num_dst = len; o.num_src = len * 4; return o; } WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__encode2(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { wuffs_base__transform__output o; size_t dst_len2 = dst.len / 2; size_t len; if (dst_len2 < src.len) { len = dst_len2; o.status.repr = wuffs_base__suspension__short_write; } else { len = src.len; if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; } else { o.status.repr = NULL; } } uint8_t* d = dst.ptr; uint8_t* s = src.ptr; size_t n = len; while (n--) { uint8_t c = *s; d[0] = wuffs_private_impl__encode_base16[c >> 4]; d[1] = wuffs_private_impl__encode_base16[c & 0x0F]; d += 2; s += 1; } o.num_dst = len * 2; o.num_src = len; return o; } WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_16__encode4(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { wuffs_base__transform__output o; size_t dst_len4 = dst.len / 4; size_t len; if (dst_len4 < src.len) { len = dst_len4; o.status.repr = wuffs_base__suspension__short_write; } else { len = src.len; if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; } else { o.status.repr = NULL; } } uint8_t* d = dst.ptr; uint8_t* s = src.ptr; size_t n = len; while (n--) { uint8_t c = *s; d[0] = '\\'; d[1] = 'x'; d[2] = wuffs_private_impl__encode_base16[c >> 4]; d[3] = wuffs_private_impl__encode_base16[c & 0x0F]; d += 4; s += 1; } o.num_dst = len * 4; o.num_src = len; return o; } // ---------------- Base-64 // The two base-64 alphabets, std and url, differ only in the last two codes. // - std: "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/" // - url: "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-_" static const uint8_t wuffs_base__base_64__decode_std[256] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x00 ..= 0x07. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x08 ..= 0x0F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x10 ..= 0x17. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x18 ..= 0x1F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x20 ..= 0x27. 0x80, 0x80, 0x80, 0x3E, 0x80, 0x80, 0x80, 0x3F, // 0x28 ..= 0x2F. 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x3A, 0x3B, // 0x30 ..= 0x37. 0x3C, 0x3D, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x38 ..= 0x3F. 0x80, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, // 0x40 ..= 0x47. 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, // 0x48 ..= 0x4F. 0x0F, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, // 0x50 ..= 0x57. 0x17, 0x18, 0x19, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x58 ..= 0x5F. 0x80, 0x1A, 0x1B, 0x1C, 0x1D, 0x1E, 0x1F, 0x20, // 0x60 ..= 0x67. 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, // 0x68 ..= 0x6F. 0x29, 0x2A, 0x2B, 0x2C, 0x2D, 0x2E, 0x2F, 0x30, // 0x70 ..= 0x77. 0x31, 0x32, 0x33, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x78 ..= 0x7F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x80 ..= 0x87. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x88 ..= 0x8F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x90 ..= 0x97. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x98 ..= 0x9F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xA0 ..= 0xA7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xA8 ..= 0xAF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xB0 ..= 0xB7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xB8 ..= 0xBF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xC0 ..= 0xC7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xC8 ..= 0xCF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xD0 ..= 0xD7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xD8 ..= 0xDF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xE0 ..= 0xE7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xE8 ..= 0xEF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xF0 ..= 0xF7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xF8 ..= 0xFF. // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F }; static const uint8_t wuffs_base__base_64__decode_url[256] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x00 ..= 0x07. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x08 ..= 0x0F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x10 ..= 0x17. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x18 ..= 0x1F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x20 ..= 0x27. 0x80, 0x80, 0x80, 0x80, 0x80, 0x3E, 0x80, 0x80, // 0x28 ..= 0x2F. 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x3A, 0x3B, // 0x30 ..= 0x37. 0x3C, 0x3D, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x38 ..= 0x3F. 0x80, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, // 0x40 ..= 0x47. 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, // 0x48 ..= 0x4F. 0x0F, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, // 0x50 ..= 0x57. 0x17, 0x18, 0x19, 0x80, 0x80, 0x80, 0x80, 0x3F, // 0x58 ..= 0x5F. 0x80, 0x1A, 0x1B, 0x1C, 0x1D, 0x1E, 0x1F, 0x20, // 0x60 ..= 0x67. 0x21, 0x22, 0x23, 0x24, 0x25, 0x26, 0x27, 0x28, // 0x68 ..= 0x6F. 0x29, 0x2A, 0x2B, 0x2C, 0x2D, 0x2E, 0x2F, 0x30, // 0x70 ..= 0x77. 0x31, 0x32, 0x33, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x78 ..= 0x7F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x80 ..= 0x87. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x88 ..= 0x8F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x90 ..= 0x97. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0x98 ..= 0x9F. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xA0 ..= 0xA7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xA8 ..= 0xAF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xB0 ..= 0xB7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xB8 ..= 0xBF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xC0 ..= 0xC7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xC8 ..= 0xCF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xD0 ..= 0xD7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xD8 ..= 0xDF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xE0 ..= 0xE7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xE8 ..= 0xEF. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xF0 ..= 0xF7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xF8 ..= 0xFF. // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F }; static const uint8_t wuffs_base__base_64__encode_std[64] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, // 0x00 ..= 0x07. 0x49, 0x4A, 0x4B, 0x4C, 0x4D, 0x4E, 0x4F, 0x50, // 0x08 ..= 0x0F. 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, // 0x10 ..= 0x17. 0x59, 0x5A, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, // 0x18 ..= 0x1F. 0x67, 0x68, 0x69, 0x6A, 0x6B, 0x6C, 0x6D, 0x6E, // 0x20 ..= 0x27. 0x6F, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76, // 0x28 ..= 0x2F. 0x77, 0x78, 0x79, 0x7A, 0x30, 0x31, 0x32, 0x33, // 0x30 ..= 0x37. 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x2B, 0x2F, // 0x38 ..= 0x3F. }; static const uint8_t wuffs_base__base_64__encode_url[64] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, // 0x00 ..= 0x07. 0x49, 0x4A, 0x4B, 0x4C, 0x4D, 0x4E, 0x4F, 0x50, // 0x08 ..= 0x0F. 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, // 0x10 ..= 0x17. 0x59, 0x5A, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, // 0x18 ..= 0x1F. 0x67, 0x68, 0x69, 0x6A, 0x6B, 0x6C, 0x6D, 0x6E, // 0x20 ..= 0x27. 0x6F, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76, // 0x28 ..= 0x2F. 0x77, 0x78, 0x79, 0x7A, 0x30, 0x31, 0x32, 0x33, // 0x30 ..= 0x37. 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x2D, 0x5F, // 0x38 ..= 0x3F. }; // -------- WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_64__decode(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { const uint8_t* alphabet = (options & WUFFS_BASE__BASE_64__URL_ALPHABET) ? wuffs_base__base_64__decode_url : wuffs_base__base_64__decode_std; wuffs_base__transform__output o; uint8_t* d_ptr = dst.ptr; size_t d_len = dst.len; const uint8_t* s_ptr = src.ptr; size_t s_len = src.len; bool pad = false; while (s_len >= 4) { uint32_t s = wuffs_base__peek_u32le__no_bounds_check(s_ptr); uint32_t s0 = alphabet[0xFF & (s >> 0)]; uint32_t s1 = alphabet[0xFF & (s >> 8)]; uint32_t s2 = alphabet[0xFF & (s >> 16)]; uint32_t s3 = alphabet[0xFF & (s >> 24)]; if (((s0 | s1 | s2 | s3) & 0xC0) != 0) { if (s_len > 4) { o.status.repr = wuffs_base__error__bad_data; goto done; } else if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; goto done; } else if ((options & WUFFS_BASE__BASE_64__DECODE_ALLOW_PADDING) && (s_ptr[3] == '=')) { pad = true; if (s_ptr[2] == '=') { goto src2; } goto src3; } o.status.repr = wuffs_base__error__bad_data; goto done; } if (d_len < 3) { o.status.repr = wuffs_base__suspension__short_write; goto done; } s_ptr += 4; s_len -= 4; s = (s0 << 18) | (s1 << 12) | (s2 << 6) | (s3 << 0); *d_ptr++ = (uint8_t)(s >> 16); *d_ptr++ = (uint8_t)(s >> 8); *d_ptr++ = (uint8_t)(s >> 0); d_len -= 3; } if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; goto done; } if (s_len == 0) { o.status.repr = NULL; goto done; } else if (s_len == 1) { o.status.repr = wuffs_base__error__bad_data; goto done; } else if (s_len == 2) { goto src2; } src3: do { uint32_t s = wuffs_base__peek_u24le__no_bounds_check(s_ptr); uint32_t s0 = alphabet[0xFF & (s >> 0)]; uint32_t s1 = alphabet[0xFF & (s >> 8)]; uint32_t s2 = alphabet[0xFF & (s >> 16)]; if ((s0 & 0xC0) || (s1 & 0xC0) || (s2 & 0xC3)) { o.status.repr = wuffs_base__error__bad_data; goto done; } if (d_len < 2) { o.status.repr = wuffs_base__suspension__short_write; goto done; } s_ptr += pad ? 4 : 3; s = (s0 << 18) | (s1 << 12) | (s2 << 6); *d_ptr++ = (uint8_t)(s >> 16); *d_ptr++ = (uint8_t)(s >> 8); o.status.repr = NULL; goto done; } while (0); src2: do { uint32_t s = wuffs_base__peek_u16le__no_bounds_check(s_ptr); uint32_t s0 = alphabet[0xFF & (s >> 0)]; uint32_t s1 = alphabet[0xFF & (s >> 8)]; if ((s0 & 0xC0) || (s1 & 0xCF)) { o.status.repr = wuffs_base__error__bad_data; goto done; } if (d_len < 1) { o.status.repr = wuffs_base__suspension__short_write; goto done; } s_ptr += pad ? 4 : 2; s = (s0 << 18) | (s1 << 12); *d_ptr++ = (uint8_t)(s >> 16); o.status.repr = NULL; goto done; } while (0); done: o.num_dst = (size_t)(d_ptr - dst.ptr); o.num_src = (size_t)(s_ptr - src.ptr); return o; } WUFFS_BASE__MAYBE_STATIC wuffs_base__transform__output // wuffs_base__base_64__encode(wuffs_base__slice_u8 dst, wuffs_base__slice_u8 src, bool src_closed, uint32_t options) { const uint8_t* alphabet = (options & WUFFS_BASE__BASE_64__URL_ALPHABET) ? wuffs_base__base_64__encode_url : wuffs_base__base_64__encode_std; wuffs_base__transform__output o; uint8_t* d_ptr = dst.ptr; size_t d_len = dst.len; const uint8_t* s_ptr = src.ptr; size_t s_len = src.len; do { while (s_len >= 3) { if (d_len < 4) { o.status.repr = wuffs_base__suspension__short_write; goto done; } uint32_t s = wuffs_base__peek_u24be__no_bounds_check(s_ptr); s_ptr += 3; s_len -= 3; *d_ptr++ = alphabet[0x3F & (s >> 18)]; *d_ptr++ = alphabet[0x3F & (s >> 12)]; *d_ptr++ = alphabet[0x3F & (s >> 6)]; *d_ptr++ = alphabet[0x3F & (s >> 0)]; d_len -= 4; } if (!src_closed) { o.status.repr = wuffs_base__suspension__short_read; goto done; } if (s_len == 2) { if (d_len < ((options & WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING) ? 4 : 3)) { o.status.repr = wuffs_base__suspension__short_write; goto done; } uint32_t s = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(s_ptr))) << 8; s_ptr += 2; *d_ptr++ = alphabet[0x3F & (s >> 18)]; *d_ptr++ = alphabet[0x3F & (s >> 12)]; *d_ptr++ = alphabet[0x3F & (s >> 6)]; if (options & WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING) { *d_ptr++ = '='; } o.status.repr = NULL; goto done; } else if (s_len == 1) { if (d_len < ((options & WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING) ? 4 : 2)) { o.status.repr = wuffs_base__suspension__short_write; goto done; } uint32_t s = ((uint32_t)(wuffs_base__peek_u8__no_bounds_check(s_ptr))) << 16; s_ptr += 1; *d_ptr++ = alphabet[0x3F & (s >> 18)]; *d_ptr++ = alphabet[0x3F & (s >> 12)]; if (options & WUFFS_BASE__BASE_64__ENCODE_EMIT_PADDING) { *d_ptr++ = '='; *d_ptr++ = '='; } o.status.repr = NULL; goto done; } else { o.status.repr = NULL; goto done; } } while (0); done: o.num_dst = (size_t)(d_ptr - dst.ptr); o.num_src = (size_t)(s_ptr - src.ptr); return o; } #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__INTCONV) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__MAGIC) // ---------------- Magic Numbers // ICO doesn't start with a magic identifier. Instead, see if the opening bytes // are plausibly ICO. // // Callers should have already verified that (prefix_data.len >= 2) and the // first two bytes are 0x00. // // See: // - https://docs.fileformat.com/image/ico/ static int32_t // wuffs_base__magic_number_guess_fourcc__maybe_ico( wuffs_base__slice_u8 prefix_data, bool prefix_closed) { // Allow-list for the Image Type field. if (prefix_data.len < 4) { return prefix_closed ? 0 : -1; } else if (prefix_data.ptr[3] != 0) { return 0; } switch (prefix_data.ptr[2]) { case 0x01: // ICO case 0x02: // CUR break; default: return 0; } // The Number Of Images should be positive. if (prefix_data.len < 6) { return prefix_closed ? 0 : -1; } else if ((prefix_data.ptr[4] == 0) && (prefix_data.ptr[5] == 0)) { return 0; } // The first ICONDIRENTRY's fourth byte should be zero. if (prefix_data.len < 10) { return prefix_closed ? 0 : -1; } else if (prefix_data.ptr[9] != 0) { return 0; } // TODO: have a separate FourCC for CUR? return 0x49434F20; // 'ICO 'be } // TGA doesn't start with a magic identifier. Instead, see if the opening bytes // are plausibly TGA. // // Callers should have already verified that (prefix_data.len >= 2) and the // second byte (prefix_data.ptr[1], the Color Map Type byte), is either 0x00 or // 0x01. // // See: // - https://docs.fileformat.com/image/tga/ // - https://www.dca.fee.unicamp.br/~martino/disciplinas/ea978/tgaffs.pdf static int32_t // wuffs_base__magic_number_guess_fourcc__maybe_tga( wuffs_base__slice_u8 prefix_data, bool prefix_closed) { // Allow-list for the Image Type field. if (prefix_data.len < 3) { return prefix_closed ? 0 : -1; } switch (prefix_data.ptr[2]) { case 0x01: case 0x02: case 0x03: case 0x09: case 0x0A: case 0x0B: break; default: // TODO: 0x20 and 0x21 are invalid, according to the spec, but are // apparently unofficial extensions. return 0; } // Allow-list for the Color Map Entry Size field (if the Color Map Type field // is non-zero) or else all the Color Map fields should be zero. if (prefix_data.len < 8) { return prefix_closed ? 0 : -1; } else if (prefix_data.ptr[1] != 0x00) { switch (prefix_data.ptr[7]) { case 0x0F: case 0x10: case 0x18: case 0x20: break; default: return 0; } } else if ((prefix_data.ptr[3] | prefix_data.ptr[4] | prefix_data.ptr[5] | prefix_data.ptr[6] | prefix_data.ptr[7]) != 0x00) { return 0; } // Allow-list for the Pixel Depth field. if (prefix_data.len < 17) { return prefix_closed ? 0 : -1; } switch (prefix_data.ptr[16]) { case 0x01: case 0x08: case 0x0F: case 0x10: case 0x18: case 0x20: break; default: return 0; } return 0x54474120; // 'TGA 'be } WUFFS_BASE__MAYBE_STATIC int32_t // wuffs_base__magic_number_guess_fourcc(wuffs_base__slice_u8 prefix_data, bool prefix_closed) { // This is similar to (but different from): // - the magic/Magdir tables under https://github.com/file/file // - the MIME Sniffing algorithm at https://mimesniff.spec.whatwg.org/ // table holds the 'magic numbers' (which are actually variable length // strings). The strings may contain NUL bytes, so the "const char* magic" // value starts with the length-minus-1 of the 'magic number'. // // Keep it sorted by magic[1], then magic[0] descending (prioritizing longer // matches) and finally by magic[2:]. When multiple entries match, the // longest one wins. // // The fourcc field might be negated, in which case there's further // specialization (see § below). static struct { int32_t fourcc; const char* magic; } table[] = { {-0x30302020, "\x01\x00\x00"}, // '00 'be {+0x475A2020, "\x02\x1F\x8B\x08"}, // GZ {+0x5A535444, "\x03\x28\xB5\x2F\xFD"}, // ZSTD {+0x425A3220, "\x02\x42\x5A\x68"}, // BZ2 {+0x424D5020, "\x01\x42\x4D"}, // BMP {+0x47494620, "\x03\x47\x49\x46\x38"}, // GIF {+0x54494646, "\x03\x49\x49\x2A\x00"}, // TIFF (little-endian) {+0x4C5A4950, "\x04\x4C\x5A\x49\x50\x01"}, // LZIP {+0x54494646, "\x03\x4D\x4D\x00\x2A"}, // TIFF (big-endian) {+0x4E50424D, "\x02\x50\x35\x0A"}, // NPBM (P5; *.pgm) {+0x4E50424D, "\x02\x50\x36\x0A"}, // NPBM (P6; *.ppm) {-0x52494646, "\x03\x52\x49\x46\x46"}, // RIFF {+0x4C5A4D41, "\x04\x5D\x00\x10\x00\x00"}, // LZMA {+0x4C5A4D41, "\x02\x5D\x00\x00"}, // LZMA {+0x4E494520, "\x02\x6E\xC3\xAF"}, // NIE {+0x514F4920, "\x03\x71\x6F\x69\x66"}, // QOI {+0x5A4C4942, "\x01\x78\x9C"}, // ZLIB {+0x504E4720, "\x03\x89\x50\x4E\x47"}, // PNG {+0x585A2020, "\x04\xFD\x37\x7A\x58\x5A"}, // XZ {+0x4A504547, "\x01\xFF\xD8"}, // JPEG }; static const size_t table_len = sizeof(table) / sizeof(table[0]); if (prefix_data.len == 0) { return prefix_closed ? 0 : -1; } uint8_t pre_first_byte = prefix_data.ptr[0]; int32_t fourcc = 0; size_t i; for (i = 0; i < table_len; i++) { uint8_t mag_first_byte = ((uint8_t)(table[i].magic[1])); if (pre_first_byte < mag_first_byte) { break; } else if (pre_first_byte > mag_first_byte) { continue; } fourcc = table[i].fourcc; uint8_t mag_remaining_len = ((uint8_t)(table[i].magic[0])); if (mag_remaining_len == 0) { goto match; } const char* mag_remaining_ptr = table[i].magic + 2; uint8_t* pre_remaining_ptr = prefix_data.ptr + 1; size_t pre_remaining_len = prefix_data.len - 1; if (pre_remaining_len < mag_remaining_len) { if (!memcmp(pre_remaining_ptr, mag_remaining_ptr, pre_remaining_len)) { return prefix_closed ? 0 : -1; } } else { if (!memcmp(pre_remaining_ptr, mag_remaining_ptr, mag_remaining_len)) { goto match; } } } if (prefix_data.len < 2) { return prefix_closed ? 0 : -1; } else if ((prefix_data.ptr[1] == 0x00) || (prefix_data.ptr[1] == 0x01)) { return wuffs_base__magic_number_guess_fourcc__maybe_tga(prefix_data, prefix_closed); } return 0; match: // Negative FourCC values (see § above) are further specialized. if (fourcc < 0) { fourcc = -fourcc; if (fourcc == 0x52494646) { // 'RIFF'be if (prefix_data.len < 12) { return prefix_closed ? 0 : -1; } uint32_t x = wuffs_base__peek_u32be__no_bounds_check(prefix_data.ptr + 8); if (x == 0x57454250) { // 'WEBP'be return 0x57454250; // 'WEBP'be } } else if (fourcc == 0x30302020) { // '00 'be // Binary data starting with multiple 0x00 NUL bytes is quite common. // Unfortunately, some file formats also don't start with a magic // identifier, so we have to use heuristics (where the order matters, the // same as /usr/bin/file's magic/Magdir tables) as best we can. Maybe // it's TGA, ICO/CUR, etc. Maybe it's something else. int32_t tga = wuffs_base__magic_number_guess_fourcc__maybe_tga( prefix_data, prefix_closed); if (tga != 0) { return tga; } int32_t ico = wuffs_base__magic_number_guess_fourcc__maybe_ico( prefix_data, prefix_closed); if (ico != 0) { return ico; } if (prefix_data.len < 4) { return prefix_closed ? 0 : -1; } else if ((prefix_data.ptr[2] != 0x00) && ((prefix_data.ptr[2] >= 0x80) || (prefix_data.ptr[3] != 0x00))) { // Roughly speaking, this could be a non-degenerate (non-0-width and // non-0-height) WBMP image. return 0x57424D50; // 'WBMP'be } return 0; } } return fourcc; } #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__MAGIC) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__PIXCONV) // ---------------- Pixel Swizzler #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_bgrw__bgr__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len); static uint64_t // wuffs_private_impl__swizzle_bgrw__rgb__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len); WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len); WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_xxxx__y__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // -------- static inline uint32_t // wuffs_private_impl__swap_u32_argb_abgr(uint32_t u) { uint32_t o = u & 0xFF00FF00ul; uint32_t r = u & 0x00FF0000ul; uint32_t b = u & 0x000000FFul; return o | (r >> 16) | (b << 16); } static inline uint64_t // wuffs_private_impl__swap_u64_argb_abgr(uint64_t u) { uint64_t o = u & 0xFFFF0000FFFF0000ull; uint64_t r = u & 0x0000FFFF00000000ull; uint64_t b = u & 0x000000000000FFFFull; return o | (r >> 32) | (b << 32); } static inline uint32_t // wuffs_private_impl__color_u64__as__color_u32__swap_u32_argb_abgr(uint64_t c) { uint32_t a = ((uint32_t)(0xFF & (c >> 56))); uint32_t r = ((uint32_t)(0xFF & (c >> 40))); uint32_t g = ((uint32_t)(0xFF & (c >> 24))); uint32_t b = ((uint32_t)(0xFF & (c >> 8))); return (a << 24) | (b << 16) | (g << 8) | (r << 0); } // -------- WUFFS_BASE__MAYBE_STATIC wuffs_base__color_u32_argb_premul // wuffs_base__pixel_buffer__color_u32_at(const wuffs_base__pixel_buffer* pb, uint32_t x, uint32_t y) { if (!pb || (x >= pb->pixcfg.private_impl.width) || (y >= pb->pixcfg.private_impl.height)) { return 0; } if (wuffs_base__pixel_format__is_planar(&pb->pixcfg.private_impl.pixfmt)) { // TODO: support planar formats. return 0; } size_t stride = pb->private_impl.planes[0].stride; const uint8_t* row = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)); switch (pb->pixcfg.private_impl.pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: return wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x))); case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: { uint8_t* palette = pb->private_impl.planes[3].ptr; return wuffs_base__peek_u32le__no_bounds_check(palette + (4 * ((size_t)row[x]))); } // Common formats above. Rarer formats below. case WUFFS_BASE__PIXEL_FORMAT__Y: return 0xFF000000 | (0x00010101 * ((uint32_t)(row[x]))); case WUFFS_BASE__PIXEL_FORMAT__Y_16LE: return 0xFF000000 | (0x00010101 * ((uint32_t)(row[(2 * x) + 1]))); case WUFFS_BASE__PIXEL_FORMAT__Y_16BE: return 0xFF000000 | (0x00010101 * ((uint32_t)(row[(2 * x) + 0]))); case WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL: return wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( (((uint32_t)(row[(2 * x) + 1])) << 24) | (((uint32_t)(row[(2 * x) + 0])) * 0x00010101)); case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: { uint8_t* palette = pb->private_impl.planes[3].ptr; return wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(palette + (4 * ((size_t)row[x])))); } case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(row + (2 * ((size_t)x)))); case WUFFS_BASE__PIXEL_FORMAT__BGR: return 0xFF000000 | wuffs_base__peek_u24le__no_bounds_check(row + (3 * ((size_t)x))); case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: return wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x)))); case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: return wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u64le__no_bounds_check(row + (8 * ((size_t)x)))); case WUFFS_BASE__PIXEL_FORMAT__BGRX: return 0xFF000000 | wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x))); case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swap_u32_argb_abgr( 0xFF000000 | wuffs_base__peek_u24le__no_bounds_check(row + (3 * ((size_t)x)))); case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: return wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x))))); case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: return wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x)))); case WUFFS_BASE__PIXEL_FORMAT__RGBX: return wuffs_private_impl__swap_u32_argb_abgr( 0xFF000000 | wuffs_base__peek_u32le__no_bounds_check(row + (4 * ((size_t)x)))); default: // TODO: support more formats. break; } return 0; } // -------- WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_buffer__set_color_u32_at( wuffs_base__pixel_buffer* pb, uint32_t x, uint32_t y, wuffs_base__color_u32_argb_premul color) { if (!pb) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if ((x >= pb->pixcfg.private_impl.width) || (y >= pb->pixcfg.private_impl.height)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if (wuffs_base__pixel_format__is_planar(&pb->pixcfg.private_impl.pixfmt)) { // TODO: support planar formats. return wuffs_base__make_status(wuffs_base__error__unsupported_option); } size_t stride = pb->private_impl.planes[0].stride; uint8_t* row = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)); switch (pb->pixcfg.private_impl.pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRX: wuffs_base__poke_u32le__no_bounds_check(row + (4 * ((size_t)x)), color); break; // Common formats above. Rarer formats below. case WUFFS_BASE__PIXEL_FORMAT__Y: wuffs_base__poke_u8__no_bounds_check( row + ((size_t)x), wuffs_base__color_u32_argb_premul__as__color_u8_gray(color)); break; case WUFFS_BASE__PIXEL_FORMAT__Y_16LE: wuffs_base__poke_u16le__no_bounds_check( row + (2 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u16_gray(color)); break; case WUFFS_BASE__PIXEL_FORMAT__Y_16BE: wuffs_base__poke_u16be__no_bounds_check( row + (2 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u16_gray(color)); break; case WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL: wuffs_base__poke_u16le__no_bounds_check( row + (2 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u16_alpha_gray_nonpremul( color)); break; case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: wuffs_base__poke_u8__no_bounds_check( row + ((size_t)x), wuffs_base__pixel_palette__closest_element( wuffs_base__pixel_buffer__palette(pb), pb->pixcfg.private_impl.pixfmt, color)); break; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: wuffs_base__poke_u16le__no_bounds_check( row + (2 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565(color)); break; case WUFFS_BASE__PIXEL_FORMAT__BGR: wuffs_base__poke_u24le__no_bounds_check(row + (3 * ((size_t)x)), color); break; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: wuffs_base__poke_u32le__no_bounds_check( row + (4 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( color)); break; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: wuffs_base__poke_u64le__no_bounds_check( row + (8 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u64_argb_nonpremul( color)); break; case WUFFS_BASE__PIXEL_FORMAT__RGB: wuffs_base__poke_u24le__no_bounds_check( row + (3 * ((size_t)x)), wuffs_private_impl__swap_u32_argb_abgr(color)); break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: wuffs_base__poke_u32le__no_bounds_check( row + (4 * ((size_t)x)), wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( wuffs_private_impl__swap_u32_argb_abgr(color))); break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBX: wuffs_base__poke_u32le__no_bounds_check( row + (4 * ((size_t)x)), wuffs_private_impl__swap_u32_argb_abgr(color)); break; default: // TODO: support more formats. return wuffs_base__make_status(wuffs_base__error__unsupported_option); } return wuffs_base__make_status(NULL); } // -------- static inline void // wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xx( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, uint16_t color) { size_t stride = pb->private_impl.planes[0].stride; uint32_t width = wuffs_base__rect_ie_u32__width(&rect); if ((stride == (2 * ((uint64_t)width))) && (rect.min_incl_x == 0)) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)rect.min_incl_y)); uint32_t height = wuffs_base__rect_ie_u32__height(&rect); size_t n; for (n = ((size_t)width) * ((size_t)height); n > 0; n--) { wuffs_base__poke_u16le__no_bounds_check(ptr, color); ptr += 2; } return; } uint32_t y; for (y = rect.min_incl_y; y < rect.max_excl_y; y++) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)) + (2 * ((size_t)rect.min_incl_x)); uint32_t n; for (n = width; n > 0; n--) { wuffs_base__poke_u16le__no_bounds_check(ptr, color); ptr += 2; } } } static inline void // wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxx( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, uint32_t color) { size_t stride = pb->private_impl.planes[0].stride; uint32_t width = wuffs_base__rect_ie_u32__width(&rect); if ((stride == (3 * ((uint64_t)width))) && (rect.min_incl_x == 0)) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)rect.min_incl_y)); uint32_t height = wuffs_base__rect_ie_u32__height(&rect); size_t n; for (n = ((size_t)width) * ((size_t)height); n > 0; n--) { wuffs_base__poke_u24le__no_bounds_check(ptr, color); ptr += 3; } return; } uint32_t y; for (y = rect.min_incl_y; y < rect.max_excl_y; y++) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)) + (3 * ((size_t)rect.min_incl_x)); uint32_t n; for (n = width; n > 0; n--) { wuffs_base__poke_u24le__no_bounds_check(ptr, color); ptr += 3; } } } static inline void // wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxx( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, uint32_t color) { size_t stride = pb->private_impl.planes[0].stride; uint32_t width = wuffs_base__rect_ie_u32__width(&rect); if ((stride == (4 * ((uint64_t)width))) && (rect.min_incl_x == 0)) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)rect.min_incl_y)); uint32_t height = wuffs_base__rect_ie_u32__height(&rect); size_t n; for (n = ((size_t)width) * ((size_t)height); n > 0; n--) { wuffs_base__poke_u32le__no_bounds_check(ptr, color); ptr += 4; } return; } uint32_t y; for (y = rect.min_incl_y; y < rect.max_excl_y; y++) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)) + (4 * ((size_t)rect.min_incl_x)); uint32_t n; for (n = width; n > 0; n--) { wuffs_base__poke_u32le__no_bounds_check(ptr, color); ptr += 4; } } } static inline void // wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxxxxxx( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, uint64_t color) { size_t stride = pb->private_impl.planes[0].stride; uint32_t width = wuffs_base__rect_ie_u32__width(&rect); if ((stride == (8 * ((uint64_t)width))) && (rect.min_incl_x == 0)) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)rect.min_incl_y)); uint32_t height = wuffs_base__rect_ie_u32__height(&rect); size_t n; for (n = ((size_t)width) * ((size_t)height); n > 0; n--) { wuffs_base__poke_u64le__no_bounds_check(ptr, color); ptr += 8; } return; } uint32_t y; for (y = rect.min_incl_y; y < rect.max_excl_y; y++) { uint8_t* ptr = pb->private_impl.planes[0].ptr + (stride * ((size_t)y)) + (8 * ((size_t)rect.min_incl_x)); uint32_t n; for (n = width; n > 0; n--) { wuffs_base__poke_u64le__no_bounds_check(ptr, color); ptr += 8; } } } WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_buffer__set_color_u32_fill_rect( wuffs_base__pixel_buffer* pb, wuffs_base__rect_ie_u32 rect, wuffs_base__color_u32_argb_premul color) { if (!pb) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } else if (wuffs_base__rect_ie_u32__is_empty(&rect)) { return wuffs_base__make_status(NULL); } wuffs_base__rect_ie_u32 bounds = wuffs_base__pixel_config__bounds(&pb->pixcfg); if (!wuffs_base__rect_ie_u32__contains_rect(&bounds, rect)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if (wuffs_base__pixel_format__is_planar(&pb->pixcfg.private_impl.pixfmt)) { // TODO: support planar formats. return wuffs_base__make_status(wuffs_base__error__unsupported_option); } switch (pb->pixcfg.private_impl.pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRX: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxx(pb, rect, color); return wuffs_base__make_status(NULL); // Common formats above. Rarer formats below. case WUFFS_BASE__PIXEL_FORMAT__BGR_565: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xx( pb, rect, wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565(color)); return wuffs_base__make_status(NULL); case WUFFS_BASE__PIXEL_FORMAT__BGR: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxx(pb, rect, color); return wuffs_base__make_status(NULL); case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxx( pb, rect, wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( color)); return wuffs_base__make_status(NULL); case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxxxxxx( pb, rect, wuffs_base__color_u32_argb_premul__as__color_u64_argb_nonpremul( color)); return wuffs_base__make_status(NULL); case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxx( pb, rect, wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( wuffs_private_impl__swap_u32_argb_abgr(color))); return wuffs_base__make_status(NULL); case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBX: wuffs_private_impl__pixel_buffer__set_color_u32_fill_rect__xxxx( pb, rect, wuffs_private_impl__swap_u32_argb_abgr(color)); return wuffs_base__make_status(NULL); } uint32_t y; for (y = rect.min_incl_y; y < rect.max_excl_y; y++) { uint32_t x; for (x = rect.min_incl_x; x < rect.max_excl_x; x++) { wuffs_base__pixel_buffer__set_color_u32_at(pb, x, y, color); } } return wuffs_base__make_status(NULL); } // -------- WUFFS_BASE__MAYBE_STATIC uint8_t // wuffs_base__pixel_palette__closest_element( wuffs_base__slice_u8 palette_slice, wuffs_base__pixel_format palette_format, wuffs_base__color_u32_argb_premul c) { size_t n = palette_slice.len / 4; if (n > (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { n = (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4); } size_t best_index = 0; uint64_t best_score = 0xFFFFFFFFFFFFFFFF; // Work in 16-bit color. uint32_t ca = 0x101 * (0xFF & (c >> 24)); uint32_t cr = 0x101 * (0xFF & (c >> 16)); uint32_t cg = 0x101 * (0xFF & (c >> 8)); uint32_t cb = 0x101 * (0xFF & (c >> 0)); switch (palette_format.repr) { case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: { bool nonpremul = palette_format.repr == WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL; size_t i; for (i = 0; i < n; i++) { // Work in 16-bit color. uint32_t pb = 0x101 * ((uint32_t)(palette_slice.ptr[(4 * i) + 0])); uint32_t pg = 0x101 * ((uint32_t)(palette_slice.ptr[(4 * i) + 1])); uint32_t pr = 0x101 * ((uint32_t)(palette_slice.ptr[(4 * i) + 2])); uint32_t pa = 0x101 * ((uint32_t)(palette_slice.ptr[(4 * i) + 3])); // Convert to premultiplied alpha. if (nonpremul && (pa != 0xFFFF)) { pb = (pb * pa) / 0xFFFF; pg = (pg * pa) / 0xFFFF; pr = (pr * pa) / 0xFFFF; } // These deltas are conceptually int32_t (signed) but after squaring, // it's equivalent to work in uint32_t (unsigned). pb -= cb; pg -= cg; pr -= cr; pa -= ca; uint64_t score = ((uint64_t)(pb * pb)) + ((uint64_t)(pg * pg)) + ((uint64_t)(pr * pr)) + ((uint64_t)(pa * pa)); if (best_score > score) { best_score = score; best_index = i; } } break; } } return (uint8_t)best_index; } // -------- static inline uint32_t // wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx( uint32_t dst_nonpremul, uint32_t src_nonpremul) { // Extract 16-bit color components. // // If the destination is transparent then SRC_OVER is equivalent to SRC: just // return src_nonpremul. This isn't just an optimization (skipping the rest // of the function's computation). It also preserves the nonpremul // distinction between e.g. transparent red and transparent blue that would // otherwise be lost by converting from nonpremul to premul and back. uint32_t da = 0x101 * (0xFF & (dst_nonpremul >> 24)); if (da == 0) { return src_nonpremul; } uint32_t dr = 0x101 * (0xFF & (dst_nonpremul >> 16)); uint32_t dg = 0x101 * (0xFF & (dst_nonpremul >> 8)); uint32_t db = 0x101 * (0xFF & (dst_nonpremul >> 0)); uint32_t sa = 0x101 * (0xFF & (src_nonpremul >> 24)); uint32_t sr = 0x101 * (0xFF & (src_nonpremul >> 16)); uint32_t sg = 0x101 * (0xFF & (src_nonpremul >> 8)); uint32_t sb = 0x101 * (0xFF & (src_nonpremul >> 0)); // Convert dst from nonpremul to premul. dr = (dr * da) / 0xFFFF; dg = (dg * da) / 0xFFFF; db = (db * da) / 0xFFFF; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert dst from premul to nonpremul. if (da != 0) { dr = (dr * 0xFFFF) / da; dg = (dg * 0xFFFF) / da; db = (db * 0xFFFF) / da; } // Convert from 16-bit color to 8-bit color. da >>= 8; dr >>= 8; dg >>= 8; db >>= 8; // Combine components. return (db << 0) | (dg << 8) | (dr << 16) | (da << 24); } static inline uint64_t // wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx( uint64_t dst_nonpremul, uint64_t src_nonpremul) { // Extract components. // // If the destination is transparent then SRC_OVER is equivalent to SRC: just // return src_nonpremul. This isn't just an optimization (skipping the rest // of the function's computation). It also preserves the nonpremul // distinction between e.g. transparent red and transparent blue that would // otherwise be lost by converting from nonpremul to premul and back. uint64_t da = 0xFFFF & (dst_nonpremul >> 48); if (da == 0) { return src_nonpremul; } uint64_t dr = 0xFFFF & (dst_nonpremul >> 32); uint64_t dg = 0xFFFF & (dst_nonpremul >> 16); uint64_t db = 0xFFFF & (dst_nonpremul >> 0); uint64_t sa = 0xFFFF & (src_nonpremul >> 48); uint64_t sr = 0xFFFF & (src_nonpremul >> 32); uint64_t sg = 0xFFFF & (src_nonpremul >> 16); uint64_t sb = 0xFFFF & (src_nonpremul >> 0); // Convert dst from nonpremul to premul. dr = (dr * da) / 0xFFFF; dg = (dg * da) / 0xFFFF; db = (db * da) / 0xFFFF; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint64_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert dst from premul to nonpremul. if (da != 0) { dr = (dr * 0xFFFF) / da; dg = (dg * 0xFFFF) / da; db = (db * 0xFFFF) / da; } // Combine components. return (db << 0) | (dg << 16) | (dr << 32) | (da << 48); } static inline uint32_t // wuffs_private_impl__composite_nonpremul_premul_u32_axxx(uint32_t dst_nonpremul, uint32_t src_premul) { // Extract 16-bit color components. uint32_t da = 0x101 * (0xFF & (dst_nonpremul >> 24)); uint32_t dr = 0x101 * (0xFF & (dst_nonpremul >> 16)); uint32_t dg = 0x101 * (0xFF & (dst_nonpremul >> 8)); uint32_t db = 0x101 * (0xFF & (dst_nonpremul >> 0)); uint32_t sa = 0x101 * (0xFF & (src_premul >> 24)); uint32_t sr = 0x101 * (0xFF & (src_premul >> 16)); uint32_t sg = 0x101 * (0xFF & (src_premul >> 8)); uint32_t sb = 0x101 * (0xFF & (src_premul >> 0)); // Convert dst from nonpremul to premul. dr = (dr * da) / 0xFFFF; dg = (dg * da) / 0xFFFF; db = (db * da) / 0xFFFF; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert dst from premul to nonpremul. if (da != 0) { dr = (dr * 0xFFFF) / da; dg = (dg * 0xFFFF) / da; db = (db * 0xFFFF) / da; } // Convert from 16-bit color to 8-bit color. da >>= 8; dr >>= 8; dg >>= 8; db >>= 8; // Combine components. return (db << 0) | (dg << 8) | (dr << 16) | (da << 24); } static inline uint64_t // wuffs_private_impl__composite_nonpremul_premul_u64_axxx(uint64_t dst_nonpremul, uint64_t src_premul) { // Extract components. uint64_t da = 0xFFFF & (dst_nonpremul >> 48); uint64_t dr = 0xFFFF & (dst_nonpremul >> 32); uint64_t dg = 0xFFFF & (dst_nonpremul >> 16); uint64_t db = 0xFFFF & (dst_nonpremul >> 0); uint64_t sa = 0xFFFF & (src_premul >> 48); uint64_t sr = 0xFFFF & (src_premul >> 32); uint64_t sg = 0xFFFF & (src_premul >> 16); uint64_t sb = 0xFFFF & (src_premul >> 0); // Convert dst from nonpremul to premul. dr = (dr * da) / 0xFFFF; dg = (dg * da) / 0xFFFF; db = (db * da) / 0xFFFF; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint64_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert dst from premul to nonpremul. if (da != 0) { dr = (dr * 0xFFFF) / da; dg = (dg * 0xFFFF) / da; db = (db * 0xFFFF) / da; } // Combine components. return (db << 0) | (dg << 16) | (dr << 32) | (da << 48); } static inline uint32_t // wuffs_private_impl__composite_premul_nonpremul_u32_axxx( uint32_t dst_premul, uint32_t src_nonpremul) { // Extract 16-bit color components. uint32_t da = 0x101 * (0xFF & (dst_premul >> 24)); uint32_t dr = 0x101 * (0xFF & (dst_premul >> 16)); uint32_t dg = 0x101 * (0xFF & (dst_premul >> 8)); uint32_t db = 0x101 * (0xFF & (dst_premul >> 0)); uint32_t sa = 0x101 * (0xFF & (src_nonpremul >> 24)); uint32_t sr = 0x101 * (0xFF & (src_nonpremul >> 16)); uint32_t sg = 0x101 * (0xFF & (src_nonpremul >> 8)); uint32_t sb = 0x101 * (0xFF & (src_nonpremul >> 0)); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 8-bit color. da >>= 8; dr >>= 8; dg >>= 8; db >>= 8; // Combine components. return (db << 0) | (dg << 8) | (dr << 16) | (da << 24); } static inline uint64_t // wuffs_private_impl__composite_premul_nonpremul_u64_axxx( uint64_t dst_premul, uint64_t src_nonpremul) { // Extract components. uint64_t da = 0xFFFF & (dst_premul >> 48); uint64_t dr = 0xFFFF & (dst_premul >> 32); uint64_t dg = 0xFFFF & (dst_premul >> 16); uint64_t db = 0xFFFF & (dst_premul >> 0); uint64_t sa = 0xFFFF & (src_nonpremul >> 48); uint64_t sr = 0xFFFF & (src_nonpremul >> 32); uint64_t sg = 0xFFFF & (src_nonpremul >> 16); uint64_t sb = 0xFFFF & (src_nonpremul >> 0); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint64_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Combine components. return (db << 0) | (dg << 16) | (dr << 32) | (da << 48); } static inline uint32_t // wuffs_private_impl__composite_premul_premul_u32_axxx(uint32_t dst_premul, uint32_t src_premul) { // Extract 16-bit color components. uint32_t da = 0x101 * (0xFF & (dst_premul >> 24)); uint32_t dr = 0x101 * (0xFF & (dst_premul >> 16)); uint32_t dg = 0x101 * (0xFF & (dst_premul >> 8)); uint32_t db = 0x101 * (0xFF & (dst_premul >> 0)); uint32_t sa = 0x101 * (0xFF & (src_premul >> 24)); uint32_t sr = 0x101 * (0xFF & (src_premul >> 16)); uint32_t sg = 0x101 * (0xFF & (src_premul >> 8)); uint32_t sb = 0x101 * (0xFF & (src_premul >> 0)); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). da = sa + ((da * ia) / 0xFFFF); dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert from 16-bit color to 8-bit color. da >>= 8; dr >>= 8; dg >>= 8; db >>= 8; // Combine components. return (db << 0) | (dg << 8) | (dr << 16) | (da << 24); } // -------- static uint64_t // wuffs_private_impl__swizzle_squash_align4_bgr_565_8888(uint8_t* dst_ptr, size_t dst_len, const uint8_t* src_ptr, size_t src_len, bool nonpremul) { size_t len = (dst_len < src_len ? dst_len : src_len) / 4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n--) { uint32_t argb = wuffs_base__peek_u32le__no_bounds_check(s); if (nonpremul) { argb = wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul(argb); } uint32_t b5 = 0x1F & (argb >> (8 - 5)); uint32_t g6 = 0x3F & (argb >> (16 - 6)); uint32_t r5 = 0x1F & (argb >> (24 - 5)); uint32_t alpha = argb & 0xFF000000; wuffs_base__poke_u32le__no_bounds_check( d, alpha | (r5 << 11) | (g6 << 5) | (b5 << 0)); s += 4; d += 4; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_swap_rgb_bgr(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t len = (dst_len < src_len ? dst_len : src_len) / 3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n--) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s2; d[1] = s1; d[2] = s0; s += 3; d += 3; } return len; } // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t len = (dst_len < src_len ? dst_len : src_len) / 4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; __m128i shuffle = _mm_set_epi8(+0x0F, +0x0C, +0x0D, +0x0E, // +0x0B, +0x08, +0x09, +0x0A, // +0x07, +0x04, +0x05, +0x06, // +0x03, +0x00, +0x01, +0x02); while (n >= 4) { __m128i x; x = _mm_lddqu_si128((const __m128i*)(const void*)s); x = _mm_shuffle_epi8(x, shuffle); _mm_storeu_si128((__m128i*)(void*)d, x); s += 4 * 4; d += 4 * 4; n -= 4; } while (n--) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; uint8_t s3 = s[3]; d[0] = s2; d[1] = s1; d[2] = s0; d[3] = s3; s += 4; d += 4; } return len; } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 static uint64_t // wuffs_private_impl__swizzle_swap_rgbx_bgrx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t len = (dst_len < src_len ? dst_len : src_len) / 4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n--) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; uint8_t s3 = s[3]; d[0] = s2; d[1] = s1; d[2] = s0; d[3] = s3; s += 4; d += 4; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_copy_1_1(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t len = (dst_len < src_len) ? dst_len : src_len; if (len > 0) { memmove(dst_ptr, src_ptr, len); } return len; } static uint64_t // wuffs_private_impl__swizzle_copy_2_2(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; if (len > 0) { memmove(dst_ptr, src_ptr, len * 2); } return len; } static uint64_t // wuffs_private_impl__swizzle_copy_3_3(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len3 = src_len / 3; size_t len = (dst_len3 < src_len3) ? dst_len3 : src_len3; if (len > 0) { memmove(dst_ptr, src_ptr, len * 3); } return len; } static uint64_t // wuffs_private_impl__swizzle_copy_4_4(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; if (len > 0) { memmove(dst_ptr, src_ptr, len * 4); } return len; } static uint64_t // wuffs_private_impl__swizzle_copy_8_8(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len8 = src_len / 8; size_t len = (dst_len8 < src_len8) ? dst_len8 : src_len8; if (len > 0) { memmove(dst_ptr, src_ptr, len * 8); } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgr(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len3 = src_len / 3; size_t len = (dst_len2 < src_len3) ? dst_len2 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t b5 = (uint32_t)(s[0] >> 3); uint32_t g6 = (uint32_t)(s[1] >> 2); uint32_t r5 = (uint32_t)(s[2] >> 3); uint32_t rgb_565 = (r5 << 11) | (g6 << 5) | (b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)rgb_565); s += 1 * 3; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgrx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t b5 = (uint32_t)(s[0] >> 3); uint32_t g6 = (uint32_t)(s[1] >> 2); uint32_t r5 = (uint32_t)(s[2] >> 3); uint32_t rgb_565 = (r5 << 11) | (g6 << 5) | (b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)rgb_565); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))))); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len8 = src_len / 8; size_t len = (dst_len2 < src_len8) ? dst_len2 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8))))); s += 1 * 8; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sr = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sb = 0x101 * ((uint32_t)s[0]); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len8 = src_len / 8; size_t len = (dst_len2 < src_len8) ? dst_len2 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 6)); uint32_t sr = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 4)); uint32_t sg = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 2)); uint32_t sb = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 0)); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 8; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_premul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__bgra_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sr = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sb = 0x101 * ((uint32_t)s[0]); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__rgb(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len3 = src_len / 3; size_t len = (dst_len2 < src_len3) ? dst_len2 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t r5 = (uint32_t)(s[0] >> 3); uint32_t g6 = (uint32_t)(s[1] >> 2); uint32_t b5 = (uint32_t)(s[2] >> 3); uint32_t rgb_565 = (r5 << 11) | (g6 << 5) | (b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)rgb_565); s += 1 * 3; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__rgba_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))))); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__rgba_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sb = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sr = 0x101 * ((uint32_t)s[0]); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__rgba_premul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))))); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__rgba_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len4 = src_len / 4; size_t len = (dst_len2 < src_len4) ? dst_len2 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sb = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sr = 0x101 * ((uint32_t)s[0]); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 4; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__y(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t len = (dst_len2 < src_len) ? dst_len2 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t y5 = (uint32_t)(s[0] >> 3); uint32_t y6 = (uint32_t)(s[0] >> 2); uint32_t rgb_565 = (y5 << 11) | (y6 << 5) | (y5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)rgb_565); s += 1 * 1; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t y5 = (uint32_t)(s[0] >> 3); uint32_t y6 = (uint32_t)(s[0] >> 2); uint32_t rgb_565 = (y5 << 11) | (y6 << 5) | (y5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)rgb_565); s += 1 * 2; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__ya_nonpremul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( s0))); s += 1 * 2; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t sa = 0x101 * ((uint32_t)s[1]); uint32_t sy = 0x101 * ((uint32_t)s[0]); // Convert from 565 color to 16-bit color. uint32_t old_rgb_565 = wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2)); uint32_t old_r5 = 0x1F & (old_rgb_565 >> 11); uint32_t dr = (0x8421 * old_r5) >> 4; uint32_t old_g6 = 0x3F & (old_rgb_565 >> 5); uint32_t dg = (0x1041 * old_g6) >> 2; uint32_t old_b5 = 0x1F & (old_rgb_565 >> 0); uint32_t db = (0x8421 * old_b5) >> 4; // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sy * sa) + (dr * ia)) / 0xFFFF; dg = ((sy * sa) + (dg * ia)) / 0xFFFF; db = ((sy * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 565 color and combine the components. uint32_t new_r5 = 0x1F & (dr >> 11); uint32_t new_g6 = 0x3F & (dg >> 10); uint32_t new_b5 = 0x1F & (db >> 11); uint32_t new_rgb_565 = (new_r5 << 11) | (new_g6 << 5) | (new_b5 << 0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)new_rgb_565); s += 1 * 2; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__index__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len2 = dst_len / 2; size_t len = (dst_len2 < src_len) ? dst_len2 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; const size_t loop_unroll_count = 4; while (n >= loop_unroll_count) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__peek_u16le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4))); wuffs_base__poke_u16le__no_bounds_check( d + (1 * 2), wuffs_base__peek_u16le__no_bounds_check( dst_palette_ptr + ((size_t)s[1] * 4))); wuffs_base__poke_u16le__no_bounds_check( d + (2 * 2), wuffs_base__peek_u16le__no_bounds_check( dst_palette_ptr + ((size_t)s[2] * 4))); wuffs_base__poke_u16le__no_bounds_check( d + (3 * 2), wuffs_base__peek_u16le__no_bounds_check( dst_palette_ptr + ((size_t)s[3] * 4))); s += loop_unroll_count * 1; d += loop_unroll_count * 2; n -= loop_unroll_count; } while (n >= 1) { wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__peek_u16le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4))); s += 1 * 1; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__index_bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len2 = dst_len / 2; size_t len = (dst_len2 < src_len) ? dst_len2 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(d + (0 * 2))); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); wuffs_base__poke_u16le__no_bounds_check( d + (0 * 2), wuffs_base__color_u32_argb_premul__as__color_u16_rgb_565( wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0))); s += 1 * 1; d += 1 * 2; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr_565__index_binary_alpha__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len2 = dst_len / 2; size_t len = (dst_len2 < src_len) ? dst_len2 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)s0); } s += 1 * 1; d += 1 * 2; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgr__bgr_565(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len2 = src_len / 2; size_t len = (dst_len3 < src_len2) ? dst_len3 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(s + (0 * 2))); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 2; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len8 = src_len / 8; size_t len = (dst_len3 < src_len8) ? dst_len3 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8))); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 8; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sr = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sb = 0x101 * ((uint32_t)s[0]); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len8 = src_len / 8; size_t len = (dst_len3 < src_len8) ? dst_len3 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 6)); uint32_t sr = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 4)); uint32_t sg = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 2)); uint32_t sb = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 0)); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 8; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_premul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s0; d[1] = s1; d[2] = s2; s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__bgra_premul__src_over(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sr = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sb = 0x101 * ((uint32_t)s[0]); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len8 = src_len / 8; size_t len = (dst_len3 < src_len8) ? dst_len3 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)))); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 8; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sb = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sr = 0x101 * ((uint32_t)s[0]); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len8 = src_len / 8; size_t len = (dst_len3 < src_len8) ? dst_len3 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 6)); uint32_t sb = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 4)); uint32_t sg = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 2)); uint32_t sr = ((uint32_t)wuffs_base__peek_u16le__no_bounds_check(s + 0)); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (nonpremul) over dst (premul). dr = ((sr * sa) + (dr * ia)) / 0xFFFF; dg = ((sg * sa) + (dg * ia)) / 0xFFFF; db = ((sb * sa) + (db * ia)) / 0xFFFF; // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 8; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_premul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s2; d[1] = s1; d[2] = s0; s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgba_premul__src_over(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { // Extract 16-bit color components. uint32_t dr = 0x101 * ((uint32_t)d[2]); uint32_t dg = 0x101 * ((uint32_t)d[1]); uint32_t db = 0x101 * ((uint32_t)d[0]); uint32_t sa = 0x101 * ((uint32_t)s[3]); uint32_t sb = 0x101 * ((uint32_t)s[2]); uint32_t sg = 0x101 * ((uint32_t)s[1]); uint32_t sr = 0x101 * ((uint32_t)s[0]); // Calculate the inverse of the src-alpha: how much of the dst to keep. uint32_t ia = 0xFFFF - sa; // Composite src (premul) over dst (premul). dr = sr + ((dr * ia) / 0xFFFF); dg = sg + ((dg * ia) / 0xFFFF); db = sb + ((db * ia) / 0xFFFF); // Convert from 16-bit color to 8-bit color. d[0] = (uint8_t)(db >> 8); d[1] = (uint8_t)(dg >> 8); d[2] = (uint8_t)(dr >> 8); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgr__rgbx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint8_t b0 = s[0]; uint8_t b1 = s[1]; uint8_t b2 = s[2]; d[0] = b2; d[1] = b1; d[2] = b0; s += 1 * 4; d += 1 * 3; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64__as__color_u32( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4))); uint64_t s0 = wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64__as__color_u32( wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul(s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_premul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__index_bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx(d0, s0)); s += 1 * 1; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__rgba_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul(s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_premul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__ya_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u32le__no_bounds_check(d + (0 * 4), s0); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx(d0, s0)); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; uint8_t s3 = s[3]; d[0] = s0; d[1] = s0; d[2] = s1; d[3] = s1; d[4] = s2; d[5] = s2; d[6] = s3; d[7] = s3; s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0)); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len8 = src_len / 8; size_t len = (dst_len8 < src_len8) ? dst_len8 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0)); s += 1 * 8; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_premul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))); wuffs_base__poke_u64le__no_bounds_check(d + (0 * 8), s0); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_premul_u64_axxx(d0, s0)); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__index_bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len8 = dst_len / 8; size_t len = (dst_len8 < src_len) ? dst_len8 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0)); s += 1 * 1; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; uint8_t s3 = s[3]; d[0] = s2; d[1] = s2; d[2] = s1; d[3] = s1; d[4] = s0; d[5] = s0; d[6] = s3; d[7] = s3; s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0)); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_premul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_base__color_u32_argb_premul__as__color_u32_argb_nonpremul( wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))))); wuffs_base__poke_u64le__no_bounds_check(d + (0 * 8), s0); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = wuffs_base__color_u32__as__color_u64( wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_premul_u64_axxx(d0, s0)); s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__ya_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len2 = src_len / 2; size_t len = (dst_len8 < src_len2) ? dst_len8 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t s0 = ((uint64_t)(s[1]) * 0x0101000000000000) | ((uint64_t)(s[0]) * 0x0000010101010101); wuffs_base__poke_u64le__no_bounds_check(d + (0 * 8), s0); s += 1 * 2; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len2 = src_len / 2; size_t len = (dst_len8 < src_len2) ? dst_len8 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__peek_u64le__no_bounds_check(d + (0 * 8)); uint64_t s0 = ((uint64_t)(s[1]) * 0x0101000000000000) | ((uint64_t)(s[0]) * 0x0000010101010101); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0)); s += 1 * 2; d += 1 * 8; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul(s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint64_t s0 = wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul(s0)); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint64_t d0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4))); uint64_t s0 = wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64__as__color_u32( wuffs_private_impl__composite_premul_nonpremul_u64_axxx(d0, s0))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__bgra_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_premul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__index_bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 1; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul(s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint64_t s0 = wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u64_argb_nonpremul__as__color_u32_argb_premul( s0))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint64_t d0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4))); uint64_t s0 = wuffs_private_impl__swap_u64_argb_abgr( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64__as__color_u32( wuffs_private_impl__composite_premul_nonpremul_u64_axxx(d0, s0))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__rgba_premul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_premul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__ya_nonpremul__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul(s0)); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgra_premul__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4)); uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgrw__bgr(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len3 = src_len / 3; size_t len = (dst_len4 < src_len3) ? dst_len4 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), 0xFF000000 | wuffs_base__peek_u24le__no_bounds_check(s + (0 * 3))); s += 1 * 3; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw__bgr_565(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(s + (0 * 2)))); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw__bgrx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), 0xFF000000 | wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); s += 1 * 4; d += 1 * 4; n -= 1; } return len; } // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_bgrw__bgr__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len3 = src_len / 3; size_t len = (dst_len4 < src_len3) ? dst_len4 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; __m128i shuffle = _mm_set_epi8(+0x00, +0x0B, +0x0A, +0x09, // +0x00, +0x08, +0x07, +0x06, // +0x00, +0x05, +0x04, +0x03, // +0x00, +0x02, +0x01, +0x00); __m128i or_ff = _mm_set_epi8(-0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00); while (n >= 6) { __m128i x; x = _mm_lddqu_si128((const __m128i*)(const void*)s); x = _mm_shuffle_epi8(x, shuffle); x = _mm_or_si128(x, or_ff); _mm_storeu_si128((__m128i*)(void*)d, x); s += 4 * 3; d += 4 * 4; n -= 4; } while (n >= 1) { uint8_t b0 = s[0]; uint8_t b1 = s[1]; uint8_t b2 = s[2]; d[0] = b0; d[1] = b1; d[2] = b2; d[3] = 0xFF; s += 1 * 3; d += 1 * 4; n -= 1; } return len; } WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_bgrw__rgb__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len3 = src_len / 3; size_t len = (dst_len4 < src_len3) ? dst_len4 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; __m128i shuffle = _mm_set_epi8(+0x00, +0x09, +0x0A, +0x0B, // +0x00, +0x06, +0x07, +0x08, // +0x00, +0x03, +0x04, +0x05, // +0x00, +0x00, +0x01, +0x02); __m128i or_ff = _mm_set_epi8(-0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00); while (n >= 6) { __m128i x; x = _mm_lddqu_si128((const __m128i*)(const void*)s); x = _mm_shuffle_epi8(x, shuffle); x = _mm_or_si128(x, or_ff); _mm_storeu_si128((__m128i*)(void*)d, x); s += 4 * 3; d += 4 * 4; n -= 4; } while (n >= 1) { uint8_t b0 = s[0]; uint8_t b1 = s[1]; uint8_t b2 = s[2]; d[0] = b2; d[1] = b1; d[2] = b0; d[3] = 0xFF; s += 1 * 3; d += 1 * 4; n -= 1; } return len; } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 static uint64_t // wuffs_private_impl__swizzle_bgrw__rgb(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len3 = src_len / 3; size_t len = (dst_len4 < src_len3) ? dst_len4 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t b0 = s[0]; uint8_t b1 = s[1]; uint8_t b2 = s[2]; d[0] = b2; d[1] = b1; d[2] = b0; d[3] = 0xFF; s += 1 * 3; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw__rgbx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len4 = src_len / 4; size_t len = (dst_len4 < src_len4) ? dst_len4 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint8_t b0 = s[0]; uint8_t b1 = s[1]; uint8_t b2 = s[2]; d[0] = b2; d[1] = b1; d[2] = b0; d[3] = 0xFF; s += 1 * 4; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_bgrw_4x16le__bgr(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len3 = src_len / 3; size_t len = (dst_len8 < src_len3) ? dst_len8 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s0; d[1] = s0; d[2] = s1; d[3] = s1; d[4] = s2; d[5] = s2; d[6] = 0xFF; d[7] = 0xFF; s += 1 * 3; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw_4x16le__bgr_565(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len2 = src_len / 2; size_t len = (dst_len8 < src_len2) ? dst_len8 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_base__color_u32__as__color_u64( wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(s + (0 * 2))))); s += 1 * 2; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw_4x16le__bgrx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len4 = src_len / 4; size_t len = (dst_len8 < src_len4) ? dst_len8 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s0; d[1] = s0; d[2] = s1; d[3] = s1; d[4] = s2; d[5] = s2; d[6] = 0xFF; d[7] = 0xFF; s += 1 * 4; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_bgrw_4x16le__rgb(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len3 = src_len / 3; size_t len = (dst_len8 < src_len3) ? dst_len8 : src_len3; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; uint8_t s2 = s[2]; d[0] = s2; d[1] = s2; d[2] = s1; d[3] = s1; d[4] = s0; d[5] = s0; d[6] = 0xFF; d[7] = 0xFF; s += 1 * 3; d += 1 * 8; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_rgb__bgr_565(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len2 = src_len / 2; size_t len = (dst_len3 < src_len2) ? dst_len3 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u24le__no_bounds_check( d + (0 * 3), wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(s + (0 * 2))))); s += 1 * 2; d += 1 * 3; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_rgba_nonpremul__bgra_nonpremul_4x16le__src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__color_u64__as__color_u32__swap_u32_argb_abgr( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8)))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_rgba_nonpremul__bgra_nonpremul_4x16le__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len8 = src_len / 8; size_t len = (dst_len4 < src_len8) ? dst_len4 : src_len8; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t d0 = wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check(d + (0 * 4))); uint64_t s0 = wuffs_private_impl__swap_u64_argb_abgr( wuffs_base__peek_u64le__no_bounds_check(s + (0 * 8))); wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__color_u64__as__color_u32( wuffs_private_impl__composite_nonpremul_nonpremul_u64_axxx(d0, s0))); s += 1 * 8; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_rgbw__bgr_565(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_private_impl__swap_u32_argb_abgr( wuffs_base__color_u16_rgb_565__as__color_u32_argb_premul( wuffs_base__peek_u16le__no_bounds_check(s + (0 * 2))))); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_xxx__index__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len3 = dst_len / 3; size_t len = (dst_len3 < src_len) ? dst_len3 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; const size_t loop_unroll_count = 4; // The comparison in the while condition is ">", not ">=", because with // ">=", the last 4-byte store could write past the end of the dst slice. // // Each 4-byte store writes one too many bytes, but a subsequent store // will overwrite that with the correct byte. There is always another // store, whether a 4-byte store in this loop or a 1-byte store in the // next loop. while (n > loop_unroll_count) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 3), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (1 * 3), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[1] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (2 * 3), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[2] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (3 * 3), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[3] * 4))); s += loop_unroll_count * 1; d += loop_unroll_count * 3; n -= loop_unroll_count; } while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); s += 1 * 1; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__index_bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len3 = dst_len / 3; size_t len = (dst_len3 < src_len) ? dst_len3 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u24le__no_bounds_check(d + (0 * 3)) | 0xFF000000; uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); wuffs_base__poke_u24le__no_bounds_check( d + (0 * 3), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 1; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__index_binary_alpha__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len3 = dst_len / 3; size_t len = (dst_len3 < src_len) ? dst_len3 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; const size_t loop_unroll_count = 4; while (n >= loop_unroll_count) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); } uint32_t s1 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[1] * 4)); if (s1) { wuffs_base__poke_u24le__no_bounds_check(d + (1 * 3), s1); } uint32_t s2 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[2] * 4)); if (s2) { wuffs_base__poke_u24le__no_bounds_check(d + (2 * 3), s2); } uint32_t s3 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[3] * 4)); if (s3) { wuffs_base__poke_u24le__no_bounds_check(d + (3 * 3), s3); } s += loop_unroll_count * 1; d += loop_unroll_count * 3; n -= loop_unroll_count; } while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u24le__no_bounds_check(d + (0 * 3), s0); } s += 1 * 1; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__xxxx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len4 = src_len / 4; size_t len = (dst_len3 < src_len4) ? dst_len3 : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { wuffs_base__poke_u24le__no_bounds_check( d + (0 * 3), wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); s += 1 * 4; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__y(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t len = (dst_len3 < src_len) ? dst_len3 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint8_t s0 = s[0]; d[0] = s0; d[1] = s0; d[2] = s0; s += 1 * 1; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len2 = src_len / 2; size_t len = (dst_len3 < src_len2) ? dst_len3 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint8_t s0 = s[0]; d[0] = s0; d[1] = s0; d[2] = s0; s += 1 * 2; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__ya_nonpremul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len2 = src_len / 2; size_t len = (dst_len3 < src_len2) ? dst_len3 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u24le__no_bounds_check( d + (0 * 3), wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul(s0)); s += 1 * 2; d += 1 * 3; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxx__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len3 = dst_len / 3; size_t src_len2 = src_len / 2; size_t len = (dst_len3 < src_len2) ? dst_len3 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; // TODO: unroll. while (n >= 1) { uint32_t d0 = wuffs_base__peek_u24le__no_bounds_check(d + (0 * 3)) | 0xFF000000; uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); wuffs_base__poke_u24le__no_bounds_check( d + (0 * 3), wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 2; d += 1 * 3; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_xxxx__index__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; const size_t loop_unroll_count = 4; while (n >= loop_unroll_count) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (1 * 4), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[1] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (2 * 4), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[2] * 4))); wuffs_base__poke_u32le__no_bounds_check( d + (3 * 4), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[3] * 4))); s += loop_unroll_count * 1; d += loop_unroll_count * 4; n -= loop_unroll_count; } while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4))); s += 1 * 1; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxxx__index_binary_alpha__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; const size_t loop_unroll_count = 4; while (n >= loop_unroll_count) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u32le__no_bounds_check(d + (0 * 4), s0); } uint32_t s1 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[1] * 4)); if (s1) { wuffs_base__poke_u32le__no_bounds_check(d + (1 * 4), s1); } uint32_t s2 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[2] * 4)); if (s2) { wuffs_base__poke_u32le__no_bounds_check(d + (2 * 4), s2); } uint32_t s3 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[3] * 4)); if (s3) { wuffs_base__poke_u32le__no_bounds_check(d + (3 * 4), s3); } s += loop_unroll_count * 1; d += loop_unroll_count * 4; n -= loop_unroll_count; } while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u32le__no_bounds_check(d + (0 * 4), s0); } s += 1 * 1; d += 1 * 4; n -= 1; } return len; } // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") static uint64_t // wuffs_private_impl__swizzle_xxxx__y__x86_sse42(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; __m128i shuffle = _mm_set_epi8(+0x03, +0x03, +0x03, +0x03, // +0x02, +0x02, +0x02, +0x02, // +0x01, +0x01, +0x01, +0x01, // +0x00, +0x00, +0x00, +0x00); __m128i or_ff = _mm_set_epi8(-0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00, // -0x01, +0x00, +0x00, +0x00); while (n >= 4) { __m128i x; x = _mm_cvtsi32_si128((int)(wuffs_base__peek_u32le__no_bounds_check(s))); x = _mm_shuffle_epi8(x, shuffle); x = _mm_or_si128(x, or_ff); _mm_storeu_si128((__m128i*)(void*)d, x); s += 4 * 1; d += 4 * 4; n -= 4; } while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), 0xFF000000 | (0x010101 * (uint32_t)s[0])); s += 1 * 1; d += 1 * 4; n -= 1; } return len; } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 static uint64_t // wuffs_private_impl__swizzle_xxxx__y(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t len = (dst_len4 < src_len) ? dst_len4 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), 0xFF000000 | (0x010101 * (uint32_t)s[0])); s += 1 * 1; d += 1 * 4; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxxx__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len4 = dst_len / 4; size_t src_len2 = src_len / 2; size_t len = (dst_len4 < src_len2) ? dst_len4 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u32le__no_bounds_check( d + (0 * 4), 0xFF000000 | (0x010101 * (uint32_t)s[0])); s += 1 * 2; d += 1 * 4; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_xxxxxxxx__index__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len8 = dst_len / 8; size_t len = (dst_len8 < src_len) ? dst_len8 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_base__color_u32__as__color_u64( wuffs_base__peek_u32le__no_bounds_check( dst_palette_ptr + ((size_t)s[0] * 4)))); s += 1 * 1; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxxxxxxx__index_binary_alpha__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { if (dst_palette_len != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return 0; } size_t dst_len8 = dst_len / 8; size_t len = (dst_len8 < src_len) ? dst_len8 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(dst_palette_ptr + ((size_t)s[0] * 4)); if (s0) { wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), wuffs_base__color_u32__as__color_u64(s0)); } s += 1 * 1; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxxxxxxx__y(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t len = (dst_len8 < src_len) ? dst_len8 : src_len; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), 0xFFFF000000000000 | (0x010101010101 * (uint64_t)s[0])); s += 1 * 1; d += 1 * 8; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_xxxxxxxx__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len8 = dst_len / 8; size_t src_len2 = src_len / 2; size_t len = (dst_len8 < src_len2) ? dst_len8 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint64_t s0 = ((uint64_t)(wuffs_base__peek_u16be__no_bounds_check(s + (0 * 2)))); wuffs_base__poke_u64le__no_bounds_check( d + (0 * 8), 0xFFFF000000000000 | (0x000100010001 * s0)); s += 1 * 2; d += 1 * 8; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_y__bgra_nonpremul__src(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t src_len4 = src_len / 4; size_t len = (dst_len < src_len4) ? dst_len : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t s0 = wuffs_base__color_u32_argb_nonpremul__as__color_u32_argb_premul( wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4))); d[0] = wuffs_base__color_u32_argb_premul__as__color_u8_gray(s0); s += 1 * 4; d += 1 * 1; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_y__bgra_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t src_len4 = src_len / 4; size_t len = (dst_len < src_len4) ? dst_len : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = 0xFF000000 | (0x00010101 * ((uint32_t)(d[0]))); uint32_t s0 = wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); d[0] = wuffs_base__color_u32_argb_premul__as__color_u8_gray( wuffs_private_impl__composite_premul_nonpremul_u32_axxx(d0, s0)); s += 1 * 4; d += 1 * 1; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_y__bgrx(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t src_len4 = src_len / 4; size_t len = (dst_len < src_len4) ? dst_len : src_len4; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t s0 = 0xFF000000 | wuffs_base__peek_u32le__no_bounds_check(s + (0 * 4)); d[0] = wuffs_base__color_u32_argb_premul__as__color_u8_gray(s0); s += 1 * 4; d += 1 * 1; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_y__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t src_len2 = src_len / 2; size_t len = (dst_len < src_len2) ? dst_len : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { d[0] = s[0]; s += 1 * 2; d += 1 * 1; n -= 1; } return len; } static uint64_t // wuffs_private_impl__swizzle_y_16le__y_16be(uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint8_t s0 = s[0]; uint8_t s1 = s[1]; d[0] = s1; d[1] = s0; s += 1 * 2; d += 1 * 2; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_ya_nonpremul__ya_nonpremul__src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, const uint8_t* src_ptr, size_t src_len) { size_t dst_len2 = dst_len / 2; size_t src_len2 = src_len / 2; size_t len = (dst_len2 < src_len2) ? dst_len2 : src_len2; uint8_t* d = dst_ptr; const uint8_t* s = src_ptr; size_t n = len; while (n >= 1) { uint32_t d0 = ((uint32_t)(d[1]) << 24) | ((uint32_t)(d[0]) * 0x010101); uint32_t s0 = ((uint32_t)(s[1]) << 24) | ((uint32_t)(s[0]) * 0x010101); uint32_t c0 = wuffs_private_impl__composite_nonpremul_nonpremul_u32_axxx(d0, s0); wuffs_base__poke_u16le__no_bounds_check(d + (0 * 2), (uint16_t)(c0 >> 16)); s += 1 * 2; d += 1 * 2; n -= 1; } return len; } // -------- static uint64_t // wuffs_private_impl__swizzle_transparent_black_src( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, uint64_t num_pixels, uint32_t dst_pixfmt_bytes_per_pixel) { uint64_t n = ((uint64_t)dst_len) / dst_pixfmt_bytes_per_pixel; if (n > num_pixels) { n = num_pixels; } memset(dst_ptr, 0, ((size_t)(n * dst_pixfmt_bytes_per_pixel))); return n; } static uint64_t // wuffs_private_impl__swizzle_transparent_black_src_over( uint8_t* dst_ptr, size_t dst_len, uint8_t* dst_palette_ptr, size_t dst_palette_len, uint64_t num_pixels, uint32_t dst_pixfmt_bytes_per_pixel) { uint64_t n = ((uint64_t)dst_len) / dst_pixfmt_bytes_per_pixel; if (n > num_pixels) { n = num_pixels; } return n; } // -------- static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__y( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: return wuffs_private_impl__swizzle_copy_1_1; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_bgr_565__y; case WUFFS_BASE__PIXEL_FORMAT__BGR: case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_xxx__y; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_xxxx__y__x86_sse42; } #endif return wuffs_private_impl__swizzle_xxxx__y; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL_4X16LE: return wuffs_private_impl__swizzle_xxxxxxxx__y; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__y_16be( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: return wuffs_private_impl__swizzle_y__y_16be; case WUFFS_BASE__PIXEL_FORMAT__Y_16LE: return wuffs_private_impl__swizzle_y_16le__y_16be; case WUFFS_BASE__PIXEL_FORMAT__Y_16BE: return wuffs_private_impl__swizzle_copy_2_2; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_bgr_565__y_16be; case WUFFS_BASE__PIXEL_FORMAT__BGR: case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_xxx__y_16be; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: return wuffs_private_impl__swizzle_xxxx__y_16be; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL_4X16LE: return wuffs_private_impl__swizzle_xxxxxxxx__y_16be; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__ya_nonpremul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_2_2; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_ya_nonpremul__ya_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__ya_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__ya_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxx__ya_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxx__ya_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__ya_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__ya_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__ya_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__ya_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__ya_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__ya_nonpremul__src_over; } return NULL; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__indexed__bgra_nonpremul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_1_1; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: if (wuffs_private_impl__swizzle_squash_align4_bgr_565_8888( dst_palette.ptr, dst_palette.len, src_palette.ptr, src_palette.len, true) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_bgr_565__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } return wuffs_private_impl__swizzle_bgr_565__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: if (wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_xxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } return wuffs_private_impl__swizzle_xxx__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxxxxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: if (wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } return wuffs_private_impl__swizzle_bgra_premul__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: if (wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_xxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: if (wuffs_private_impl__swizzle_swap_rgbx_bgrx( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_xxx__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: if (wuffs_private_impl__swizzle_swap_rgbx_bgrx( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: if (wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: if (wuffs_private_impl__swizzle_swap_rgbx_bgrx( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } return wuffs_private_impl__swizzle_bgra_premul__index_bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBX: // TODO. break; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__indexed__bgra_binary( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_1_1; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: if (wuffs_private_impl__swizzle_squash_align4_bgr_565_8888( dst_palette.ptr, dst_palette.len, src_palette.ptr, src_palette.len, false) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__index_binary_alpha__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxx__index_binary_alpha__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxxx__index_binary_alpha__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE: if (wuffs_private_impl__slice_u8__copy_from_slice(dst_palette, src_palette) != WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxxxxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxxxxxxx__index_binary_alpha__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGB: if (wuffs_private_impl__swizzle_swap_rgbx_bgrx( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxx__index_binary_alpha__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: if (wuffs_private_impl__swizzle_swap_rgbx_bgrx( dst_palette.ptr, dst_palette.len, NULL, 0, src_palette.ptr, src_palette.len) != (WUFFS_BASE__PIXEL_FORMAT__INDEXED__PALETTE_BYTE_LENGTH / 4)) { return NULL; } switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_xxxx__index__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_xxxx__index_binary_alpha__src_over; } return NULL; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgr_565( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_copy_2_2; case WUFFS_BASE__PIXEL_FORMAT__BGR: return wuffs_private_impl__swizzle_bgr__bgr_565; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: return wuffs_private_impl__swizzle_bgrw__bgr_565; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE: return wuffs_private_impl__swizzle_bgrw_4x16le__bgr_565; case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_rgb__bgr_565; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: return wuffs_private_impl__swizzle_rgbw__bgr_565; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgr( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_bgr_565__bgr; case WUFFS_BASE__PIXEL_FORMAT__BGR: return wuffs_private_impl__swizzle_copy_3_3; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_bgrw__bgr__x86_sse42; } #endif return wuffs_private_impl__swizzle_bgrw__bgr; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL_4X16LE: return wuffs_private_impl__swizzle_bgrw_4x16le__bgr; case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_swap_rgb_bgr; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_bgrw__rgb__x86_sse42; } #endif return wuffs_private_impl__swizzle_bgrw__rgb; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgra_nonpremul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_y__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_y__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_4_4; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: // TODO. break; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42; } #endif return wuffs_private_impl__swizzle_swap_rgbx_bgrx; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: // TODO. break; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgra_nonpremul_4x16le( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__bgra_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_8_8; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: // TODO. break; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_rgba_nonpremul__bgra_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_rgba_nonpremul__bgra_nonpremul_4x16le__src_over; } break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul_4x16le__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul_4x16le__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: // TODO. break; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgra_premul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_4_4; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42; } #endif return wuffs_private_impl__swizzle_swap_rgbx_bgrx; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__rgba_premul__src_over; } return NULL; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__bgrx( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: return wuffs_private_impl__swizzle_y__bgrx; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_bgr_565__bgrx; case WUFFS_BASE__PIXEL_FORMAT__BGR: return wuffs_private_impl__swizzle_xxx__xxxx; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: return wuffs_private_impl__swizzle_bgrw__bgrx; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: return wuffs_private_impl__swizzle_bgrw_4x16le__bgrx; case WUFFS_BASE__PIXEL_FORMAT__BGRX: return wuffs_private_impl__swizzle_copy_4_4; case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_bgr__rgbx; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: return wuffs_private_impl__swizzle_bgrw__rgbx; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__rgb( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: return wuffs_private_impl__swizzle_bgr_565__rgb; case WUFFS_BASE__PIXEL_FORMAT__BGR: return wuffs_private_impl__swizzle_swap_rgb_bgr; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_bgrw__rgb__x86_sse42; } #endif return wuffs_private_impl__swizzle_bgrw__rgb; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: return wuffs_private_impl__swizzle_bgrw_4x16le__rgb; case WUFFS_BASE__PIXEL_FORMAT__RGB: return wuffs_private_impl__swizzle_copy_3_3; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_bgrw__bgr__x86_sse42; } #endif return wuffs_private_impl__swizzle_bgrw__bgr; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__rgba_nonpremul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42; } #endif return wuffs_private_impl__swizzle_swap_rgbx_bgrx; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__rgba_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGRX: // TODO. break; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_4_4; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__bgra_nonpremul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__RGBX: // TODO. break; } return NULL; } static inline WUFFS_BASE__FORCE_INLINE wuffs_base__pixel_swizzler__func // wuffs_private_impl__pixel_swizzler__prepare__rgba_premul( wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { switch (dst_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr_565__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr_565__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGR: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul_4x16le__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) if (wuffs_base__cpu_arch__have_x86_sse42()) { return wuffs_private_impl__swizzle_swap_rgbx_bgrx__x86_sse42; } #endif return wuffs_private_impl__swizzle_swap_rgbx_bgrx; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__rgba_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGB: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgr__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgr__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_nonpremul__bgra_premul__src_over; } return NULL; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: return wuffs_private_impl__swizzle_copy_4_4; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: return wuffs_private_impl__swizzle_bgra_premul__bgra_premul__src_over; } return NULL; } return NULL; } // -------- WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_swizzler__prepare(wuffs_base__pixel_swizzler* p, wuffs_base__pixel_format dst_pixfmt, wuffs_base__slice_u8 dst_palette, wuffs_base__pixel_format src_pixfmt, wuffs_base__slice_u8 src_palette, wuffs_base__pixel_blend blend) { if (!p) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } p->private_impl.func = NULL; p->private_impl.transparent_black_func = NULL; p->private_impl.dst_pixfmt_bytes_per_pixel = 0; p->private_impl.src_pixfmt_bytes_per_pixel = 0; // ---- #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST) switch (dst_pixfmt.repr) { #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGR_565) case WUFFS_BASE__PIXEL_FORMAT__BGR_565: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGR) case WUFFS_BASE__PIXEL_FORMAT__BGR: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_NONPREMUL) case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_NONPREMUL_4X16LE) case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_PREMUL) case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGB) case WUFFS_BASE__PIXEL_FORMAT__RGB: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGBA_NONPREMUL) case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGBA_PREMUL) case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: break; #endif default: return wuffs_base__make_status( wuffs_base__error__disabled_by_wuffs_config_dst_pixel_format_enable_allowlist); } #endif // defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST) // ---- wuffs_base__pixel_swizzler__func func = NULL; wuffs_base__pixel_swizzler__transparent_black_func transparent_black_func = NULL; uint32_t dst_pixfmt_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&dst_pixfmt); if ((dst_pixfmt_bits_per_pixel == 0) || ((dst_pixfmt_bits_per_pixel & 7) != 0)) { return wuffs_base__make_status( wuffs_base__error__unsupported_pixel_swizzler_option); } uint32_t src_pixfmt_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&src_pixfmt); if ((src_pixfmt_bits_per_pixel == 0) || ((src_pixfmt_bits_per_pixel & 7) != 0)) { return wuffs_base__make_status( wuffs_base__error__unsupported_pixel_swizzler_option); } // TODO: support many more formats. switch (blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: transparent_black_func = wuffs_private_impl__swizzle_transparent_black_src; break; case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: transparent_black_func = wuffs_private_impl__swizzle_transparent_black_src_over; break; } switch (src_pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: func = wuffs_private_impl__pixel_swizzler__prepare__y( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__Y_16BE: func = wuffs_private_impl__pixel_swizzler__prepare__y_16be( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__ya_nonpremul( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__indexed__bgra_nonpremul( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: func = wuffs_private_impl__pixel_swizzler__prepare__indexed__bgra_binary( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGR_565: func = wuffs_private_impl__pixel_swizzler__prepare__bgr_565( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGR: func = wuffs_private_impl__pixel_swizzler__prepare__bgr( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__bgra_nonpremul( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: func = wuffs_private_impl__pixel_swizzler__prepare__bgra_nonpremul_4x16le( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__bgra_premul( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__BGRX: func = wuffs_private_impl__pixel_swizzler__prepare__bgrx( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__RGB: func = wuffs_private_impl__pixel_swizzler__prepare__rgb( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__rgba_nonpremul( p, dst_pixfmt, dst_palette, src_palette, blend); break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: func = wuffs_private_impl__pixel_swizzler__prepare__rgba_premul( p, dst_pixfmt, dst_palette, src_palette, blend); break; } p->private_impl.func = func; p->private_impl.transparent_black_func = transparent_black_func; p->private_impl.dst_pixfmt_bytes_per_pixel = dst_pixfmt_bits_per_pixel / 8; p->private_impl.src_pixfmt_bytes_per_pixel = src_pixfmt_bits_per_pixel / 8; return wuffs_base__make_status( func ? NULL : wuffs_base__error__unsupported_pixel_swizzler_option); } WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__limited_swizzle_u32_interleaved_from_reader( const wuffs_base__pixel_swizzler* p, uint32_t up_to_num_pixels, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, const uint8_t** ptr_iop_r, const uint8_t* io2_r) { if (p && p->private_impl.func) { const uint8_t* iop_r = *ptr_iop_r; uint64_t src_len = wuffs_base__u64__min( ((uint64_t)up_to_num_pixels) * ((uint64_t)p->private_impl.src_pixfmt_bytes_per_pixel), ((uint64_t)(io2_r - iop_r))); uint64_t n = (*p->private_impl.func)(dst.ptr, dst.len, dst_palette.ptr, dst_palette.len, iop_r, (size_t)src_len); *ptr_iop_r += n * p->private_impl.src_pixfmt_bytes_per_pixel; return n; } return 0; } WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_from_reader( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, const uint8_t** ptr_iop_r, const uint8_t* io2_r) { if (p && p->private_impl.func) { const uint8_t* iop_r = *ptr_iop_r; uint64_t src_len = ((uint64_t)(io2_r - iop_r)); uint64_t n = (*p->private_impl.func)(dst.ptr, dst.len, dst_palette.ptr, dst_palette.len, iop_r, (size_t)src_len); *ptr_iop_r += n * p->private_impl.src_pixfmt_bytes_per_pixel; return n; } return 0; } WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, wuffs_base__slice_u8 src) { if (p && p->private_impl.func) { return (*p->private_impl.func)(dst.ptr, dst.len, dst_palette.ptr, dst_palette.len, src.ptr, src.len); } return 0; } WUFFS_BASE__MAYBE_STATIC uint64_t // wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black( const wuffs_base__pixel_swizzler* p, wuffs_base__slice_u8 dst, wuffs_base__slice_u8 dst_palette, uint64_t num_pixels) { if (p && p->private_impl.transparent_black_func) { return (*p->private_impl.transparent_black_func)( dst.ptr, dst.len, dst_palette.ptr, dst_palette.len, num_pixels, p->private_impl.dst_pixfmt_bytes_per_pixel); } return 0; } // -------- #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static void // wuffs_private_impl__swizzle_ycc__convert_3_bgrx_x86_avx2( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2); WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static void // wuffs_private_impl__swizzle_ycc__convert_3_rgbx_x86_avx2( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2); #if defined(__GNUC__) && !defined(__clang__) // No-op. #else WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h2v2_triangle_x86_avx2( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column, bool last_column); #endif #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) // -------- static inline uint32_t // wuffs_private_impl__u32__max_of_4(uint32_t a, uint32_t b, uint32_t c, uint32_t d) { return wuffs_base__u32__max( // wuffs_base__u32__max(a, b), // wuffs_base__u32__max(c, d)); } static inline uint32_t // wuffs_private_impl__u32__min_of_5(uint32_t a, uint32_t b, uint32_t c, uint32_t d, uint32_t e) { return wuffs_base__u32__min( // wuffs_base__u32__min( // wuffs_base__u32__min(a, b), // wuffs_base__u32__min(c, d)), // e); } // -------- typedef void (*wuffs_private_impl__swizzle_ycc__convert_4_func)( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2, const uint8_t* up3); static void // wuffs_private_impl__swizzle_cmyk__convert_4_general( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2, const uint8_t* up3) { for (; x < x_end; x++) { // It's called CMYK but, but for Adobe CMYK JPEG images in practice, it's // RGBW: 0xFFu means no ink instead of full ink. Note that a double // inversion is a no-op, so inversions might be implicit in the code below. uint32_t r = ((uint32_t)(*up0++)); uint32_t g = ((uint32_t)(*up1++)); uint32_t b = ((uint32_t)(*up2++)); uint32_t w = ((uint32_t)(*up3++)); r = ((r * w) + 0x7Fu) / 0xFFu; g = ((g * w) + 0x7Fu) / 0xFFu; b = ((b * w) + 0x7Fu) / 0xFFu; wuffs_base__pixel_buffer__set_color_u32_at( dst, x, y, 0xFF000000u | (r << 16u) | (g << 8u) | (b << 0u)); } } static void // wuffs_private_impl__swizzle_ycck__convert_4_general( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2, const uint8_t* up3) { for (; x < x_end; x++) { // We invert once again: 0xFFu means no ink instead of full ink. uint32_t color = // wuffs_base__color_ycc__as__color_u32( // *up0++, *up1++, *up2++); uint32_t r = 0xFFu - (0xFFu & (color >> 16u)); uint32_t g = 0xFFu - (0xFFu & (color >> 8u)); uint32_t b = 0xFFu - (0xFFu & (color >> 0u)); uint32_t w = ((uint32_t)(*up3++)); r = ((r * w) + 0x7Fu) / 0xFFu; g = ((g * w) + 0x7Fu) / 0xFFu; b = ((b * w) + 0x7Fu) / 0xFFu; wuffs_base__pixel_buffer__set_color_u32_at( dst, x, y, 0xFF000000u | (r << 16u) | (g << 8u) | (b << 0u)); } } // -------- typedef void (*wuffs_private_impl__swizzle_ycc__convert_3_func)( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2); static void // wuffs_private_impl__swizzle_rgb__convert_3_general( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { for (; x < x_end; x++) { uint32_t color = 0xFF000000u | // (((uint32_t)(*up0++)) << 16u) | // (((uint32_t)(*up1++)) << 8u) | // (((uint32_t)(*up2++)) << 0u); wuffs_base__pixel_buffer__set_color_u32_at(dst, x, y, color); } } static void // wuffs_private_impl__swizzle_ycc__convert_3_general( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { for (; x < x_end; x++) { uint32_t color = // wuffs_base__color_ycc__as__color_u32( // *up0++, *up1++, *up2++); wuffs_base__pixel_buffer__set_color_u32_at(dst, x, y, color); } } static void // wuffs_private_impl__swizzle_ycc__convert_3_bgrx(wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { size_t dst_stride = dst->private_impl.planes[0].stride; uint8_t* dst_iter = dst->private_impl.planes[0].ptr + (dst_stride * ((size_t)y)) + (4u * ((size_t)x)); for (; x < x_end; x++) { uint32_t color = // wuffs_base__color_ycc__as__color_u32( // *up0++, *up1++, *up2++); wuffs_base__poke_u32le__no_bounds_check(dst_iter, color); dst_iter += 4u; } } static void // wuffs_private_impl__swizzle_ycc__convert_3_rgbx(wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { size_t dst_stride = dst->private_impl.planes[0].stride; uint8_t* dst_iter = dst->private_impl.planes[0].ptr + (dst_stride * ((size_t)y)) + (4u * ((size_t)x)); for (; x < x_end; x++) { uint32_t color = // wuffs_base__color_ycc__as__color_u32_abgr( // *up0++, *up1++, *up2++); wuffs_base__poke_u32le__no_bounds_check(dst_iter, color); dst_iter += 4u; } } // -------- // wuffs_private_impl__swizzle_ycc__upsample_func upsamples to a destination // slice at least 480 (YCCK) or 672 (YCC) bytes long and whose src_len // (multiplied by 1, 2, 3 or 4) is positive but no more than that. This 480 or // 672 length is just under 1/4 or 1/3 of the scratch_buffer_2k slice length. // Both (480 * 4) = 1920 and (672 * 3) = 2016 are less than 2048. // // 480 and 672 are nice round numbers because a JPEG MCU is 1, 2, 3 or 4 blocks // wide and each block is 8 pixels wide. We have: // 480 = 1 * 8 * 60, 672 = 1 * 8 * 84 // 480 = 2 * 8 * 30, 672 = 2 * 8 * 42 // 480 = 3 * 8 * 20, 672 = 3 * 8 * 28 // 480 = 4 * 8 * 15, 672 = 4 * 8 * 21 // // Box filters are equivalent to nearest neighbor upsampling. These ignore the // src_ptr_minor, h1v2_bias, first_column and last_column arguments. // // Triangle filters use a 3:1 ratio (in 1 dimension), or 9:3:3:1 (in 2 // dimensions), which is higher quality (less blocky) but also higher // computational effort. // // In theory, we could use triangle filters for any (inv_h, inv_v) combination. // In practice, matching libjpeg-turbo, we only implement it for the common // chroma subsampling ratios (YCC420, YCC422 or YCC440), corresponding to an // (inv_h, inv_v) pair of (2, 2), (2, 1) or (1, 2). typedef const uint8_t* (*wuffs_private_impl__swizzle_ycc__upsample_func)( uint8_t* dst_ptr, const uint8_t* src_ptr_major, // Nearest row. const uint8_t* src_ptr_minor, // Adjacent row, alternating above or below. size_t src_len, uint32_t h1v2_bias, bool first_column, bool last_column); static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h1vn_box( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor_ignored, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column_ignored, bool last_column_ignored) { return src_ptr_major; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h2vn_box( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor_ignored, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column_ignored, bool last_column_ignored) { uint8_t* dp = dst_ptr; const uint8_t* sp = src_ptr_major; while (src_len--) { uint8_t sv = *sp++; *dp++ = sv; *dp++ = sv; } return dst_ptr; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h3vn_box( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor_ignored, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column_ignored, bool last_column_ignored) { uint8_t* dp = dst_ptr; const uint8_t* sp = src_ptr_major; while (src_len--) { uint8_t sv = *sp++; *dp++ = sv; *dp++ = sv; *dp++ = sv; } return dst_ptr; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h4vn_box( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor_ignored, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column_ignored, bool last_column_ignored) { uint8_t* dp = dst_ptr; const uint8_t* sp = src_ptr_major; while (src_len--) { uint8_t sv = *sp++; *dp++ = sv; *dp++ = sv; *dp++ = sv; *dp++ = sv; } return dst_ptr; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h1v2_triangle( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor, size_t src_len, uint32_t h1v2_bias, bool first_column, bool last_column) { uint8_t* dp = dst_ptr; const uint8_t* sp_major = src_ptr_major; const uint8_t* sp_minor = src_ptr_minor; while (src_len--) { *dp++ = (uint8_t)(((3u * ((uint32_t)(*sp_major++))) + // (1u * ((uint32_t)(*sp_minor++))) + // h1v2_bias) >> 2u); } return dst_ptr; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h2v1_triangle( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column, bool last_column) { uint8_t* dp = dst_ptr; const uint8_t* sp = src_ptr_major; if (first_column) { src_len--; if ((src_len <= 0u) && last_column) { uint8_t sv = *sp++; *dp++ = sv; *dp++ = sv; return dst_ptr; } uint32_t svp1 = sp[+1]; uint8_t sv = *sp++; *dp++ = sv; *dp++ = (uint8_t)(((3u * (uint32_t)sv) + svp1 + 2u) >> 2u); if (src_len <= 0u) { return dst_ptr; } } if (last_column) { src_len--; } for (; src_len > 0u; src_len--) { uint32_t svm1 = sp[-1]; uint32_t svp1 = sp[+1]; uint32_t sv3 = 3u * (uint32_t)(*sp++); *dp++ = (uint8_t)((sv3 + svm1 + 1u) >> 2u); *dp++ = (uint8_t)((sv3 + svp1 + 2u) >> 2u); } if (last_column) { uint32_t svm1 = sp[-1]; uint8_t sv = *sp++; *dp++ = (uint8_t)(((3u * (uint32_t)sv) + svm1 + 1u) >> 2u); *dp++ = sv; } return dst_ptr; } static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h2v2_triangle( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column, bool last_column) { uint8_t* dp = dst_ptr; const uint8_t* sp_major = src_ptr_major; const uint8_t* sp_minor = src_ptr_minor; if (first_column) { src_len--; if ((src_len <= 0u) && last_column) { uint32_t sv = (12u * ((uint32_t)(*sp_major++))) + // (4u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + 8u) >> 4u); *dp++ = (uint8_t)((sv + 7u) >> 4u); return dst_ptr; } uint32_t sv_major_m1 = sp_major[-0]; // Clamp offset to zero. uint32_t sv_minor_m1 = sp_minor[-0]; // Clamp offset to zero. uint32_t sv_major_p1 = sp_major[+1]; uint32_t sv_minor_p1 = sp_minor[+1]; uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); if (src_len <= 0u) { return dst_ptr; } } if (last_column) { src_len--; } for (; src_len > 0u; src_len--) { uint32_t sv_major_m1 = sp_major[-1]; uint32_t sv_minor_m1 = sp_minor[-1]; uint32_t sv_major_p1 = sp_major[+1]; uint32_t sv_minor_p1 = sp_minor[+1]; uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); } if (last_column) { uint32_t sv_major_m1 = sp_major[-1]; uint32_t sv_minor_m1 = sp_minor[-1]; uint32_t sv_major_p1 = sp_major[+0]; // Clamp offset to zero. uint32_t sv_minor_p1 = sp_minor[+0]; // Clamp offset to zero. uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); } return dst_ptr; } // wuffs_private_impl__swizzle_ycc__upsample_funcs is indexed by inv_h and then // inv_v. static const wuffs_private_impl__swizzle_ycc__upsample_func wuffs_private_impl__swizzle_ycc__upsample_funcs[4][4] = { { wuffs_private_impl__swizzle_ycc__upsample_inv_h1vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h1vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h1vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h1vn_box, }, { wuffs_private_impl__swizzle_ycc__upsample_inv_h2vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h2vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h2vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h2vn_box, }, { wuffs_private_impl__swizzle_ycc__upsample_inv_h3vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h3vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h3vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h3vn_box, }, { wuffs_private_impl__swizzle_ycc__upsample_inv_h4vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h4vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h4vn_box, wuffs_private_impl__swizzle_ycc__upsample_inv_h4vn_box, }, }; static inline uint32_t // wuffs_private_impl__swizzle_has_triangle_upsampler(uint32_t inv_h, uint32_t inv_v) { if (inv_h == 1u) { return inv_v == 2u; } else if (inv_h == 2u) { return (inv_v == 1u) || (inv_v == 2u); } return false; } // -------- // All of the wuffs_private_impl__swizzle_ycc__etc functions have // preconditions. See all of the checks made in // wuffs_base__pixel_swizzler__swizzle_ycck before calling these functions. For // example, (width > 0) is a precondition, but there are many more. static void // wuffs_private_impl__swizzle_ycck__general__triangle_filter_edge_row( wuffs_base__pixel_buffer* dst, uint32_t width, uint32_t y, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, const uint8_t* src_ptr3, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t stride3, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_h3, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t inv_v3, uint32_t half_width_for_2to1, uint32_t h1v2_bias, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func upfunc0, wuffs_private_impl__swizzle_ycc__upsample_func upfunc1, wuffs_private_impl__swizzle_ycc__upsample_func upfunc2, wuffs_private_impl__swizzle_ycc__upsample_func upfunc3, wuffs_private_impl__swizzle_ycc__convert_4_func conv4func) { const uint8_t* src0 = src_ptr0 + ((y / inv_v0) * (size_t)stride0); const uint8_t* src1 = src_ptr1 + ((y / inv_v1) * (size_t)stride1); const uint8_t* src2 = src_ptr2 + ((y / inv_v2) * (size_t)stride2); const uint8_t* src3 = src_ptr3 + ((y / inv_v3) * (size_t)stride3); uint32_t total_src_len0 = 0u; uint32_t total_src_len1 = 0u; uint32_t total_src_len2 = 0u; uint32_t total_src_len3 = 0u; uint32_t x = 0u; while (x < width) { bool first_column = x == 0u; uint32_t end = x + 480u; if (end > width) { end = width; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; uint32_t src_len3 = ((end - x) + inv_h3 - 1u) / inv_h3; total_src_len0 += src_len0; total_src_len1 += src_len1; total_src_len2 += src_len2; total_src_len3 += src_len3; const uint8_t* src_ptr_x0 = src0 + (x / inv_h0); const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 480u), // src_ptr_x0, // src_ptr_x0, // src_len0, // h1v2_bias, // first_column, // (total_src_len0 >= half_width_for_2to1)); const uint8_t* src_ptr_x1 = src1 + (x / inv_h1); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 480u), // src_ptr_x1, // src_ptr_x1, // src_len1, // h1v2_bias, // first_column, // (total_src_len1 >= half_width_for_2to1)); const uint8_t* src_ptr_x2 = src2 + (x / inv_h2); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 480u), // src_ptr_x2, // src_ptr_x2, // src_len2, // h1v2_bias, // first_column, // (total_src_len2 >= half_width_for_2to1)); const uint8_t* src_ptr_x3 = src3 + (x / inv_h3); const uint8_t* up3 = (*upfunc3)( // scratch_buffer_2k_ptr + (3u * 480u), // src_ptr_x3, // src_ptr_x3, // src_len3, // h1v2_bias, // first_column, // (total_src_len3 >= half_width_for_2to1)); (*conv4func)(dst, x, end, y, up0, up1, up2, up3); x = end; } } static void // wuffs_private_impl__swizzle_ycck__general__triangle_filter( wuffs_base__pixel_buffer* dst, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, const uint8_t* src_ptr3, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t stride3, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_h3, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t inv_v3, uint32_t half_width_for_2to1, uint32_t half_height_for_2to1, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func (*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_4_func conv4func) { if ((x_min_incl != 0) || (y_min_incl != 0)) { return; } wuffs_private_impl__swizzle_ycc__upsample_func upfunc0 = (*upfuncs)[(inv_h0 - 1u) & 3u][(inv_v0 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc1 = (*upfuncs)[(inv_h1 - 1u) & 3u][(inv_v1 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc2 = (*upfuncs)[(inv_h2 - 1u) & 3u][(inv_v2 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc3 = (*upfuncs)[(inv_h3 - 1u) & 3u][(inv_v3 - 1u) & 3u]; // First row. uint32_t h1v2_bias = 1u; wuffs_private_impl__swizzle_ycck__general__triangle_filter_edge_row( dst, x_max_excl, 0u, // src_ptr0, src_ptr1, src_ptr2, src_ptr3, // stride0, stride1, stride2, stride3, // inv_h0, inv_h1, inv_h2, inv_h3, // inv_v0, inv_v1, inv_v2, inv_v3, // half_width_for_2to1, // h1v2_bias, // scratch_buffer_2k_ptr, // upfunc0, upfunc1, upfunc2, upfunc3, conv4func); h1v2_bias = 2u; // Middle rows. bool last_row = y_max_excl == 2u * half_height_for_2to1; uint32_t middle_y_max_excl = last_row ? (y_max_excl - 1u) : y_max_excl; uint32_t y; for (y = 1u; y < middle_y_max_excl; y++) { const uint8_t* src0_major = src_ptr0 + ((y / inv_v0) * (size_t)stride0); const uint8_t* src0_minor = (inv_v0 != 2u) ? src0_major : ((y & 1u) ? (src0_major + stride0) : (src0_major - stride0)); const uint8_t* src1_major = src_ptr1 + ((y / inv_v1) * (size_t)stride1); const uint8_t* src1_minor = (inv_v1 != 2u) ? src1_major : ((y & 1u) ? (src1_major + stride1) : (src1_major - stride1)); const uint8_t* src2_major = src_ptr2 + ((y / inv_v2) * (size_t)stride2); const uint8_t* src2_minor = (inv_v2 != 2u) ? src2_major : ((y & 1u) ? (src2_major + stride2) : (src2_major - stride2)); const uint8_t* src3_major = src_ptr3 + ((y / inv_v3) * (size_t)stride3); const uint8_t* src3_minor = (inv_v3 != 2u) ? src3_major : ((y & 1u) ? (src3_major + stride3) : (src3_major - stride3)); uint32_t total_src_len0 = 0u; uint32_t total_src_len1 = 0u; uint32_t total_src_len2 = 0u; uint32_t total_src_len3 = 0u; uint32_t x = 0u; while (x < x_max_excl) { bool first_column = x == 0u; uint32_t end = x + 480u; if (end > x_max_excl) { end = x_max_excl; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; uint32_t src_len3 = ((end - x) + inv_h3 - 1u) / inv_h3; total_src_len0 += src_len0; total_src_len1 += src_len1; total_src_len2 += src_len2; total_src_len3 += src_len3; const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 480u), // src0_major + (x / inv_h0), // src0_minor + (x / inv_h0), // src_len0, // h1v2_bias, // first_column, // (total_src_len0 >= half_width_for_2to1)); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 480u), // src1_major + (x / inv_h1), // src1_minor + (x / inv_h1), // src_len1, // h1v2_bias, // first_column, // (total_src_len1 >= half_width_for_2to1)); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 480u), // src2_major + (x / inv_h2), // src2_minor + (x / inv_h2), // src_len2, // h1v2_bias, // first_column, // (total_src_len2 >= half_width_for_2to1)); const uint8_t* up3 = (*upfunc3)( // scratch_buffer_2k_ptr + (3u * 480u), // src3_major + (x / inv_h3), // src3_minor + (x / inv_h3), // src_len3, // h1v2_bias, // first_column, // (total_src_len3 >= half_width_for_2to1)); (*conv4func)(dst, x, end, y, up0, up1, up2, up3); x = end; } h1v2_bias ^= 3u; } // Last row. if (middle_y_max_excl != y_max_excl) { wuffs_private_impl__swizzle_ycck__general__triangle_filter_edge_row( dst, x_max_excl, middle_y_max_excl, // src_ptr0, src_ptr1, src_ptr2, src_ptr3, // stride0, stride1, stride2, stride3, // inv_h0, inv_h1, inv_h2, inv_h3, // inv_v0, inv_v1, inv_v2, inv_v3, // half_width_for_2to1, // h1v2_bias, // scratch_buffer_2k_ptr, // upfunc0, upfunc1, upfunc2, upfunc3, conv4func); } } static void // wuffs_private_impl__swizzle_ycc__general__triangle_filter_edge_row( wuffs_base__pixel_buffer* dst, uint32_t width, uint32_t y, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t half_width_for_2to1, uint32_t h1v2_bias, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func upfunc0, wuffs_private_impl__swizzle_ycc__upsample_func upfunc1, wuffs_private_impl__swizzle_ycc__upsample_func upfunc2, wuffs_private_impl__swizzle_ycc__convert_3_func conv3func) { const uint8_t* src0 = src_ptr0 + ((y / inv_v0) * (size_t)stride0); const uint8_t* src1 = src_ptr1 + ((y / inv_v1) * (size_t)stride1); const uint8_t* src2 = src_ptr2 + ((y / inv_v2) * (size_t)stride2); uint32_t total_src_len0 = 0u; uint32_t total_src_len1 = 0u; uint32_t total_src_len2 = 0u; uint32_t x = 0u; while (x < width) { bool first_column = x == 0u; uint32_t end = x + 672u; if (end > width) { end = width; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; total_src_len0 += src_len0; total_src_len1 += src_len1; total_src_len2 += src_len2; const uint8_t* src_ptr_x0 = src0 + (x / inv_h0); const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 672u), // src_ptr_x0, // src_ptr_x0, // src_len0, // h1v2_bias, // first_column, // (total_src_len0 >= half_width_for_2to1)); const uint8_t* src_ptr_x1 = src1 + (x / inv_h1); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 672u), // src_ptr_x1, // src_ptr_x1, // src_len1, // h1v2_bias, // first_column, // (total_src_len1 >= half_width_for_2to1)); const uint8_t* src_ptr_x2 = src2 + (x / inv_h2); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 672u), // src_ptr_x2, // src_ptr_x2, // src_len2, // h1v2_bias, // first_column, // (total_src_len2 >= half_width_for_2to1)); (*conv3func)(dst, x, end, y, up0, up1, up2); x = end; } } static void // wuffs_private_impl__swizzle_ycc__general__triangle_filter( wuffs_base__pixel_buffer* dst, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t half_width_for_2to1, uint32_t half_height_for_2to1, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func (*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_3_func conv3func) { if ((x_min_incl != 0) || (y_min_incl != 0)) { return; } wuffs_private_impl__swizzle_ycc__upsample_func upfunc0 = (*upfuncs)[(inv_h0 - 1u) & 3u][(inv_v0 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc1 = (*upfuncs)[(inv_h1 - 1u) & 3u][(inv_v1 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc2 = (*upfuncs)[(inv_h2 - 1u) & 3u][(inv_v2 - 1u) & 3u]; // First row. uint32_t h1v2_bias = 1u; wuffs_private_impl__swizzle_ycc__general__triangle_filter_edge_row( dst, x_max_excl, 0u, // src_ptr0, src_ptr1, src_ptr2, // stride0, stride1, stride2, // inv_h0, inv_h1, inv_h2, // inv_v0, inv_v1, inv_v2, // half_width_for_2to1, // h1v2_bias, // scratch_buffer_2k_ptr, // upfunc0, upfunc1, upfunc2, conv3func); h1v2_bias = 2u; // Middle rows. bool last_row = y_max_excl == 2u * half_height_for_2to1; uint32_t middle_y_max_excl = last_row ? (y_max_excl - 1u) : y_max_excl; uint32_t y; for (y = 1u; y < middle_y_max_excl; y++) { const uint8_t* src0_major = src_ptr0 + ((y / inv_v0) * (size_t)stride0); const uint8_t* src0_minor = (inv_v0 != 2u) ? src0_major : ((y & 1u) ? (src0_major + stride0) : (src0_major - stride0)); const uint8_t* src1_major = src_ptr1 + ((y / inv_v1) * (size_t)stride1); const uint8_t* src1_minor = (inv_v1 != 2u) ? src1_major : ((y & 1u) ? (src1_major + stride1) : (src1_major - stride1)); const uint8_t* src2_major = src_ptr2 + ((y / inv_v2) * (size_t)stride2); const uint8_t* src2_minor = (inv_v2 != 2u) ? src2_major : ((y & 1u) ? (src2_major + stride2) : (src2_major - stride2)); uint32_t total_src_len0 = 0u; uint32_t total_src_len1 = 0u; uint32_t total_src_len2 = 0u; uint32_t x = 0u; while (x < x_max_excl) { bool first_column = x == 0u; uint32_t end = x + 672u; if (end > x_max_excl) { end = x_max_excl; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; total_src_len0 += src_len0; total_src_len1 += src_len1; total_src_len2 += src_len2; const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 672u), // src0_major + (x / inv_h0), // src0_minor + (x / inv_h0), // src_len0, // h1v2_bias, // first_column, // (total_src_len0 >= half_width_for_2to1)); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 672u), // src1_major + (x / inv_h1), // src1_minor + (x / inv_h1), // src_len1, // h1v2_bias, // first_column, // (total_src_len1 >= half_width_for_2to1)); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 672u), // src2_major + (x / inv_h2), // src2_minor + (x / inv_h2), // src_len2, // h1v2_bias, // first_column, // (total_src_len2 >= half_width_for_2to1)); (*conv3func)(dst, x, end, y, up0, up1, up2); x = end; } h1v2_bias ^= 3u; } // Last row. if (middle_y_max_excl != y_max_excl) { wuffs_private_impl__swizzle_ycc__general__triangle_filter_edge_row( dst, x_max_excl, middle_y_max_excl, // src_ptr0, src_ptr1, src_ptr2, // stride0, stride1, stride2, // inv_h0, inv_h1, inv_h2, // inv_v0, inv_v1, inv_v2, // half_width_for_2to1, // h1v2_bias, // scratch_buffer_2k_ptr, // upfunc0, upfunc1, upfunc2, conv3func); } } static void // wuffs_private_impl__swizzle_ycc__general__box_filter( wuffs_base__pixel_buffer* dst, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t half_width_for_2to1, uint32_t half_height_for_2to1, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func (*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_3_func conv3func) { wuffs_private_impl__swizzle_ycc__upsample_func upfunc0 = (*upfuncs)[(inv_h0 - 1u) & 3u][(inv_v0 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc1 = (*upfuncs)[(inv_h1 - 1u) & 3u][(inv_v1 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc2 = (*upfuncs)[(inv_h2 - 1u) & 3u][(inv_v2 - 1u) & 3u]; uint32_t y; for (y = y_min_incl; y < y_max_excl; y++) { const uint8_t* src0_major = src_ptr0 + (((y - y_min_incl) / inv_v0) * (size_t)stride0); const uint8_t* src1_major = src_ptr1 + (((y - y_min_incl) / inv_v1) * (size_t)stride1); const uint8_t* src2_major = src_ptr2 + (((y - y_min_incl) / inv_v2) * (size_t)stride2); uint32_t x = x_min_incl; while (x < x_max_excl) { uint32_t end = x + 672u; if (end > x_max_excl) { end = x_max_excl; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 672u), // src0_major + ((x - x_min_incl) / inv_h0), // src0_major + ((x - x_min_incl) / inv_h0), // src_len0, // 0u, false, false); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 672u), // src1_major + ((x - x_min_incl) / inv_h1), // src1_major + ((x - x_min_incl) / inv_h1), // src_len1, // 0u, false, false); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 672u), // src2_major + ((x - x_min_incl) / inv_h2), // src2_major + ((x - x_min_incl) / inv_h2), // src_len2, // 0u, false, false); (*conv3func)(dst, x, end, y, up0, up1, up2); x = end; } } } static void // wuffs_private_impl__swizzle_ycck__general__box_filter( wuffs_base__pixel_buffer* dst, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, const uint8_t* src_ptr0, const uint8_t* src_ptr1, const uint8_t* src_ptr2, const uint8_t* src_ptr3, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t stride3, uint32_t inv_h0, uint32_t inv_h1, uint32_t inv_h2, uint32_t inv_h3, uint32_t inv_v0, uint32_t inv_v1, uint32_t inv_v2, uint32_t inv_v3, uint32_t half_width_for_2to1, uint32_t half_height_for_2to1, uint8_t* scratch_buffer_2k_ptr, wuffs_private_impl__swizzle_ycc__upsample_func (*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_4_func conv4func) { wuffs_private_impl__swizzle_ycc__upsample_func upfunc0 = (*upfuncs)[(inv_h0 - 1u) & 3u][(inv_v0 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc1 = (*upfuncs)[(inv_h1 - 1u) & 3u][(inv_v1 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc2 = (*upfuncs)[(inv_h2 - 1u) & 3u][(inv_v2 - 1u) & 3u]; wuffs_private_impl__swizzle_ycc__upsample_func upfunc3 = (*upfuncs)[(inv_h3 - 1u) & 3u][(inv_v3 - 1u) & 3u]; uint32_t y; for (y = y_min_incl; y < y_max_excl; y++) { const uint8_t* src0_major = src_ptr0 + (((y - y_min_incl) / inv_v0) * (size_t)stride0); const uint8_t* src1_major = src_ptr1 + (((y - y_min_incl) / inv_v1) * (size_t)stride1); const uint8_t* src2_major = src_ptr2 + (((y - y_min_incl) / inv_v2) * (size_t)stride2); const uint8_t* src3_major = src_ptr3 + (((y - y_min_incl) / inv_v3) * (size_t)stride3); uint32_t x = x_min_incl; while (x < x_max_excl) { uint32_t end = x + 480u; if (end > x_max_excl) { end = x_max_excl; } uint32_t src_len0 = ((end - x) + inv_h0 - 1u) / inv_h0; uint32_t src_len1 = ((end - x) + inv_h1 - 1u) / inv_h1; uint32_t src_len2 = ((end - x) + inv_h2 - 1u) / inv_h2; uint32_t src_len3 = ((end - x) + inv_h3 - 1u) / inv_h3; const uint8_t* up0 = (*upfunc0)( // scratch_buffer_2k_ptr + (0u * 480u), // src0_major + ((x - x_min_incl) / inv_h0), // src0_major + ((x - x_min_incl) / inv_h0), // src_len0, // 0u, false, false); const uint8_t* up1 = (*upfunc1)( // scratch_buffer_2k_ptr + (1u * 480u), // src1_major + ((x - x_min_incl) / inv_h1), // src1_major + ((x - x_min_incl) / inv_h1), // src_len1, // 0u, false, false); const uint8_t* up2 = (*upfunc2)( // scratch_buffer_2k_ptr + (2u * 480u), // src2_major + ((x - x_min_incl) / inv_h2), // src2_major + ((x - x_min_incl) / inv_h2), // src_len2, // 0u, false, false); const uint8_t* up3 = (*upfunc3)( // scratch_buffer_2k_ptr + (3u * 480u), // src3_major + ((x - x_min_incl) / inv_h3), // src3_major + ((x - x_min_incl) / inv_h3), // src_len3, // 0u, false, false); (*conv4func)(dst, x, end, y, up0, up1, up2, up3); x = end; } } } // -------- // wuffs_private_impl__swizzle_flattened_length is like // wuffs_base__table__flattened_length but returns uint64_t (not size_t) and // also accounts for subsampling. static uint64_t // wuffs_private_impl__swizzle_flattened_length(uint32_t width, uint32_t height, uint32_t stride, uint32_t inv_h, uint32_t inv_v) { uint64_t scaled_width = (((uint64_t)width) + (inv_h - 1u)) / inv_h; uint64_t scaled_height = (((uint64_t)height) + (inv_v - 1u)) / inv_v; if (scaled_height <= 0u) { return 0u; } return ((scaled_height - 1u) * stride) + scaled_width; } WUFFS_BASE__MAYBE_STATIC wuffs_base__status // wuffs_base__pixel_swizzler__swizzle_ycck( const wuffs_base__pixel_swizzler* p, wuffs_base__pixel_buffer* dst, wuffs_base__slice_u8 dst_palette, uint32_t x_min_incl, uint32_t x_max_excl, uint32_t y_min_incl, uint32_t y_max_excl, wuffs_base__slice_u8 src0, wuffs_base__slice_u8 src1, wuffs_base__slice_u8 src2, wuffs_base__slice_u8 src3, uint32_t width0, uint32_t width1, uint32_t width2, uint32_t width3, uint32_t height0, uint32_t height1, uint32_t height2, uint32_t height3, uint32_t stride0, uint32_t stride1, uint32_t stride2, uint32_t stride3, uint8_t h0, uint8_t h1, uint8_t h2, uint8_t h3, uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, bool is_rgb_or_cmyk, bool triangle_filter_for_2to1, wuffs_base__slice_u8 scratch_buffer_2k) { if (!p) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } else if (!dst || // (x_min_incl > x_max_excl) || // (x_max_excl > 0xFFFFu) || // (y_min_incl > y_max_excl) || // (y_max_excl > 0xFFFFu) || // (4u <= ((unsigned int)h0 - 1u)) || // (4u <= ((unsigned int)h1 - 1u)) || // (4u <= ((unsigned int)h2 - 1u)) || // (4u <= ((unsigned int)v0 - 1u)) || // (4u <= ((unsigned int)v1 - 1u)) || // (4u <= ((unsigned int)v2 - 1u)) || // (triangle_filter_for_2to1 && ((x_min_incl | y_min_incl) > 0u)) || (scratch_buffer_2k.len < 2048u)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((h3 != 0u) || (v3 != 0u)) { if ((4u <= ((unsigned int)h3 - 1u)) || // (4u <= ((unsigned int)v3 - 1u))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } uint32_t max_incl_h = wuffs_private_impl__u32__max_of_4(h0, h1, h2, h3); uint32_t max_incl_v = wuffs_private_impl__u32__max_of_4(v0, v1, v2, v3); // Calculate the inverse h and v ratios. // // It also canonicalizes (h=2 and max_incl_h=4) as equivalent to (h=1 and // max_incl_h=2). In both cases, the inv_h value is 2. uint32_t inv_h0 = max_incl_h / h0; uint32_t inv_h1 = max_incl_h / h1; uint32_t inv_h2 = max_incl_h / h2; uint32_t inv_h3 = h3 ? (max_incl_h / h3) : 0u; uint32_t inv_v0 = max_incl_v / v0; uint32_t inv_v1 = max_incl_v / v1; uint32_t inv_v2 = max_incl_v / v2; uint32_t inv_v3 = v3 ? (max_incl_v / v3) : 0u; if (x_min_incl != 0) { if ((x_min_incl % inv_h0) || (x_min_incl % inv_h1) || (x_min_incl % inv_h2) || (inv_h3 && (x_min_incl % inv_h3))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } if (y_min_incl != 0) { if ((y_min_incl % inv_v0) || (y_min_incl % inv_v1) || (y_min_incl % inv_v2) || (inv_v3 && (y_min_incl % inv_v3))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } uint32_t half_width_for_2to1 = ((x_max_excl - x_min_incl) + 1u) / 2u; if (inv_h0 == 2) { half_width_for_2to1 = wuffs_base__u32__min(half_width_for_2to1, width0); } if (inv_h1 == 2) { half_width_for_2to1 = wuffs_base__u32__min(half_width_for_2to1, width1); } if (inv_h2 == 2) { half_width_for_2to1 = wuffs_base__u32__min(half_width_for_2to1, width2); } if (inv_h3 == 2) { half_width_for_2to1 = wuffs_base__u32__min(half_width_for_2to1, width3); } uint32_t half_height_for_2to1 = ((y_max_excl - y_min_incl) + 1u) / 2u; if (inv_v0 == 2) { half_height_for_2to1 = wuffs_base__u32__min(half_height_for_2to1, height0); } if (inv_v1 == 2) { half_height_for_2to1 = wuffs_base__u32__min(half_height_for_2to1, height1); } if (inv_v2 == 2) { half_height_for_2to1 = wuffs_base__u32__min(half_height_for_2to1, height2); } if (inv_v3 == 2) { half_height_for_2to1 = wuffs_base__u32__min(half_height_for_2to1, height3); } x_max_excl = wuffs_base__u32__min( // wuffs_base__pixel_config__width(&dst->pixcfg), // x_min_incl + wuffs_private_impl__u32__min_of_5( // x_max_excl - x_min_incl, // width0 * inv_h0, // width1 * inv_h1, // width2 * inv_h2, // inv_h3 ? (width3 * inv_h3) : 0xFFFFFFFF)); y_max_excl = wuffs_base__u32__min( // wuffs_base__pixel_config__height(&dst->pixcfg), // y_min_incl + wuffs_private_impl__u32__min_of_5( // y_max_excl - y_min_incl, // height0 * inv_v0, // height1 * inv_v1, // height2 * inv_v2, // inv_v3 ? (height3 * inv_v3) : 0xFFFFFFFF)); if ((x_min_incl >= x_max_excl) || (y_min_incl >= y_max_excl)) { return wuffs_base__make_status(NULL); } uint32_t width = x_max_excl - x_min_incl; uint32_t height = y_max_excl - y_min_incl; if (((h0 * inv_h0) != max_incl_h) || // ((h1 * inv_h1) != max_incl_h) || // ((h2 * inv_h2) != max_incl_h) || // ((v0 * inv_v0) != max_incl_v) || // ((v1 * inv_v1) != max_incl_v) || // ((v2 * inv_v2) != max_incl_v) || // (src0.len < wuffs_private_impl__swizzle_flattened_length( width, height, stride0, inv_h0, inv_v0)) || (src1.len < wuffs_private_impl__swizzle_flattened_length( width, height, stride1, inv_h1, inv_v1)) || (src2.len < wuffs_private_impl__swizzle_flattened_length( width, height, stride2, inv_h2, inv_v2))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((h3 != 0u) || (v3 != 0u)) { if (((h3 * inv_h3) != max_incl_h) || // ((v3 * inv_v3) != max_incl_v) || // (src3.len < wuffs_private_impl__swizzle_flattened_length( width, height, stride3, inv_h3, inv_v3))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } } if (wuffs_base__pixel_format__is_planar(&dst->pixcfg.private_impl.pixfmt)) { // TODO: see wuffs_base__pixel_buffer__set_color_u32_at's TODO. return wuffs_base__make_status( wuffs_base__error__unsupported_pixel_swizzler_option); } // ---- #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST) switch (dst->pixcfg.private_impl.pixfmt.repr) { #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGR_565) case WUFFS_BASE__PIXEL_FORMAT__BGR_565: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGR) case WUFFS_BASE__PIXEL_FORMAT__BGR: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_NONPREMUL) case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_NONPREMUL_4X16LE) case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_BGRA_PREMUL) case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGB) case WUFFS_BASE__PIXEL_FORMAT__RGB: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGBA_NONPREMUL) case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: break; #endif #if defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ALLOW_RGBA_PREMUL) case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: break; #endif default: return wuffs_base__make_status( wuffs_base__error__disabled_by_wuffs_config_dst_pixel_format_enable_allowlist); } #else // defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST) switch (dst->pixcfg.private_impl.pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__Y: case WUFFS_BASE__PIXEL_FORMAT__Y_16LE: case WUFFS_BASE__PIXEL_FORMAT__Y_16BE: case WUFFS_BASE__PIXEL_FORMAT__YA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__INDEXED__BGRA_BINARY: case WUFFS_BASE__PIXEL_FORMAT__BGR_565: case WUFFS_BASE__PIXEL_FORMAT__BGR: case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRX: case WUFFS_BASE__PIXEL_FORMAT__RGB: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBX: break; default: // TODO: see wuffs_base__pixel_buffer__set_color_u32_at's TODO. return wuffs_base__make_status( wuffs_base__error__unsupported_pixel_swizzler_option); } #endif // defined(WUFFS_CONFIG__DST_PIXEL_FORMAT__ENABLE_ALLOWLIST) // ---- wuffs_private_impl__swizzle_ycc__convert_3_func conv3func = NULL; if (is_rgb_or_cmyk) { conv3func = &wuffs_private_impl__swizzle_rgb__convert_3_general; } else { switch (dst->pixcfg.private_impl.pixfmt.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) if (wuffs_base__cpu_arch__have_x86_avx2()) { conv3func = &wuffs_private_impl__swizzle_ycc__convert_3_bgrx_x86_avx2; break; } #endif conv3func = &wuffs_private_impl__swizzle_ycc__convert_3_bgrx; break; case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBX: #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) if (wuffs_base__cpu_arch__have_x86_avx2()) { conv3func = &wuffs_private_impl__swizzle_ycc__convert_3_rgbx_x86_avx2; break; } #endif conv3func = &wuffs_private_impl__swizzle_ycc__convert_3_rgbx; break; default: conv3func = &wuffs_private_impl__swizzle_ycc__convert_3_general; break; } } void (*func3)(wuffs_base__pixel_buffer * dst, // uint32_t x_min_incl, // uint32_t x_max_excl, // uint32_t y_min_incl, // uint32_t y_max_excl, // const uint8_t* src_ptr0, // const uint8_t* src_ptr1, // const uint8_t* src_ptr2, // uint32_t stride0, // uint32_t stride1, // uint32_t stride2, // uint32_t inv_h0, // uint32_t inv_h1, // uint32_t inv_h2, // uint32_t inv_v0, // uint32_t inv_v1, // uint32_t inv_v2, // uint32_t half_width_for_2to1, // uint32_t half_height_for_2to1, // uint8_t* scratch_buffer_2k_ptr, // wuffs_private_impl__swizzle_ycc__upsample_func(*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_3_func conv3func) = &wuffs_private_impl__swizzle_ycc__general__box_filter; void (*func4)(wuffs_base__pixel_buffer * dst, // uint32_t x_min_incl, // uint32_t x_max_excl, // uint32_t y_min_incl, // uint32_t y_max_excl, // const uint8_t* src_ptr0, // const uint8_t* src_ptr1, // const uint8_t* src_ptr2, // const uint8_t* src_ptr3, // uint32_t stride0, // uint32_t stride1, // uint32_t stride2, // uint32_t stride3, // uint32_t inv_h0, // uint32_t inv_h1, // uint32_t inv_h2, // uint32_t inv_h3, // uint32_t inv_v0, // uint32_t inv_v1, // uint32_t inv_v2, // uint32_t inv_v3, // uint32_t half_width_for_2to1, // uint32_t half_height_for_2to1, // uint8_t* scratch_buffer_2k_ptr, // wuffs_private_impl__swizzle_ycc__upsample_func(*upfuncs)[4][4], wuffs_private_impl__swizzle_ycc__convert_4_func conv4func) = &wuffs_private_impl__swizzle_ycck__general__box_filter; wuffs_private_impl__swizzle_ycc__upsample_func upfuncs[4][4]; memcpy(&upfuncs, &wuffs_private_impl__swizzle_ycc__upsample_funcs, sizeof upfuncs); if (triangle_filter_for_2to1 && (wuffs_private_impl__swizzle_has_triangle_upsampler(inv_h0, inv_v0) || wuffs_private_impl__swizzle_has_triangle_upsampler(inv_h1, inv_v1) || wuffs_private_impl__swizzle_has_triangle_upsampler(inv_h2, inv_v2) || wuffs_private_impl__swizzle_has_triangle_upsampler(inv_h3, inv_v3))) { func3 = &wuffs_private_impl__swizzle_ycc__general__triangle_filter; func4 = &wuffs_private_impl__swizzle_ycck__general__triangle_filter; upfuncs[0][1] = wuffs_private_impl__swizzle_ycc__upsample_inv_h1v2_triangle; upfuncs[1][0] = wuffs_private_impl__swizzle_ycc__upsample_inv_h2v1_triangle; upfuncs[1][1] = wuffs_private_impl__swizzle_ycc__upsample_inv_h2v2_triangle; #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) #if defined(__GNUC__) && !defined(__clang__) // Don't use our AVX2 implementation for GCC (but do use it for clang). For // some unknown reason, GCC performs noticably better on the non-SIMD // version. Possibly because GCC's auto-vectorizer is smarter (just with // SSE2, not AVX2) than our hand-written code, but that's just a guess. // // See commits 51bc60ef9298cb2efc1b29a9681191f66d49820d and // cd769a0cdf1b5affee13f6089b995f3d39569cb4 for benchmark numbers. // // See also https://godbolt.org/z/MbhbPGEz4 for Debian Bullseye's clang 11 // versus gcc 10, where only gcc auto-vectorizes, although later clang // versions will also auto-vectorize. #else if (wuffs_base__cpu_arch__have_x86_avx2()) { upfuncs[1][1] = wuffs_private_impl__swizzle_ycc__upsample_inv_h2v2_triangle_x86_avx2; } #endif #endif } if ((h3 != 0u) || (v3 != 0u)) { wuffs_private_impl__swizzle_ycc__convert_4_func conv4func = is_rgb_or_cmyk ? &wuffs_private_impl__swizzle_cmyk__convert_4_general : &wuffs_private_impl__swizzle_ycck__convert_4_general; (*func4)( // dst, x_min_incl, x_max_excl, y_min_incl, y_max_excl, // src0.ptr, src1.ptr, src2.ptr, src3.ptr, // stride0, stride1, stride2, stride3, // inv_h0, inv_h1, inv_h2, inv_h3, // inv_v0, inv_v1, inv_v2, inv_v3, // half_width_for_2to1, half_height_for_2to1, // scratch_buffer_2k.ptr, &upfuncs, conv4func); } else { (*func3)( // dst, x_min_incl, x_max_excl, y_min_incl, y_max_excl, // src0.ptr, src1.ptr, src2.ptr, // stride0, stride1, stride2, // inv_h0, inv_h1, inv_h2, // inv_v0, inv_v1, inv_v2, // half_width_for_2to1, half_height_for_2to1, // scratch_buffer_2k.ptr, &upfuncs, conv3func); } return wuffs_base__make_status(NULL); } // -------- // ‼ WUFFS MULTI-FILE SECTION +x86_avx2 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static void // wuffs_private_impl__swizzle_ycc__convert_3_bgrx_x86_avx2( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { if ((x + 32u) > x_end) { wuffs_private_impl__swizzle_ycc__convert_3_bgrx( // dst, x, x_end, y, up0, up1, up2); return; } size_t dst_stride = dst->private_impl.planes[0].stride; uint8_t* dst_iter = dst->private_impl.planes[0].ptr + (dst_stride * ((size_t)y)) + (4u * ((size_t)x)); // u0001 = u16x16 [0x0001 .. 0x0001] // u00FF = u16x16 [0x00FF .. 0x00FF] // uFF80 = u16x16 [0xFF80 .. 0xFF80] // uFFFF = u16x16 [0xFFFF .. 0xFFFF] const __m256i u0001 = _mm256_set1_epi16(+0x0001); const __m256i u00FF = _mm256_set1_epi16(+0x00FF); const __m256i uFF80 = _mm256_set1_epi16(-0x0080); const __m256i uFFFF = _mm256_set1_epi16(-0x0001); // p8000_p0000 = u16x16 [0x8000 0x0000 .. 0x8000 0x0000] const __m256i p8000_p0000 = _mm256_set_epi16( // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000); // Per wuffs_base__color_ycc__as__color_u32, the formulae: // // R = Y + 1.40200 * Cr // G = Y - 0.34414 * Cb - 0.71414 * Cr // B = Y + 1.77200 * Cb // // When scaled by 1<<16: // // 0.34414 becomes 0x0581A = 22554. // 0.71414 becomes 0x0B6D2 = 46802. // 1.40200 becomes 0x166E9 = 91881. // 1.77200 becomes 0x1C5A2 = 116130. // // Separate the integer and fractional parts, since we work with signed // 16-bit SIMD lanes. The fractional parts range from -0.5 .. +0.5 (as // floating-point) which is from -0x8000 .. +0x8000 (as fixed-point). // // -0x3A5E = -0x20000 + 0x1C5A2 The B:Cb factor. // +0x66E9 = -0x10000 + 0x166E9 The R:Cr factor. // -0x581A = +0x00000 - 0x0581A The G:Cb factor. // +0x492E = +0x10000 - 0x0B6D2 The G:Cr factor. const __m256i m3A5E = _mm256_set1_epi16(-0x3A5E); const __m256i p66E9 = _mm256_set1_epi16(+0x66E9); const __m256i m581A_p492E = _mm256_set_epi16( // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A); while (x < x_end) { // Load chroma values in even and odd columns (the high 8 bits of each // u16x16 element are zero) and then subtract 0x0080. // // cb_all = u8x32 [cb.00 cb.01 cb.02 cb.03 .. cb.1C cb.1D cb.1E cb.1F] // cb_eve = i16x16 [cb.00-0x80 cb.02-0x80 .. cb.1C-0x80 cb.1E-0x80 ] // cb_odd = i16x16 [cb.01-0x80 cb.03-0x80 .. cb.1D-0x80 cb.1F-0x80 ] // // Ditto for the cr_xxx Chroma-Red values. __m256i cb_all = _mm256_lddqu_si256((const __m256i*)(const void*)up1); __m256i cr_all = _mm256_lddqu_si256((const __m256i*)(const void*)up2); __m256i cb_eve = _mm256_add_epi16(uFF80, _mm256_and_si256(cb_all, u00FF)); __m256i cr_eve = _mm256_add_epi16(uFF80, _mm256_and_si256(cr_all, u00FF)); __m256i cb_odd = _mm256_add_epi16(uFF80, _mm256_srli_epi16(cb_all, 8)); __m256i cr_odd = _mm256_add_epi16(uFF80, _mm256_srli_epi16(cr_all, 8)); // ---- // Calculate: // // B-Y = (+1.77200 * Cb) as floating-point // R-Y = (+1.40200 * Cr) as floating-point // // B-Y = ((0x2_0000 - 0x3A5E) * Cb) as fixed-point // R-Y = ((0x1_0000 + 0x66E9) * Cr) as fixed-point // // B-Y = ((-0x3A5E * Cb) + ("2.0" * Cb)) // R-Y = ((+0x66E9 * Cr) + ("1.0" * Cr)) // Multiply by m3A5E or p66E9, taking the high 16 bits. There's also a // doubling (add x to itself), adding-of-1 and halving (shift right by 1). // That makes multiply-and-take-high round to nearest (instead of down). __m256i tmp_by_eve = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cb_eve, cb_eve), m3A5E), u0001), 1); __m256i tmp_by_odd = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cb_odd, cb_odd), m3A5E), u0001), 1); __m256i tmp_ry_eve = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cr_eve, cr_eve), p66E9), u0001), 1); __m256i tmp_ry_odd = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cr_odd, cr_odd), p66E9), u0001), 1); // Add (2 * Cb) and (1 * Cr). __m256i by_eve = _mm256_add_epi16(tmp_by_eve, _mm256_add_epi16(cb_eve, cb_eve)); __m256i by_odd = _mm256_add_epi16(tmp_by_odd, _mm256_add_epi16(cb_odd, cb_odd)); __m256i ry_eve = _mm256_add_epi16(tmp_ry_eve, cr_eve); __m256i ry_odd = _mm256_add_epi16(tmp_ry_odd, cr_odd); // ---- // Calculate: // // G-Y = (-0.34414 * Cb) + // (-0.71414 * Cr) as floating-point // // G-Y = ((+0x0_0000 - 0x581A) * Cb) + // ((-0x1_0000 + 0x492E) * Cr) as fixed-point // // G-Y = (-0x581A * Cb) + // (+0x492E * Cr) - ("1.0" * Cr) // Multiply-add to get ((-0x581A * Cb) + (+0x492E * Cr)). __m256i tmp0_gy_eve_lo = _mm256_madd_epi16( // _mm256_unpacklo_epi16(cb_eve, cr_eve), m581A_p492E); __m256i tmp0_gy_eve_hi = _mm256_madd_epi16( // _mm256_unpackhi_epi16(cb_eve, cr_eve), m581A_p492E); __m256i tmp0_gy_odd_lo = _mm256_madd_epi16( // _mm256_unpacklo_epi16(cb_odd, cr_odd), m581A_p492E); __m256i tmp0_gy_odd_hi = _mm256_madd_epi16( // _mm256_unpackhi_epi16(cb_odd, cr_odd), m581A_p492E); // Divide the i32x8 vectors by (1 << 16), rounding to nearest. __m256i tmp1_gy_eve_lo = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_eve_lo, p8000_p0000), 16); __m256i tmp1_gy_eve_hi = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_eve_hi, p8000_p0000), 16); __m256i tmp1_gy_odd_lo = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_odd_lo, p8000_p0000), 16); __m256i tmp1_gy_odd_hi = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_odd_hi, p8000_p0000), 16); // Pack the ((-0x581A * Cb) + (+0x492E * Cr)) as i16x16 and subtract Cr. __m256i gy_eve = _mm256_sub_epi16( _mm256_packs_epi32(tmp1_gy_eve_lo, tmp1_gy_eve_hi), cr_eve); __m256i gy_odd = _mm256_sub_epi16( _mm256_packs_epi32(tmp1_gy_odd_lo, tmp1_gy_odd_hi), cr_odd); // ---- // Add Y to (B-Y), (G-Y) and (R-Y) to produce B, G and R. // // For the resultant packed_x_xxx vectors, only elements 0 ..= 7 and 16 ..= // 23 of the 32-element vectors matter (since we'll unpacklo but not // unpackhi them). Let … denote 8 ignored consecutive u8 values and let % // denote 0xFF. We'll end this section with: // // packed_b_eve = u8x32 [b00 b02 .. b0C b0E … b10 b12 .. b1C b1E …] // packed_b_odd = u8x32 [b01 b03 .. b0D b0F … b11 b13 .. b1D b1F …] // packed_g_eve = u8x32 [g00 g02 .. g0C g0E … g10 g12 .. g1C g1E …] // packed_g_odd = u8x32 [g01 g03 .. g0D g0F … g11 g13 .. g1D g1F …] // packed_r_eve = u8x32 [r00 r02 .. r0C r0E … r10 r12 .. r1C r1E …] // packed_r_odd = u8x32 [r01 r03 .. r0D r0F … r11 r13 .. r1D r1F …] // uFFFF = u8x32 [ % % .. % % … % % .. % % …] __m256i yy_all = _mm256_lddqu_si256((const __m256i*)(const void*)up0); __m256i yy_eve = _mm256_and_si256(yy_all, u00FF); __m256i yy_odd = _mm256_srli_epi16(yy_all, 8); __m256i loose_b_eve = _mm256_add_epi16(by_eve, yy_eve); __m256i loose_b_odd = _mm256_add_epi16(by_odd, yy_odd); __m256i packed_b_eve = _mm256_packus_epi16(loose_b_eve, loose_b_eve); __m256i packed_b_odd = _mm256_packus_epi16(loose_b_odd, loose_b_odd); __m256i loose_g_eve = _mm256_add_epi16(gy_eve, yy_eve); __m256i loose_g_odd = _mm256_add_epi16(gy_odd, yy_odd); __m256i packed_g_eve = _mm256_packus_epi16(loose_g_eve, loose_g_eve); __m256i packed_g_odd = _mm256_packus_epi16(loose_g_odd, loose_g_odd); __m256i loose_r_eve = _mm256_add_epi16(ry_eve, yy_eve); __m256i loose_r_odd = _mm256_add_epi16(ry_odd, yy_odd); __m256i packed_r_eve = _mm256_packus_epi16(loose_r_eve, loose_r_eve); __m256i packed_r_odd = _mm256_packus_epi16(loose_r_odd, loose_r_odd); // ---- // Mix those values (unpacking in 8, 16 and then 32 bit units) to get the // desired BGRX/RGBX order. // // From here onwards, all of our __m256i registers are u8x32. // mix00 = [b00 g00 b02 g02 .. b0E g0E b10 g10 .. b1C g1C b1E g1E] // mix01 = [b01 g01 b03 g03 .. b0F g0F b11 g11 .. b1D g1D b1F g1F] // mix02 = [r00 % r02 % .. r0E % r10 % .. r1C % r1E %] // mix03 = [r01 % r03 % .. r0F % r11 % .. r1D % r1F %] // // See also § below. __m256i mix00 = _mm256_unpacklo_epi8(packed_b_eve, packed_g_eve); __m256i mix01 = _mm256_unpacklo_epi8(packed_b_odd, packed_g_odd); __m256i mix02 = _mm256_unpacklo_epi8(packed_r_eve, uFFFF); __m256i mix03 = _mm256_unpacklo_epi8(packed_r_odd, uFFFF); // mix10 = [b00 g00 r00 % b02 g02 r02 % b04 g04 r04 % b06 g06 r06 % // b10 g10 r10 % b12 g12 r12 % b14 g14 r14 % b16 g16 r16 %] // mix11 = [b01 g01 r01 % b03 g03 r03 % b05 g05 r05 % b07 g07 r07 % // b11 g11 r11 % b13 g13 r13 % b15 g15 r15 % b17 g17 r17 %] // mix12 = [b08 g08 r08 % b0A g0A r0A % b0C g0C r0C % b0E g0E r0E % // b18 g18 r18 % b1A g1A r1A % b1C g1C r1C % b1E g1E r1E %] // mix13 = [b09 g09 r09 % b0B g0B r0B % b0D g0D r0D % b0F g0F r0F % // b19 g19 r19 % b1B g1B r1B % b1D g1D r1D % b1F g1F r1F %] __m256i mix10 = _mm256_unpacklo_epi16(mix00, mix02); __m256i mix11 = _mm256_unpacklo_epi16(mix01, mix03); __m256i mix12 = _mm256_unpackhi_epi16(mix00, mix02); __m256i mix13 = _mm256_unpackhi_epi16(mix01, mix03); // mix20 = [b00 g00 r00 % b01 g01 r01 % b02 g02 r02 % b03 g03 r03 % // b10 g10 r10 % b11 g11 r11 % b12 g12 r12 % b13 g13 r13 %] // mix21 = [b04 g04 r04 % b05 g05 r05 % b06 g06 r06 % b07 g07 r07 % // b14 g14 r14 % b15 g15 r15 % b16 g16 r16 % b17 g17 r17 %] // mix22 = [b08 g08 r08 % b09 g09 r09 % b0A g0A r0A % b0B g0B r0B % // b18 g18 r18 % b19 g19 r19 % b1A g1A r1A % b1B g1B r1B %] // mix23 = [b0C g0C r0C % b0D g0D r0D % b0E g0E r0E % b0F g0F r0F % // b1C g1C r1C % b1D g1D r1D % b1E g1E r1E % b1F g1F r1F %] __m256i mix20 = _mm256_unpacklo_epi32(mix10, mix11); __m256i mix21 = _mm256_unpackhi_epi32(mix10, mix11); __m256i mix22 = _mm256_unpacklo_epi32(mix12, mix13); __m256i mix23 = _mm256_unpackhi_epi32(mix12, mix13); // mix30 = [b00 g00 r00 % b01 g01 r01 % b02 g02 r02 % b03 g03 r03 % // b04 g04 r04 % b05 g05 r05 % b06 g06 r06 % b07 g07 r07 %] // mix31 = [b08 g08 r08 % b09 g09 r09 % b0A g0A r0A % b0B g0B r0B % // b0C g0C r0C % b0D g0D r0D % b0E g0E r0E % b0F g0F r0F %] // mix32 = [b10 g10 r10 % b11 g11 r11 % b12 g12 r12 % b13 g13 r13 % // b14 g14 r14 % b15 g15 r15 % b16 g16 r16 % b17 g17 r17 %] // mix33 = [b18 g18 r18 % b19 g19 r19 % b1A g1A r1A % b1B g1B r1B % // b1C g1C r1C % b1D g1D r1D % b1E g1E r1E % b1F g1F r1F %] __m256i mix30 = _mm256_permute2x128_si256(mix20, mix21, 0x20); __m256i mix31 = _mm256_permute2x128_si256(mix22, mix23, 0x20); __m256i mix32 = _mm256_permute2x128_si256(mix20, mix21, 0x31); __m256i mix33 = _mm256_permute2x128_si256(mix22, mix23, 0x31); // Write out four u8x32 SIMD registers (128 bytes, 32 BGRX/RGBX pixels). _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x00), mix30); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x20), mix31); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x40), mix32); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x60), mix33); // Advance by up to 32 pixels. The first iteration might be smaller than 32 // so that all of the remaining steps are exactly 32. uint32_t n = 32u - (31u & (x - x_end)); dst_iter += 4u * n; up0 += n; up1 += n; up2 += n; x += n; } } // The rgbx flavor (below) is exactly the same as the bgrx flavor (above) // except for the lines marked with a § and that comments were stripped. WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static void // wuffs_private_impl__swizzle_ycc__convert_3_rgbx_x86_avx2( wuffs_base__pixel_buffer* dst, uint32_t x, uint32_t x_end, uint32_t y, const uint8_t* up0, const uint8_t* up1, const uint8_t* up2) { if ((x + 32u) > x_end) { wuffs_private_impl__swizzle_ycc__convert_3_bgrx( // dst, x, x_end, y, up0, up1, up2); return; } size_t dst_stride = dst->private_impl.planes[0].stride; uint8_t* dst_iter = dst->private_impl.planes[0].ptr + (dst_stride * ((size_t)y)) + (4u * ((size_t)x)); const __m256i u0001 = _mm256_set1_epi16(+0x0001); const __m256i u00FF = _mm256_set1_epi16(+0x00FF); const __m256i uFF80 = _mm256_set1_epi16(-0x0080); const __m256i uFFFF = _mm256_set1_epi16(-0x0001); const __m256i p8000_p0000 = _mm256_set_epi16( // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000, // +0x0000, -0x8000, +0x0000, -0x8000); const __m256i m3A5E = _mm256_set1_epi16(-0x3A5E); const __m256i p66E9 = _mm256_set1_epi16(+0x66E9); const __m256i m581A_p492E = _mm256_set_epi16( // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A, // +0x492E, -0x581A, +0x492E, -0x581A); while (x < x_end) { __m256i cb_all = _mm256_lddqu_si256((const __m256i*)(const void*)up1); __m256i cr_all = _mm256_lddqu_si256((const __m256i*)(const void*)up2); __m256i cb_eve = _mm256_add_epi16(uFF80, _mm256_and_si256(cb_all, u00FF)); __m256i cr_eve = _mm256_add_epi16(uFF80, _mm256_and_si256(cr_all, u00FF)); __m256i cb_odd = _mm256_add_epi16(uFF80, _mm256_srli_epi16(cb_all, 8)); __m256i cr_odd = _mm256_add_epi16(uFF80, _mm256_srli_epi16(cr_all, 8)); __m256i tmp_by_eve = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cb_eve, cb_eve), m3A5E), u0001), 1); __m256i tmp_by_odd = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cb_odd, cb_odd), m3A5E), u0001), 1); __m256i tmp_ry_eve = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cr_eve, cr_eve), p66E9), u0001), 1); __m256i tmp_ry_odd = _mm256_srai_epi16( _mm256_add_epi16( _mm256_mulhi_epi16(_mm256_add_epi16(cr_odd, cr_odd), p66E9), u0001), 1); __m256i by_eve = _mm256_add_epi16(tmp_by_eve, _mm256_add_epi16(cb_eve, cb_eve)); __m256i by_odd = _mm256_add_epi16(tmp_by_odd, _mm256_add_epi16(cb_odd, cb_odd)); __m256i ry_eve = _mm256_add_epi16(tmp_ry_eve, cr_eve); __m256i ry_odd = _mm256_add_epi16(tmp_ry_odd, cr_odd); __m256i tmp0_gy_eve_lo = _mm256_madd_epi16( // _mm256_unpacklo_epi16(cb_eve, cr_eve), m581A_p492E); __m256i tmp0_gy_eve_hi = _mm256_madd_epi16( // _mm256_unpackhi_epi16(cb_eve, cr_eve), m581A_p492E); __m256i tmp0_gy_odd_lo = _mm256_madd_epi16( // _mm256_unpacklo_epi16(cb_odd, cr_odd), m581A_p492E); __m256i tmp0_gy_odd_hi = _mm256_madd_epi16( // _mm256_unpackhi_epi16(cb_odd, cr_odd), m581A_p492E); __m256i tmp1_gy_eve_lo = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_eve_lo, p8000_p0000), 16); __m256i tmp1_gy_eve_hi = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_eve_hi, p8000_p0000), 16); __m256i tmp1_gy_odd_lo = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_odd_lo, p8000_p0000), 16); __m256i tmp1_gy_odd_hi = _mm256_srai_epi32(_mm256_add_epi32(tmp0_gy_odd_hi, p8000_p0000), 16); __m256i gy_eve = _mm256_sub_epi16( _mm256_packs_epi32(tmp1_gy_eve_lo, tmp1_gy_eve_hi), cr_eve); __m256i gy_odd = _mm256_sub_epi16( _mm256_packs_epi32(tmp1_gy_odd_lo, tmp1_gy_odd_hi), cr_odd); __m256i yy_all = _mm256_lddqu_si256((const __m256i*)(const void*)up0); __m256i yy_eve = _mm256_and_si256(yy_all, u00FF); __m256i yy_odd = _mm256_srli_epi16(yy_all, 8); __m256i loose_b_eve = _mm256_add_epi16(by_eve, yy_eve); __m256i loose_b_odd = _mm256_add_epi16(by_odd, yy_odd); __m256i packed_b_eve = _mm256_packus_epi16(loose_b_eve, loose_b_eve); __m256i packed_b_odd = _mm256_packus_epi16(loose_b_odd, loose_b_odd); __m256i loose_g_eve = _mm256_add_epi16(gy_eve, yy_eve); __m256i loose_g_odd = _mm256_add_epi16(gy_odd, yy_odd); __m256i packed_g_eve = _mm256_packus_epi16(loose_g_eve, loose_g_eve); __m256i packed_g_odd = _mm256_packus_epi16(loose_g_odd, loose_g_odd); __m256i loose_r_eve = _mm256_add_epi16(ry_eve, yy_eve); __m256i loose_r_odd = _mm256_add_epi16(ry_odd, yy_odd); __m256i packed_r_eve = _mm256_packus_epi16(loose_r_eve, loose_r_eve); __m256i packed_r_odd = _mm256_packus_epi16(loose_r_odd, loose_r_odd); // § Note the swapped B and R channels. __m256i mix00 = _mm256_unpacklo_epi8(packed_r_eve, packed_g_eve); __m256i mix01 = _mm256_unpacklo_epi8(packed_r_odd, packed_g_odd); __m256i mix02 = _mm256_unpacklo_epi8(packed_b_eve, uFFFF); __m256i mix03 = _mm256_unpacklo_epi8(packed_b_odd, uFFFF); __m256i mix10 = _mm256_unpacklo_epi16(mix00, mix02); __m256i mix11 = _mm256_unpacklo_epi16(mix01, mix03); __m256i mix12 = _mm256_unpackhi_epi16(mix00, mix02); __m256i mix13 = _mm256_unpackhi_epi16(mix01, mix03); __m256i mix20 = _mm256_unpacklo_epi32(mix10, mix11); __m256i mix21 = _mm256_unpackhi_epi32(mix10, mix11); __m256i mix22 = _mm256_unpacklo_epi32(mix12, mix13); __m256i mix23 = _mm256_unpackhi_epi32(mix12, mix13); __m256i mix30 = _mm256_permute2x128_si256(mix20, mix21, 0x20); __m256i mix31 = _mm256_permute2x128_si256(mix22, mix23, 0x20); __m256i mix32 = _mm256_permute2x128_si256(mix20, mix21, 0x31); __m256i mix33 = _mm256_permute2x128_si256(mix22, mix23, 0x31); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x00), mix30); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x20), mix31); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x40), mix32); _mm256_storeu_si256((__m256i*)(void*)(dst_iter + 0x60), mix33); uint32_t n = 32u - (31u & (x - x_end)); dst_iter += 4u * n; up0 += n; up1 += n; up2 += n; x += n; } } #if defined(__GNUC__) && !defined(__clang__) // No-op. #else WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") static const uint8_t* // wuffs_private_impl__swizzle_ycc__upsample_inv_h2v2_triangle_x86_avx2( uint8_t* dst_ptr, const uint8_t* src_ptr_major, const uint8_t* src_ptr_minor, size_t src_len, uint32_t h1v2_bias_ignored, bool first_column, bool last_column) { uint8_t* dp = dst_ptr; const uint8_t* sp_major = src_ptr_major; const uint8_t* sp_minor = src_ptr_minor; if (first_column) { src_len--; if ((src_len <= 0u) && last_column) { uint32_t sv = (12u * ((uint32_t)(*sp_major++))) + // (4u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + 8u) >> 4u); *dp++ = (uint8_t)((sv + 7u) >> 4u); return dst_ptr; } uint32_t sv_major_m1 = sp_major[-0]; // Clamp offset to zero. uint32_t sv_minor_m1 = sp_minor[-0]; // Clamp offset to zero. uint32_t sv_major_p1 = sp_major[+1]; uint32_t sv_minor_p1 = sp_minor[+1]; uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); if (src_len <= 0u) { return dst_ptr; } } if (last_column) { src_len--; } if (src_len < 32) { // This fallback is the same as the non-SIMD-capable code path. for (; src_len > 0u; src_len--) { uint32_t sv_major_m1 = sp_major[-1]; uint32_t sv_minor_m1 = sp_minor[-1]; uint32_t sv_major_p1 = sp_major[+1]; uint32_t sv_minor_p1 = sp_minor[+1]; uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); } } else { while (src_len > 0u) { // Load 1+32+1 samples (six u8x32 vectors) from the major (jxx) and minor // (nxx) rows. // // major_p0 = [j00 j01 j02 j03 .. j28 j29 j30 j31] // p0 = "plus 0" // minor_p0 = [n00 n01 n02 n03 .. n28 n29 n30 n31] // p0 = "plus 0" // major_m1 = [jm1 j00 j01 j02 .. j27 j28 j29 j30] // m1 = "minus 1" // minor_m1 = [nm1 n00 n01 n02 .. n27 n28 n29 n30] // m1 = "minus 1" // major_p1 = [j01 j02 j03 j04 .. j29 j30 j31 j32] // p1 = "plus 1" // minor_p1 = [n01 n02 n03 n04 .. n29 n30 n31 n32] // p1 = "plus 1" __m256i major_p0 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_major + 0)); __m256i minor_p0 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_minor + 0)); __m256i major_m1 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_major - 1)); __m256i minor_m1 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_minor - 1)); __m256i major_p1 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_major + 1)); __m256i minor_p1 = _mm256_lddqu_si256((const __m256i*)(const void*)(sp_minor + 1)); // Unpack, staying with u8x32 vectors. // // step1_p0_lo = [j00 n00 j01 n01 .. j07 n07 j16 n16 j17 n17 .. j23 n23] // step1_p0_hi = [j08 n08 j09 n09 .. j15 n15 j24 n24 j25 n25 .. j31 n31] // step1_m1_lo = [jm1 nm1 j00 n00 .. j06 n06 j15 n15 j16 n16 .. j22 n22] // step1_m1_hi = [j07 n07 j08 n08 .. j14 n14 j23 n23 j24 n24 .. j30 n30] // step1_p1_lo = [j01 n01 j02 n02 .. j08 n08 j17 n17 j18 n18 .. j24 n24] // step1_p1_hi = [j09 n09 j10 n10 .. j16 n16 j25 n25 j26 n26 .. j32 n32] __m256i step1_p0_lo = _mm256_unpacklo_epi8(major_p0, minor_p0); __m256i step1_p0_hi = _mm256_unpackhi_epi8(major_p0, minor_p0); __m256i step1_m1_lo = _mm256_unpacklo_epi8(major_m1, minor_m1); __m256i step1_m1_hi = _mm256_unpackhi_epi8(major_m1, minor_m1); __m256i step1_p1_lo = _mm256_unpacklo_epi8(major_p1, minor_p1); __m256i step1_p1_hi = _mm256_unpackhi_epi8(major_p1, minor_p1); // Multiply-add to get u16x16 vectors. // // step2_p0_lo = [9*j00+3*n00 9*j01+3*n01 .. 9*j23+3*n23] // step2_p0_hi = [9*j08+3*n08 9*j09+3*n09 .. 9*j31+3*n31] // step2_m1_lo = [3*jm1+1*nm1 3*j00+1*n00 .. 3*j22+1*n22] // step2_m1_hi = [3*j07+1*n07 3*j08+1*n08 .. 3*j30+1*n30] // step2_p1_lo = [3*j01+1*n01 3*j02+1*n02 .. 3*j24+1*n24] // step2_p1_hi = [3*j09+1*n09 3*j10+1*n10 .. 3*j32+1*n32] const __m256i k0309 = _mm256_set1_epi16(0x0309); const __m256i k0103 = _mm256_set1_epi16(0x0103); __m256i step2_p0_lo = _mm256_maddubs_epi16(step1_p0_lo, k0309); __m256i step2_p0_hi = _mm256_maddubs_epi16(step1_p0_hi, k0309); __m256i step2_m1_lo = _mm256_maddubs_epi16(step1_m1_lo, k0103); __m256i step2_m1_hi = _mm256_maddubs_epi16(step1_m1_hi, k0103); __m256i step2_p1_lo = _mm256_maddubs_epi16(step1_p1_lo, k0103); __m256i step2_p1_hi = _mm256_maddubs_epi16(step1_p1_hi, k0103); // Compute the weighted sums of (p0, m1) and (p0, p1). For example: // // step3_m1_lo[00] = ((9*j00) + (3*n00) + (3*jm1) + (1*nm1)) as u16 // step3_p1_hi[15] = ((9*j31) + (3*n31) + (3*j32) + (1*n32)) as u16 __m256i step3_m1_lo = _mm256_add_epi16(step2_p0_lo, step2_m1_lo); __m256i step3_m1_hi = _mm256_add_epi16(step2_p0_hi, step2_m1_hi); __m256i step3_p1_lo = _mm256_add_epi16(step2_p0_lo, step2_p1_lo); __m256i step3_p1_hi = _mm256_add_epi16(step2_p0_hi, step2_p1_hi); // Bias by 8 (on the left) or 7 (on the right) and then divide by 16 // (which is 9+3+3+1) to get a weighted average. On the left (m1), shift // the u16 right value by 4. On the right (p1), shift right by 4 and then // shift left by 8 so that, when still in the u16x16 little-endian // interpretation, we have: // - m1_element = (etcetera + 8) >> 4 // - p1_element = ((etcetera + 7) >> 4) << 8 // // step4_m1_lo = [0x00?? 0x00?? ... 0x00?? 0x00??] // step4_p1_lo = [0x??00 0x??00 ... 0x??00 0x??00] // step4_m1_hi = [0x00?? 0x00?? ... 0x00?? 0x00??] // step4_p1_hi = [0x??00 0x??00 ... 0x??00 0x??00] __m256i step4_m1_lo = _mm256_srli_epi16( _mm256_add_epi16(step3_m1_lo, _mm256_set1_epi16(8)), 4); __m256i step4_p1_lo = _mm256_slli_epi16( _mm256_srli_epi16(_mm256_add_epi16(step3_p1_lo, _mm256_set1_epi16(7)), 4), 8); __m256i step4_m1_hi = _mm256_srli_epi16( _mm256_add_epi16(step3_m1_hi, _mm256_set1_epi16(8)), 4); __m256i step4_p1_hi = _mm256_slli_epi16( _mm256_srli_epi16(_mm256_add_epi16(step3_p1_hi, _mm256_set1_epi16(7)), 4), 8); // Bitwise-or two "0x00"-rich u16x16 vectors to get a u8x32 vector. Do // that twice. Once for the low columns and once for the high columns. // // In terms of jxx (major row) or nxx (minor row) source samples: // - low columns means ( 0 .. 8; 16 .. 24). // - high columns means ( 8 .. 16; 24 .. 32). // // In terms of dxx destination samples (there are twice as many): // - low columns means ( 0 .. 16; 32 .. 48). // - high columns means (16 .. 32; 48 .. 64). // // step5_lo = [d00 d01 .. d14 d15 d32 d33 .. d46 d47] // step5_hi = [d16 d17 .. d30 d31 d48 d49 .. d62 d63] // // The d00, d02 ... d62 even elements come from (p0, m1) weighted sums. // The d01, d03 ... d63 odd elements come from (p0, p1) weighted sums. __m256i step5_lo = _mm256_or_si256(step4_m1_lo, step4_p1_lo); __m256i step5_hi = _mm256_or_si256(step4_m1_hi, step4_p1_hi); // Permute and store. // // step6_00_31 = [d00 d01 .. d14 d15 d16 d17 .. d30 d31] // step6_32_63 = [d32 d33 .. d46 d47 d48 d49 .. d62 d63] __m256i step6_00_31 = _mm256_permute2x128_si256(step5_lo, step5_hi, 0x20); __m256i step6_32_63 = _mm256_permute2x128_si256(step5_lo, step5_hi, 0x31); _mm256_storeu_si256((__m256i*)(void*)(dp + 0x00), step6_00_31); _mm256_storeu_si256((__m256i*)(void*)(dp + 0x20), step6_32_63); // Advance by up to 32 source samples (64 destination samples). The first // iteration might be smaller than 32 so that all of the remaining steps // are exactly 32. size_t n = 32u - (31u & (0u - src_len)); dp += 2u * n; sp_major += n; sp_minor += n; src_len -= n; } } if (last_column) { uint32_t sv_major_m1 = sp_major[-1]; uint32_t sv_minor_m1 = sp_minor[-1]; uint32_t sv_major_p1 = sp_major[+0]; // Clamp offset to zero. uint32_t sv_minor_p1 = sp_minor[+0]; // Clamp offset to zero. uint32_t sv = (9u * ((uint32_t)(*sp_major++))) + // (3u * ((uint32_t)(*sp_minor++))); *dp++ = (uint8_t)((sv + (3u * sv_major_m1) + (sv_minor_m1) + 8u) >> 4u); *dp++ = (uint8_t)((sv + (3u * sv_major_p1) + (sv_minor_p1) + 7u) >> 4u); } return dst_ptr; } #endif #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) // ‼ WUFFS MULTI-FILE SECTION -x86_avx2 #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__PIXCONV) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BASE) || \ defined(WUFFS_CONFIG__MODULE__BASE__UTF8) // ---------------- Unicode and UTF-8 WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__utf_8__encode(wuffs_base__slice_u8 dst, uint32_t code_point) { if (code_point <= 0x7F) { if (dst.len >= 1) { dst.ptr[0] = (uint8_t)(code_point); return 1; } } else if (code_point <= 0x07FF) { if (dst.len >= 2) { dst.ptr[0] = (uint8_t)(0xC0 | ((code_point >> 6))); dst.ptr[1] = (uint8_t)(0x80 | ((code_point >> 0) & 0x3F)); return 2; } } else if (code_point <= 0xFFFF) { if ((dst.len >= 3) && ((code_point < 0xD800) || (0xDFFF < code_point))) { dst.ptr[0] = (uint8_t)(0xE0 | ((code_point >> 12))); dst.ptr[1] = (uint8_t)(0x80 | ((code_point >> 6) & 0x3F)); dst.ptr[2] = (uint8_t)(0x80 | ((code_point >> 0) & 0x3F)); return 3; } } else if (code_point <= 0x10FFFF) { if (dst.len >= 4) { dst.ptr[0] = (uint8_t)(0xF0 | ((code_point >> 18))); dst.ptr[1] = (uint8_t)(0x80 | ((code_point >> 12) & 0x3F)); dst.ptr[2] = (uint8_t)(0x80 | ((code_point >> 6) & 0x3F)); dst.ptr[3] = (uint8_t)(0x80 | ((code_point >> 0) & 0x3F)); return 4; } } return 0; } // wuffs_base__utf_8__byte_length_minus_1 is the byte length (minus 1) of a // UTF-8 encoded code point, based on the encoding's initial byte. // - 0x00 is 1-byte UTF-8 (ASCII). // - 0x01 is the start of 2-byte UTF-8. // - 0x02 is the start of 3-byte UTF-8. // - 0x03 is the start of 4-byte UTF-8. // - 0x40 is a UTF-8 tail byte. // - 0x80 is invalid UTF-8. // // RFC 3629 (UTF-8) gives this grammar for valid UTF-8: // UTF8-1 = %x00-7F // UTF8-2 = %xC2-DF UTF8-tail // UTF8-3 = %xE0 %xA0-BF UTF8-tail / %xE1-EC 2( UTF8-tail ) / // %xED %x80-9F UTF8-tail / %xEE-EF 2( UTF8-tail ) // UTF8-4 = %xF0 %x90-BF 2( UTF8-tail ) / %xF1-F3 3( UTF8-tail ) / // %xF4 %x80-8F 2( UTF8-tail ) // UTF8-tail = %x80-BF static const uint8_t wuffs_base__utf_8__byte_length_minus_1[256] = { // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x00 ..= 0x07. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x08 ..= 0x0F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x10 ..= 0x17. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x18 ..= 0x1F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x20 ..= 0x27. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x28 ..= 0x2F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x30 ..= 0x37. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x38 ..= 0x3F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x40 ..= 0x47. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x48 ..= 0x4F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x50 ..= 0x57. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x58 ..= 0x5F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x60 ..= 0x67. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x68 ..= 0x6F. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x70 ..= 0x77. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // 0x78 ..= 0x7F. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0x80 ..= 0x87. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0x88 ..= 0x8F. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0x90 ..= 0x97. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0x98 ..= 0x9F. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0xA0 ..= 0xA7. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0xA8 ..= 0xAF. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0xB0 ..= 0xB7. 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, // 0xB8 ..= 0xBF. 0x80, 0x80, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, // 0xC0 ..= 0xC7. 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, // 0xC8 ..= 0xCF. 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, // 0xD0 ..= 0xD7. 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, 0x01, // 0xD8 ..= 0xDF. 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, // 0xE0 ..= 0xE7. 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, // 0xE8 ..= 0xEF. 0x03, 0x03, 0x03, 0x03, 0x03, 0x80, 0x80, 0x80, // 0xF0 ..= 0xF7. 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, // 0xF8 ..= 0xFF. // 0 1 2 3 4 5 6 7 // 8 9 A B C D E F }; WUFFS_BASE__MAYBE_STATIC wuffs_base__utf_8__next__output // wuffs_base__utf_8__next(const uint8_t* s_ptr, size_t s_len) { if (s_len == 0) { return wuffs_base__make_utf_8__next__output(0, 0); } uint32_t c = s_ptr[0]; switch (wuffs_base__utf_8__byte_length_minus_1[c & 0xFF]) { case 0: return wuffs_base__make_utf_8__next__output(c, 1); case 1: if (s_len < 2) { break; } c = wuffs_base__peek_u16le__no_bounds_check(s_ptr); if ((c & 0xC000) != 0x8000) { break; } c = (0x0007C0 & (c << 6)) | (0x00003F & (c >> 8)); return wuffs_base__make_utf_8__next__output(c, 2); case 2: if (s_len < 3) { break; } c = wuffs_base__peek_u24le__no_bounds_check(s_ptr); if ((c & 0xC0C000) != 0x808000) { break; } c = (0x00F000 & (c << 12)) | (0x000FC0 & (c >> 2)) | (0x00003F & (c >> 16)); if ((c <= 0x07FF) || ((0xD800 <= c) && (c <= 0xDFFF))) { break; } return wuffs_base__make_utf_8__next__output(c, 3); case 3: if (s_len < 4) { break; } c = wuffs_base__peek_u32le__no_bounds_check(s_ptr); if ((c & 0xC0C0C000) != 0x80808000) { break; } c = (0x1C0000 & (c << 18)) | (0x03F000 & (c << 4)) | (0x000FC0 & (c >> 10)) | (0x00003F & (c >> 24)); if ((c <= 0xFFFF) || (0x110000 <= c)) { break; } return wuffs_base__make_utf_8__next__output(c, 4); } return wuffs_base__make_utf_8__next__output( WUFFS_BASE__UNICODE_REPLACEMENT_CHARACTER, 1); } WUFFS_BASE__MAYBE_STATIC wuffs_base__utf_8__next__output // wuffs_base__utf_8__next_from_end(const uint8_t* s_ptr, size_t s_len) { if (s_len == 0) { return wuffs_base__make_utf_8__next__output(0, 0); } const uint8_t* ptr = &s_ptr[s_len - 1]; if (*ptr < 0x80) { return wuffs_base__make_utf_8__next__output(*ptr, 1); } else if (*ptr < 0xC0) { const uint8_t* too_far = &s_ptr[(s_len > 4) ? (s_len - 4) : 0]; uint32_t n = 1; while (ptr != too_far) { ptr--; n++; if (*ptr < 0x80) { break; } else if (*ptr < 0xC0) { continue; } wuffs_base__utf_8__next__output o = wuffs_base__utf_8__next(ptr, n); if (o.byte_length != n) { break; } return o; } } return wuffs_base__make_utf_8__next__output( WUFFS_BASE__UNICODE_REPLACEMENT_CHARACTER, 1); } WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__utf_8__longest_valid_prefix(const uint8_t* s_ptr, size_t s_len) { // TODO: possibly optimize the all-ASCII case (4 or 8 bytes at a time). // // TODO: possibly optimize this by manually inlining the // wuffs_base__utf_8__next calls. size_t original_len = s_len; while (s_len > 0) { wuffs_base__utf_8__next__output o = wuffs_base__utf_8__next(s_ptr, s_len); if ((o.code_point > 0x7F) && (o.byte_length == 1)) { break; } s_ptr += o.byte_length; s_len -= o.byte_length; } return original_len - s_len; } WUFFS_BASE__MAYBE_STATIC size_t // wuffs_base__ascii__longest_valid_prefix(const uint8_t* s_ptr, size_t s_len) { // TODO: possibly optimize this by checking 4 or 8 bytes at a time. const uint8_t* original_ptr = s_ptr; const uint8_t* p = s_ptr; const uint8_t* q = s_ptr + s_len; for (; (p != q) && ((*p & 0x80) == 0); p++) { } return (size_t)(p - original_ptr); } #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__BASE) || // defined(WUFFS_CONFIG__MODULE__BASE__UTF8) #ifdef __cplusplus } // extern "C" #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ADLER32) // ---------------- Status Codes Implementations // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up__choosy_default( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up_arm_neon( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up_x86_sse42( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ---------------- VTables const wuffs_base__hasher_u32__func_ptrs wuffs_adler32__hasher__func_ptrs_for__wuffs_base__hasher_u32 = { (uint32_t(*)(const void*))(&wuffs_adler32__hasher__checksum_u32), (uint64_t(*)(const void*, uint32_t))(&wuffs_adler32__hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_adler32__hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_adler32__hasher__update), (uint32_t(*)(void*, wuffs_base__slice_u8))(&wuffs_adler32__hasher__update_u32), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_adler32__hasher__initialize( wuffs_adler32__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_up = &wuffs_adler32__hasher__up__choosy_default; self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_u32.vtable_name = wuffs_base__hasher_u32__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_u32.function_pointers = (const void*)(&wuffs_adler32__hasher__func_ptrs_for__wuffs_base__hasher_u32); return wuffs_base__make_status(NULL); } wuffs_adler32__hasher* wuffs_adler32__hasher__alloc(void) { wuffs_adler32__hasher* x = (wuffs_adler32__hasher*)(calloc(1, sizeof(wuffs_adler32__hasher))); if (!x) { return NULL; } if (wuffs_adler32__hasher__initialize( x, sizeof(wuffs_adler32__hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_adler32__hasher(void) { return sizeof(wuffs_adler32__hasher); } // ---------------- Function Implementations // -------- func adler32.hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_adler32__hasher__get_quirk( const wuffs_adler32__hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func adler32.hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_adler32__hasher__set_quirk( wuffs_adler32__hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func adler32.hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_adler32__hasher__update( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if ( ! self->private_impl.f_started) { self->private_impl.f_started = true; self->private_impl.f_state = 1u; self->private_impl.choosy_up = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) wuffs_base__cpu_arch__have_arm_neon() ? &wuffs_adler32__hasher__up_arm_neon : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_adler32__hasher__up_x86_sse42 : #endif self->private_impl.choosy_up); } wuffs_adler32__hasher__up(self, a_x); return wuffs_base__make_empty_struct(); } // -------- func adler32.hasher.update_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_adler32__hasher__update_u32( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } wuffs_adler32__hasher__update(self, a_x); return self->private_impl.f_state; } // -------- func adler32.hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { return (*self->private_impl.choosy_up)(self, a_x); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up__choosy_default( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_s1 = 0; uint32_t v_s2 = 0; wuffs_base__slice_u8 v_remaining = {0}; wuffs_base__slice_u8 v_p = {0}; v_s1 = ((self->private_impl.f_state) & 0xFFFFu); v_s2 = ((self->private_impl.f_state) >> (32u - 16u)); while (((uint64_t)(a_x.len)) > 0u) { v_remaining = wuffs_base__slice_u8__subslice_j(a_x, 0u); if (((uint64_t)(a_x.len)) > 5552u) { v_remaining = wuffs_base__slice_u8__subslice_i(a_x, 5552u); a_x = wuffs_base__slice_u8__subslice_j(a_x, 5552u); } { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 1; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 8) * 8)); while (v_p.ptr < i_end0_p) { v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; } v_p.len = 1; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end1_p) { v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; } v_p.len = 0; } v_s1 %= 65521u; v_s2 %= 65521u; a_x = v_remaining; } self->private_impl.f_state = (((v_s2 & 65535u) << 16u) | (v_s1 & 65535u)); return wuffs_base__make_empty_struct(); } // -------- func adler32.hasher.checksum_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_adler32__hasher__checksum_u32( const wuffs_adler32__hasher* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_state; } // ‼ WUFFS MULTI-FILE SECTION +arm_neon // -------- func adler32.hasher.up_arm_neon #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up_arm_neon( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_s1 = 0; uint32_t v_s2 = 0; wuffs_base__slice_u8 v_remaining = {0}; wuffs_base__slice_u8 v_p = {0}; uint8x16_t v_p__left = {0}; uint8x16_t v_p_right = {0}; uint32x4_t v_v1 = {0}; uint32x4_t v_v2 = {0}; uint16x8_t v_col0 = {0}; uint16x8_t v_col1 = {0}; uint16x8_t v_col2 = {0}; uint16x8_t v_col3 = {0}; uint32x2_t v_sum1 = {0}; uint32x2_t v_sum2 = {0}; uint32x2_t v_sum12 = {0}; uint32_t v_num_iterate_bytes = 0; uint64_t v_tail_index = 0; v_s1 = ((self->private_impl.f_state) & 0xFFFFu); v_s2 = ((self->private_impl.f_state) >> (32u - 16u)); while ((((uint64_t)(a_x.len)) > 0u) && ((15u & ((uint32_t)(0xFFFu & (uintptr_t)(a_x.ptr)))) != 0u)) { v_s1 += ((uint32_t)(a_x.ptr[0u])); v_s2 += v_s1; a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } v_s1 %= 65521u; v_s2 %= 65521u; while (((uint64_t)(a_x.len)) > 0u) { v_remaining = wuffs_base__slice_u8__subslice_j(a_x, 0u); if (((uint64_t)(a_x.len)) > 5536u) { v_remaining = wuffs_base__slice_u8__subslice_i(a_x, 5536u); a_x = wuffs_base__slice_u8__subslice_j(a_x, 5536u); } v_num_iterate_bytes = ((uint32_t)((((uint64_t)(a_x.len)) & 4294967264u))); v_s2 += ((uint32_t)(v_s1 * v_num_iterate_bytes)); v_v1 = vdupq_n_u32(0u); v_v2 = vdupq_n_u32(0u); v_col0 = vdupq_n_u16(0u); v_col1 = vdupq_n_u16(0u); v_col2 = vdupq_n_u16(0u); v_col3 = vdupq_n_u16(0u); { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 32; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 32) * 32)); while (v_p.ptr < i_end0_p) { v_p__left = vld1q_u8(v_p.ptr); v_p_right = vld1q_u8(v_p.ptr + 16u); v_v2 = vaddq_u32(v_v2, v_v1); v_v1 = vpadalq_u16(v_v1, vpadalq_u8(vpaddlq_u8(v_p__left), v_p_right)); v_col0 = vaddw_u8(v_col0, vget_low_u8(v_p__left)); v_col1 = vaddw_u8(v_col1, vget_high_u8(v_p__left)); v_col2 = vaddw_u8(v_col2, vget_low_u8(v_p_right)); v_col3 = vaddw_u8(v_col3, vget_high_u8(v_p_right)); v_p.ptr += 32; } v_p.len = 0; } v_v2 = vshlq_n_u32(v_v2, 5u); v_v2 = vmlal_u16(v_v2, vget_low_u16(v_col0), ((uint16x4_t){32u, 31u, 30u, 29u})); v_v2 = vmlal_u16(v_v2, vget_high_u16(v_col0), ((uint16x4_t){28u, 27u, 26u, 25u})); v_v2 = vmlal_u16(v_v2, vget_low_u16(v_col1), ((uint16x4_t){24u, 23u, 22u, 21u})); v_v2 = vmlal_u16(v_v2, vget_high_u16(v_col1), ((uint16x4_t){20u, 19u, 18u, 17u})); v_v2 = vmlal_u16(v_v2, vget_low_u16(v_col2), ((uint16x4_t){16u, 15u, 14u, 13u})); v_v2 = vmlal_u16(v_v2, vget_high_u16(v_col2), ((uint16x4_t){12u, 11u, 10u, 9u})); v_v2 = vmlal_u16(v_v2, vget_low_u16(v_col3), ((uint16x4_t){8u, 7u, 6u, 5u})); v_v2 = vmlal_u16(v_v2, vget_high_u16(v_col3), ((uint16x4_t){4u, 3u, 2u, 1u})); v_sum1 = vpadd_u32(vget_low_u32(v_v1), vget_high_u32(v_v1)); v_sum2 = vpadd_u32(vget_low_u32(v_v2), vget_high_u32(v_v2)); v_sum12 = vpadd_u32(v_sum1, v_sum2); v_s1 += vget_lane_u32(v_sum12, 0u); v_s2 += vget_lane_u32(v_sum12, 1u); v_tail_index = (((uint64_t)(a_x.len)) & 18446744073709551584u); if (v_tail_index < ((uint64_t)(a_x.len))) { { wuffs_base__slice_u8 i_slice_p = wuffs_base__slice_u8__subslice_i(a_x, v_tail_index); v_p.ptr = i_slice_p.ptr; v_p.len = 1; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end0_p) { v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; } v_p.len = 0; } } v_s1 %= 65521u; v_s2 %= 65521u; a_x = v_remaining; } self->private_impl.f_state = (((v_s2 & 65535u) << 16u) | (v_s1 & 65535u)); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) // ‼ WUFFS MULTI-FILE SECTION -arm_neon // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func adler32.hasher.up_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_adler32__hasher__up_x86_sse42( wuffs_adler32__hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_s1 = 0; uint32_t v_s2 = 0; wuffs_base__slice_u8 v_remaining = {0}; wuffs_base__slice_u8 v_p = {0}; __m128i v_zeroes = {0}; __m128i v_ones = {0}; __m128i v_weights__left = {0}; __m128i v_weights_right = {0}; __m128i v_q__left = {0}; __m128i v_q_right = {0}; __m128i v_v1 = {0}; __m128i v_v2 = {0}; __m128i v_v2j = {0}; __m128i v_v2k = {0}; uint32_t v_num_iterate_bytes = 0; uint64_t v_tail_index = 0; v_zeroes = _mm_set1_epi16((int16_t)(0u)); v_ones = _mm_set1_epi16((int16_t)(1u)); v_weights__left = _mm_set_epi8((int8_t)(17u), (int8_t)(18u), (int8_t)(19u), (int8_t)(20u), (int8_t)(21u), (int8_t)(22u), (int8_t)(23u), (int8_t)(24u), (int8_t)(25u), (int8_t)(26u), (int8_t)(27u), (int8_t)(28u), (int8_t)(29u), (int8_t)(30u), (int8_t)(31u), (int8_t)(32u)); v_weights_right = _mm_set_epi8((int8_t)(1u), (int8_t)(2u), (int8_t)(3u), (int8_t)(4u), (int8_t)(5u), (int8_t)(6u), (int8_t)(7u), (int8_t)(8u), (int8_t)(9u), (int8_t)(10u), (int8_t)(11u), (int8_t)(12u), (int8_t)(13u), (int8_t)(14u), (int8_t)(15u), (int8_t)(16u)); v_s1 = ((self->private_impl.f_state) & 0xFFFFu); v_s2 = ((self->private_impl.f_state) >> (32u - 16u)); while (((uint64_t)(a_x.len)) > 0u) { v_remaining = wuffs_base__slice_u8__subslice_j(a_x, 0u); if (((uint64_t)(a_x.len)) > 5536u) { v_remaining = wuffs_base__slice_u8__subslice_i(a_x, 5536u); a_x = wuffs_base__slice_u8__subslice_j(a_x, 5536u); } v_num_iterate_bytes = ((uint32_t)((((uint64_t)(a_x.len)) & 4294967264u))); v_s2 += ((uint32_t)(v_s1 * v_num_iterate_bytes)); v_v1 = _mm_setzero_si128(); v_v2j = _mm_setzero_si128(); v_v2k = _mm_setzero_si128(); { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 32; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 32) * 32)); while (v_p.ptr < i_end0_p) { v_q__left = _mm_lddqu_si128((const __m128i*)(const void*)(v_p.ptr)); v_q_right = _mm_lddqu_si128((const __m128i*)(const void*)(v_p.ptr + 16u)); v_v2j = _mm_add_epi32(v_v2j, v_v1); v_v1 = _mm_add_epi32(v_v1, _mm_sad_epu8(v_q__left, v_zeroes)); v_v1 = _mm_add_epi32(v_v1, _mm_sad_epu8(v_q_right, v_zeroes)); v_v2k = _mm_add_epi32(v_v2k, _mm_madd_epi16(v_ones, _mm_maddubs_epi16(v_q__left, v_weights__left))); v_v2k = _mm_add_epi32(v_v2k, _mm_madd_epi16(v_ones, _mm_maddubs_epi16(v_q_right, v_weights_right))); v_p.ptr += 32; } v_p.len = 0; } v_v1 = _mm_add_epi32(v_v1, _mm_shuffle_epi32(v_v1, (int32_t)(177u))); v_v1 = _mm_add_epi32(v_v1, _mm_shuffle_epi32(v_v1, (int32_t)(78u))); v_s1 += ((uint32_t)(_mm_cvtsi128_si32(v_v1))); v_v2 = _mm_add_epi32(v_v2k, _mm_slli_epi32(v_v2j, (int32_t)(5u))); v_v2 = _mm_add_epi32(v_v2, _mm_shuffle_epi32(v_v2, (int32_t)(177u))); v_v2 = _mm_add_epi32(v_v2, _mm_shuffle_epi32(v_v2, (int32_t)(78u))); v_s2 += ((uint32_t)(_mm_cvtsi128_si32(v_v2))); v_tail_index = (((uint64_t)(a_x.len)) & 18446744073709551584u); if (v_tail_index < ((uint64_t)(a_x.len))) { { wuffs_base__slice_u8 i_slice_p = wuffs_base__slice_u8__subslice_i(a_x, v_tail_index); v_p.ptr = i_slice_p.ptr; v_p.len = 1; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end0_p) { v_s1 += ((uint32_t)(v_p.ptr[0u])); v_s2 += v_s1; v_p.ptr += 1; } v_p.len = 0; } } v_s1 %= 65521u; v_s2 %= 65521u; a_x = v_remaining; } self->private_impl.f_state = (((v_s2 & 65535u) << 16u) | (v_s1 & 65535u)); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ADLER32) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BMP) // ---------------- Status Codes Implementations const char wuffs_bmp__error__bad_header[] = "#bmp: bad header"; const char wuffs_bmp__error__bad_rle_compression[] = "#bmp: bad RLE compression"; const char wuffs_bmp__error__truncated_input[] = "#bmp: truncated input"; const char wuffs_bmp__error__unsupported_bmp_file[] = "#bmp: unsupported BMP file"; const char wuffs_bmp__note__internal_note_short_read[] = "@bmp: internal note: short read"; // ---------------- Private Consts #define WUFFS_BMP__COMPRESSION_NONE 0u #define WUFFS_BMP__COMPRESSION_RLE8 1u #define WUFFS_BMP__COMPRESSION_RLE4 2u #define WUFFS_BMP__COMPRESSION_BITFIELDS 3u #define WUFFS_BMP__COMPRESSION_JPEG 4u #define WUFFS_BMP__COMPRESSION_PNG 5u #define WUFFS_BMP__COMPRESSION_ALPHABITFIELDS 6u #define WUFFS_BMP__COMPRESSION_LOW_BIT_DEPTH 256u #define WUFFS_BMP__RLE_STATE_NEUTRAL 0u #define WUFFS_BMP__RLE_STATE_RUN 1u #define WUFFS_BMP__RLE_STATE_ESCAPE 2u #define WUFFS_BMP__RLE_STATE_LITERAL 3u #define WUFFS_BMP__RLE_STATE_DELTA_X 4u #define WUFFS_BMP__RLE_STATE_DELTA_Y 5u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_image_config( wuffs_bmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_frame_config( wuffs_bmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_frame( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_none( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_rle( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_bitfields( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_low_bit_depth( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_tell_me_more( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__read_palette( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__process_masks( wuffs_bmp__decoder* self); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_bmp__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_bmp__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_bmp__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_bmp__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_bmp__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_bmp__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_bmp__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_bmp__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_bmp__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_bmp__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_bmp__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_bmp__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_bmp__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_bmp__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_bmp__decoder__initialize( wuffs_bmp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_bmp__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_bmp__decoder* wuffs_bmp__decoder__alloc(void) { wuffs_bmp__decoder* x = (wuffs_bmp__decoder*)(calloc(1, sizeof(wuffs_bmp__decoder))); if (!x) { return NULL; } if (wuffs_bmp__decoder__initialize( x, sizeof(wuffs_bmp__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_bmp__decoder(void) { return sizeof(wuffs_bmp__decoder); } // ---------------- Function Implementations // -------- func bmp.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__get_quirk( const wuffs_bmp__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func bmp.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__set_quirk( wuffs_bmp__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func bmp.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_image_config( wuffs_bmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_bmp__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_bmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func bmp.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_image_config( wuffs_bmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_magic = 0; uint32_t v_width = 0; uint32_t v_height = 0; uint32_t v_planes = 0; uint32_t v_n = 0; uint32_t v_dst_pixfmt = 0; uint32_t v_byte_width = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_call_sequence != 0u) || (self->private_impl.f_io_redirect_fourcc == 1u)) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if (self->private_impl.f_io_redirect_fourcc != 0u) { status = wuffs_base__make_status(wuffs_base__note__i_o_redirect); goto ok; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 8) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_magic = t_0; } if (v_magic != 19778u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } self->private_data.s_do_decode_image_config.scratch = 8u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } self->private_impl.f_padding = t_1; } if (self->private_impl.f_padding < 14u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } self->private_impl.f_padding -= 14u; self->private_impl.f_io_redirect_pos = wuffs_base__u64__sat_add(((uint64_t)(self->private_impl.f_padding)), wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } self->private_impl.f_bitmap_info_len = t_2; } if (self->private_impl.f_padding < self->private_impl.f_bitmap_info_len) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } self->private_impl.f_padding -= self->private_impl.f_bitmap_info_len; if (self->private_impl.f_bitmap_info_len == 12u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_3 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 8) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } self->private_impl.f_width = t_3; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 8) { t_4 = ((uint32_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } self->private_impl.f_height = t_4; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); uint32_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_5 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_5; if (num_bits_5 == 8) { t_5 = ((uint32_t)(*scratch)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)) << 56; } } v_planes = t_5; } if (v_planes != 1u) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); uint32_t t_6; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_6 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_6 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_6; if (num_bits_6 == 8) { t_6 = ((uint32_t)(*scratch)); break; } num_bits_6 += 8u; *scratch |= ((uint64_t)(num_bits_6)) << 56; } } self->private_impl.f_bits_per_pixel = t_6; } } else if (self->private_impl.f_bitmap_info_len == 16u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); uint32_t t_7; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_7 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(17); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_7 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_7; if (num_bits_7 == 24) { t_7 = ((uint32_t)(*scratch)); break; } num_bits_7 += 8u; *scratch |= ((uint64_t)(num_bits_7)) << 56; } } v_width = t_7; } if (v_width > 2147483647u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } else if (v_width > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_width = v_width; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(18); uint32_t t_8; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_8 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(19); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_8 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_8; if (num_bits_8 == 24) { t_8 = ((uint32_t)(*scratch)); break; } num_bits_8 += 8u; *scratch |= ((uint64_t)(num_bits_8)) << 56; } } v_height = t_8; } if (v_height > 2147483647u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } else if (v_height > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_height = v_height; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(20); uint32_t t_9; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_9 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(21); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_9 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_9; if (num_bits_9 == 8) { t_9 = ((uint32_t)(*scratch)); break; } num_bits_9 += 8u; *scratch |= ((uint64_t)(num_bits_9)) << 56; } } v_planes = t_9; } if (v_planes != 1u) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(22); uint32_t t_10; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_10 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(23); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_10 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_10; if (num_bits_10 == 8) { t_10 = ((uint32_t)(*scratch)); break; } num_bits_10 += 8u; *scratch |= ((uint64_t)(num_bits_10)) << 56; } } self->private_impl.f_bits_per_pixel = t_10; } } else { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(24); uint32_t t_11; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_11 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(25); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_11 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_11; if (num_bits_11 == 24) { t_11 = ((uint32_t)(*scratch)); break; } num_bits_11 += 8u; *scratch |= ((uint64_t)(num_bits_11)) << 56; } } v_width = t_11; } if (v_width > 2147483647u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } else if (v_width > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_width = v_width; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(26); uint32_t t_12; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_12 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(27); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_12 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_12; if (num_bits_12 == 24) { t_12 = ((uint32_t)(*scratch)); break; } num_bits_12 += 8u; *scratch |= ((uint64_t)(num_bits_12)) << 56; } } v_height = t_12; } if (v_height == 2147483648u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } else if (v_height > 2147483648u) { v_height = ((uint32_t)(0u - v_height)); if (v_height > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_height = v_height; self->private_impl.f_top_down = true; } else if (v_height > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } else { self->private_impl.f_height = v_height; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(28); uint32_t t_13; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_13 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(29); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_13 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_13; if (num_bits_13 == 8) { t_13 = ((uint32_t)(*scratch)); break; } num_bits_13 += 8u; *scratch |= ((uint64_t)(num_bits_13)) << 56; } } v_planes = t_13; } if (v_planes != 1u) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(30); uint32_t t_14; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_14 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(31); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_14 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_14; if (num_bits_14 == 8) { t_14 = ((uint32_t)(*scratch)); break; } num_bits_14 += 8u; *scratch |= ((uint64_t)(num_bits_14)) << 56; } } self->private_impl.f_bits_per_pixel = t_14; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(32); uint32_t t_15; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_15 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(33); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_15 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_15; if (num_bits_15 == 24) { t_15 = ((uint32_t)(*scratch)); break; } num_bits_15 += 8u; *scratch |= ((uint64_t)(num_bits_15)) << 56; } } self->private_impl.f_compression = t_15; } if (self->private_impl.f_bits_per_pixel == 0u) { if (self->private_impl.f_compression == 4u) { self->private_impl.f_io_redirect_fourcc = 1246774599u; status = wuffs_base__make_status(wuffs_base__note__i_o_redirect); goto ok; } else if (self->private_impl.f_compression == 5u) { self->private_impl.f_io_redirect_fourcc = 1347307296u; status = wuffs_base__make_status(wuffs_base__note__i_o_redirect); goto ok; } status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } self->private_data.s_do_decode_image_config.scratch = 20u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(34); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; if (self->private_impl.f_bitmap_info_len == 40u) { if (self->private_impl.f_bits_per_pixel >= 16u) { if (self->private_impl.f_padding >= 16u) { self->private_impl.f_bitmap_info_len = 56u; self->private_impl.f_padding -= 16u; } else if (self->private_impl.f_padding >= 12u) { self->private_impl.f_bitmap_info_len = 52u; self->private_impl.f_padding -= 12u; } } } else if ((self->private_impl.f_bitmap_info_len != 52u) && (self->private_impl.f_bitmap_info_len != 56u) && (self->private_impl.f_bitmap_info_len != 64u) && (self->private_impl.f_bitmap_info_len != 108u) && (self->private_impl.f_bitmap_info_len != 124u)) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } if (self->private_impl.f_compression == 6u) { self->private_impl.f_compression = 3u; } if (self->private_impl.f_compression == 3u) { if (self->private_impl.f_bitmap_info_len >= 52u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(35); uint32_t t_16; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_16 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(36); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_16 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_16; if (num_bits_16 == 24) { t_16 = ((uint32_t)(*scratch)); break; } num_bits_16 += 8u; *scratch |= ((uint64_t)(num_bits_16)) << 56; } } self->private_impl.f_channel_masks[2u] = t_16; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(37); uint32_t t_17; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_17 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(38); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_17 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_17; if (num_bits_17 == 24) { t_17 = ((uint32_t)(*scratch)); break; } num_bits_17 += 8u; *scratch |= ((uint64_t)(num_bits_17)) << 56; } } self->private_impl.f_channel_masks[1u] = t_17; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(39); uint32_t t_18; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_18 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(40); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_18 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_18; if (num_bits_18 == 24) { t_18 = ((uint32_t)(*scratch)); break; } num_bits_18 += 8u; *scratch |= ((uint64_t)(num_bits_18)) << 56; } } self->private_impl.f_channel_masks[0u] = t_18; } if (self->private_impl.f_bitmap_info_len >= 56u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(41); uint32_t t_19; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_19 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(42); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_19 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_19; if (num_bits_19 == 24) { t_19 = ((uint32_t)(*scratch)); break; } num_bits_19 += 8u; *scratch |= ((uint64_t)(num_bits_19)) << 56; } } self->private_impl.f_channel_masks[3u] = t_19; } self->private_data.s_do_decode_image_config.scratch = ((uint32_t)(self->private_impl.f_bitmap_info_len - 56u)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(43); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; } if ((self->private_impl.f_channel_masks[0u] == 255u) && (self->private_impl.f_channel_masks[1u] == 65280u) && (self->private_impl.f_channel_masks[2u] == 16711680u)) { if (self->private_impl.f_bits_per_pixel == 24u) { self->private_impl.f_compression = 0u; } else if (self->private_impl.f_bits_per_pixel == 32u) { if ((self->private_impl.f_channel_masks[3u] == 0u) || (self->private_impl.f_channel_masks[3u] == 4278190080u)) { self->private_impl.f_compression = 0u; } } } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(44); status = wuffs_bmp__decoder__process_masks(self); if (status.repr) { goto suspend; } } } else if (self->private_impl.f_bitmap_info_len >= 40u) { v_n = (self->private_impl.f_bitmap_info_len - 40u); self->private_data.s_do_decode_image_config.scratch = v_n; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(45); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } } if (self->private_impl.f_compression != 3u) { if (self->private_impl.f_bits_per_pixel < 16u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(46); status = wuffs_bmp__decoder__read_palette(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } } if (self->private_impl.f_compression == 0u) { if ((self->private_impl.f_bits_per_pixel == 1u) || (self->private_impl.f_bits_per_pixel == 2u) || (self->private_impl.f_bits_per_pixel == 4u)) { self->private_impl.f_src_pixfmt = 2198077448u; self->private_impl.f_compression = 256u; } else if (self->private_impl.f_bits_per_pixel == 8u) { self->private_impl.f_src_pixfmt = 2198077448u; } else if (self->private_impl.f_bits_per_pixel == 16u) { self->private_impl.f_compression = 3u; self->private_impl.f_channel_masks[0u] = 31u; self->private_impl.f_channel_masks[1u] = 992u; self->private_impl.f_channel_masks[2u] = 31744u; self->private_impl.f_channel_masks[3u] = 0u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(47); status = wuffs_bmp__decoder__process_masks(self); if (status.repr) { goto suspend; } self->private_impl.f_src_pixfmt = 2164308923u; } else if (self->private_impl.f_bits_per_pixel == 24u) { self->private_impl.f_src_pixfmt = 2147485832u; } else if (self->private_impl.f_bits_per_pixel == 32u) { if (self->private_impl.f_channel_masks[3u] == 0u) { self->private_impl.f_src_pixfmt = 2415954056u; } else { self->private_impl.f_src_pixfmt = 2164295816u; } } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } } else if (self->private_impl.f_compression == 1u) { if (self->private_impl.f_bits_per_pixel == 8u) { self->private_impl.f_src_pixfmt = 2198077448u; } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } } else if (self->private_impl.f_compression == 2u) { if (self->private_impl.f_bits_per_pixel == 4u) { self->private_impl.f_src_pixfmt = 2198077448u; } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } } else if (self->private_impl.f_compression == 3u) { if ((self->private_impl.f_bits_per_pixel == 16u) || (self->private_impl.f_bits_per_pixel == 32u)) { self->private_impl.f_src_pixfmt = 2164308923u; } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } } else { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } if (((self->private_impl.f_bitmap_info_len < 40u) || (self->private_impl.f_bitmap_info_len == 64u)) && (self->private_impl.f_bits_per_pixel != 1u) && (self->private_impl.f_bits_per_pixel != 4u) && (self->private_impl.f_bits_per_pixel != 8u) && (self->private_impl.f_bits_per_pixel != 24u)) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } if (self->private_impl.f_bits_per_pixel == 1u) { v_byte_width = ((self->private_impl.f_width >> 3u) + (((self->private_impl.f_width & 7u) + 7u) >> 3u)); self->private_impl.f_pad_per_row = ((4u - (v_byte_width & 3u)) & 3u); } else if (self->private_impl.f_bits_per_pixel == 2u) { v_byte_width = ((self->private_impl.f_width >> 2u) + (((self->private_impl.f_width & 3u) + 3u) >> 2u)); self->private_impl.f_pad_per_row = ((4u - (v_byte_width & 3u)) & 3u); } else if (self->private_impl.f_bits_per_pixel == 4u) { v_byte_width = ((self->private_impl.f_width >> 1u) + (self->private_impl.f_width & 1u)); self->private_impl.f_pad_per_row = ((4u - (v_byte_width & 3u)) & 3u); } else if (self->private_impl.f_bits_per_pixel == 8u) { self->private_impl.f_pad_per_row = ((4u - (self->private_impl.f_width & 3u)) & 3u); } else if (self->private_impl.f_bits_per_pixel == 16u) { self->private_impl.f_pad_per_row = ((self->private_impl.f_width & 1u) * 2u); } else if (self->private_impl.f_bits_per_pixel == 24u) { self->private_impl.f_pad_per_row = (self->private_impl.f_width & 3u); } else if (self->private_impl.f_bits_per_pixel == 32u) { self->private_impl.f_pad_per_row = 0u; } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { v_dst_pixfmt = 2164295816u; if ((self->private_impl.f_channel_num_bits[0u] > 8u) || (self->private_impl.f_channel_num_bits[1u] > 8u) || (self->private_impl.f_channel_num_bits[2u] > 8u) || (self->private_impl.f_channel_num_bits[3u] > 8u)) { v_dst_pixfmt = 2164308923u; } else if (((self->private_impl.f_src_pixfmt == 2198077448u) || (self->private_impl.f_src_pixfmt == 2147485832u) || (self->private_impl.f_src_pixfmt == 2415954056u)) || ((self->private_impl.f_src_pixfmt == 2164308923u) && (self->private_impl.f_channel_masks[3u] == 0u))) { v_dst_pixfmt = 2415954056u; } wuffs_base__image_config__set( a_dst, v_dst_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, (self->private_impl.f_channel_masks[3u] == 0u)); } self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_frame_config( wuffs_bmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_bmp__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_bmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func bmp.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_frame_config( wuffs_bmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_bmp__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, true, false, 4278190080u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__decode_frame( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_bmp__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_bmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func bmp.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_decode_frame( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_bmp__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } self->private_data.s_do_decode_frame.scratch = self->private_impl.f_padding; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (self->private_data.s_do_decode_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame.scratch; if ((self->private_impl.f_width > 0u) && (self->private_impl.f_height > 0u)) { self->private_impl.f_dst_x = 0u; if (self->private_impl.f_top_down) { self->private_impl.f_dst_y = 0u; self->private_impl.f_dst_y_inc = 1u; } else { self->private_impl.f_dst_y = ((uint32_t)(self->private_impl.f_height - 1u)); self->private_impl.f_dst_y_inc = 4294967295u; } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_scratch, 1024, 2048)), wuffs_base__utility__make_pixel_format(self->private_impl.f_src_pixfmt), wuffs_base__make_slice_u8(self->private_data.f_src_palette, 1024), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } while (true) { if (self->private_impl.f_compression == 0u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_bmp__decoder__swizzle_none(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } else if (self->private_impl.f_compression < 3u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_bmp__decoder__swizzle_rle(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } else if (self->private_impl.f_compression == 3u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_bmp__decoder__swizzle_bitfields(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } else { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_bmp__decoder__swizzle_low_bit_depth(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_ok(&v_status)) { break; } else if (v_status.repr != wuffs_bmp__note__internal_note_short_read) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); } self->private_data.s_do_decode_frame.scratch = self->private_impl.f_pending_pad; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (self->private_data.s_do_decode_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame.scratch; self->private_impl.f_pending_pad = 0u; } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.swizzle_none WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_none( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; uint32_t v_src_bytes_per_pixel = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_j = 0; uint64_t v_n = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_scratch, 1024, 2048)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); label__outer__continue:; while (true) { while (self->private_impl.f_pending_pad > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } self->private_impl.f_pending_pad -= 1u; iop_a_src += 1u; } while (true) { if (self->private_impl.f_dst_x == self->private_impl.f_width) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { if (self->private_impl.f_height > 0u) { self->private_impl.f_pending_pad = self->private_impl.f_pad_per_row; } goto label__outer__break; } else if (self->private_impl.f_pad_per_row != 0u) { self->private_impl.f_pending_pad = self->private_impl.f_pad_per_row; goto label__outer__continue; } } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i >= ((uint64_t)(v_dst.len))) { if (self->private_impl.f_bits_per_pixel > 32u) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } v_src_bytes_per_pixel = (self->private_impl.f_bits_per_pixel / 8u); if (v_src_bytes_per_pixel == 0u) { status = wuffs_base__make_status(wuffs_bmp__error__unsupported_bmp_file); goto exit; } v_n = (((uint64_t)(io2_a_src - iop_a_src)) / ((uint64_t)(v_src_bytes_per_pixel))); v_n = wuffs_base__u64__min(v_n, ((uint64_t)(((uint32_t)(self->private_impl.f_width - self->private_impl.f_dst_x))))); v_j = v_n; while (v_j >= 8u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 8u)))) { iop_a_src += (v_src_bytes_per_pixel * 8u); } v_j -= 8u; } while (v_j > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 1u)))) { iop_a_src += (v_src_bytes_per_pixel * 1u); } v_j -= 1u; } } else { v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_reader( &self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, &iop_a_src, io2_a_src); } if (v_n == 0u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); } } label__outer__break:; status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.swizzle_rle WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_rle( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_row = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_n = 0; uint32_t v_p0 = 0; uint8_t v_code = 0; uint8_t v_indexes[2] = {0}; uint32_t v_rle_state = 0; uint32_t v_chunk_bits = 0; uint32_t v_chunk_count = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_scratch, 1024, 2048)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_rle_state = self->private_impl.f_rle_state; label__outer__continue:; while (true) { v_row = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_row.len))) { v_row = wuffs_base__slice_u8__subslice_j(v_row, v_dst_bytes_per_row); } label__middle__continue:; while (true) { v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i <= ((uint64_t)(v_row.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_row, v_i); } else { v_dst = wuffs_base__utility__empty_slice_u8(); } while (true) { if (v_rle_state == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } v_code = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; if (v_code == 0u) { v_rle_state = 2u; continue; } self->private_impl.f_rle_length = ((uint32_t)(v_code)); v_rle_state = 1u; continue; } else if (v_rle_state == 1u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } v_code = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; if (self->private_impl.f_bits_per_pixel == 8u) { v_p0 = 0u; while (v_p0 < self->private_impl.f_rle_length) { self->private_data.f_scratch[v_p0] = v_code; v_p0 += 1u; } } else { v_indexes[0u] = ((uint8_t)(((uint8_t)(v_code >> 4u)))); v_indexes[1u] = ((uint8_t)(v_code & 15u)); v_p0 = 0u; while (v_p0 < self->private_impl.f_rle_length) { self->private_data.f_scratch[(v_p0 + 0u)] = v_indexes[0u]; self->private_data.f_scratch[(v_p0 + 1u)] = v_indexes[1u]; v_p0 += 2u; } } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, self->private_impl.f_rle_length)); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, self->private_impl.f_rle_length); v_rle_state = 0u; goto label__middle__continue; } else if (v_rle_state == 2u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } v_code = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; if (v_code < 2u) { if ((self->private_impl.f_dst_y >= self->private_impl.f_height) && (v_code == 0u)) { status = wuffs_base__make_status(wuffs_bmp__error__bad_rle_compression); goto exit; } wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black(&self->private_impl.f_swizzler, v_dst, v_dst_palette, 18446744073709551615u); self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; if (v_code > 0u) { goto label__outer__break; } v_rle_state = 0u; goto label__outer__continue; } else if (v_code == 2u) { v_rle_state = 4u; continue; } self->private_impl.f_rle_length = ((uint32_t)(v_code)); self->private_impl.f_rle_padded = ((self->private_impl.f_bits_per_pixel == 8u) && (((uint8_t)(v_code & 1u)) != 0u)); v_rle_state = 3u; continue; } else if (v_rle_state == 3u) { if (self->private_impl.f_bits_per_pixel == 8u) { v_n = wuffs_base__pixel_swizzler__limited_swizzle_u32_interleaved_from_reader( &self->private_impl.f_swizzler, self->private_impl.f_rle_length, v_dst, v_dst_palette, &iop_a_src, io2_a_src); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_rle_length, ((uint32_t)(v_n))); } else { v_chunk_count = ((self->private_impl.f_rle_length + 3u) / 4u); v_p0 = 0u; while ((v_chunk_count > 0u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 2u)) { v_chunk_bits = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2u; self->private_data.f_scratch[(v_p0 + 0u)] = ((uint8_t)((15u & (v_chunk_bits >> 12u)))); self->private_data.f_scratch[(v_p0 + 1u)] = ((uint8_t)((15u & (v_chunk_bits >> 8u)))); self->private_data.f_scratch[(v_p0 + 2u)] = ((uint8_t)((15u & (v_chunk_bits >> 4u)))); self->private_data.f_scratch[(v_p0 + 3u)] = ((uint8_t)((15u & (v_chunk_bits >> 0u)))); v_p0 = ((v_p0 & 255u) + 4u); v_chunk_count -= 1u; } v_p0 = wuffs_base__u32__min(v_p0, self->private_impl.f_rle_length); wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, v_p0)); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, v_p0); wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_rle_length, v_p0); } if (self->private_impl.f_rle_length > 0u) { break; } if (self->private_impl.f_rle_padded) { if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } iop_a_src += 1u; self->private_impl.f_rle_padded = false; } v_rle_state = 0u; goto label__middle__continue; } else if (v_rle_state == 4u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } self->private_impl.f_rle_delta_x = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_rle_state = 5u; continue; } if (((uint64_t)(io2_a_src - iop_a_src)) < 1u) { break; } v_code = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; if (self->private_impl.f_rle_delta_x > 0u) { wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black(&self->private_impl.f_swizzler, v_dst, v_dst_palette, ((uint64_t)(self->private_impl.f_rle_delta_x))); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(self->private_impl.f_rle_delta_x))); self->private_impl.f_rle_delta_x = 0u; if (self->private_impl.f_dst_x > self->private_impl.f_width) { status = wuffs_base__make_status(wuffs_bmp__error__bad_rle_compression); goto exit; } } if (v_code > 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_code -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif while (true) { self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { status = wuffs_base__make_status(wuffs_bmp__error__bad_rle_compression); goto exit; } v_row = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_row.len))) { v_row = wuffs_base__slice_u8__subslice_j(v_row, v_dst_bytes_per_row); } if (v_code <= 0u) { wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black(&self->private_impl.f_swizzler, v_row, v_dst_palette, ((uint64_t)(self->private_impl.f_dst_x))); break; } wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black(&self->private_impl.f_swizzler, v_row, v_dst_palette, 18446744073709551615u); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_code -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } } v_rle_state = 0u; goto label__middle__continue; } self->private_impl.f_rle_state = v_rle_state; status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } } label__outer__break:; while (self->private_impl.f_dst_y < self->private_impl.f_height) { v_row = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_row.len))) { v_row = wuffs_base__slice_u8__subslice_j(v_row, v_dst_bytes_per_row); } wuffs_base__pixel_swizzler__swizzle_interleaved_transparent_black(&self->private_impl.f_swizzler, v_row, v_dst_palette, 18446744073709551615u); self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; } status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.swizzle_bitfields WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_bitfields( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_n = 0; uint32_t v_p0 = 0; uint32_t v_p1 = 0; uint32_t v_p1_temp = 0; uint32_t v_num_bits = 0; uint32_t v_c = 0; uint32_t v_c32 = 0; uint32_t v_channel = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_scratch, 1024, 2048)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); label__outer__continue:; while (true) { while (self->private_impl.f_pending_pad > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } self->private_impl.f_pending_pad -= 1u; iop_a_src += 1u; } while (true) { if (self->private_impl.f_dst_x == self->private_impl.f_width) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { if (self->private_impl.f_height > 0u) { self->private_impl.f_pending_pad = self->private_impl.f_pad_per_row; } goto label__outer__break; } else if (self->private_impl.f_pad_per_row != 0u) { self->private_impl.f_pending_pad = self->private_impl.f_pad_per_row; goto label__outer__continue; } } v_p1_temp = ((uint32_t)(self->private_impl.f_width - self->private_impl.f_dst_x)); v_p1 = wuffs_base__u32__min(v_p1_temp, 256u); v_p0 = 0u; while (v_p0 < v_p1) { if (self->private_impl.f_bits_per_pixel == 16u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { break; } v_c32 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2u; } else { if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { break; } v_c32 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4u; } v_channel = 0u; while (v_channel < 4u) { if (self->private_impl.f_channel_num_bits[v_channel] == 0u) { self->private_data.f_scratch[((8u * v_p0) + (2u * v_channel) + 0u)] = 255u; self->private_data.f_scratch[((8u * v_p0) + (2u * v_channel) + 1u)] = 255u; } else { v_c = ((v_c32 & self->private_impl.f_channel_masks[v_channel]) >> self->private_impl.f_channel_shifts[v_channel]); v_num_bits = ((uint32_t)(self->private_impl.f_channel_num_bits[v_channel])); while (v_num_bits < 16u) { v_c |= ((uint32_t)(v_c << v_num_bits)); v_num_bits *= 2u; } v_c >>= (v_num_bits - 16u); self->private_data.f_scratch[((8u * v_p0) + (2u * v_channel) + 0u)] = ((uint8_t)((v_c >> 0u))); self->private_data.f_scratch[((8u * v_p0) + (2u * v_channel) + 1u)] = ((uint8_t)((v_c >> 8u))); } v_channel += 1u; } v_p0 += 1u; } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i >= ((uint64_t)(v_dst.len))) { v_n = ((uint64_t)(v_p0)); } else { v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, (8u * v_p0))); } if (v_n == 0u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); } } label__outer__break:; status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.swizzle_low_bit_depth WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__swizzle_low_bit_depth( wuffs_bmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_n = 0; uint32_t v_p0 = 0; uint32_t v_chunk_bits = 0; uint32_t v_chunk_count = 0; uint32_t v_pixels_per_chunk = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_scratch, 1024, 2048)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); while (true) { if (self->private_impl.f_dst_x == self->private_impl.f_width) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += self->private_impl.f_dst_y_inc; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { break; } } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i >= ((uint64_t)(v_dst.len))) { if (self->private_impl.f_bits_per_pixel == 1u) { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 31u) / 32u); v_pixels_per_chunk = 32u; } else if (self->private_impl.f_bits_per_pixel == 2u) { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 15u) / 16u); v_pixels_per_chunk = 16u; } else { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 7u) / 8u); v_pixels_per_chunk = 8u; } while ((v_chunk_count >= 64u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 256u)) { iop_a_src += 256u; self->private_impl.f_dst_x = wuffs_base__u32__min(self->private_impl.f_width, ((uint32_t)(self->private_impl.f_dst_x + (v_pixels_per_chunk * 64u)))); v_chunk_count -= 64u; } while ((v_chunk_count >= 8u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 32u)) { iop_a_src += 32u; self->private_impl.f_dst_x = wuffs_base__u32__min(self->private_impl.f_width, ((uint32_t)(self->private_impl.f_dst_x + (v_pixels_per_chunk * 8u)))); v_chunk_count -= 8u; } while (v_chunk_count > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } iop_a_src += 4u; self->private_impl.f_dst_x = wuffs_base__u32__min(self->private_impl.f_width, ((uint32_t)(self->private_impl.f_dst_x + (v_pixels_per_chunk * 1u)))); v_chunk_count -= 1u; } continue; } v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_i); v_p0 = 0u; if (self->private_impl.f_bits_per_pixel == 1u) { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 31u) / 32u); v_chunk_count = wuffs_base__u32__min(v_chunk_count, 16u); while ((v_chunk_count > 0u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 4u)) { v_chunk_bits = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4u; self->private_data.f_scratch[(v_p0 + 0u)] = ((uint8_t)((1u & (v_chunk_bits >> 31u)))); self->private_data.f_scratch[(v_p0 + 1u)] = ((uint8_t)((1u & (v_chunk_bits >> 30u)))); self->private_data.f_scratch[(v_p0 + 2u)] = ((uint8_t)((1u & (v_chunk_bits >> 29u)))); self->private_data.f_scratch[(v_p0 + 3u)] = ((uint8_t)((1u & (v_chunk_bits >> 28u)))); self->private_data.f_scratch[(v_p0 + 4u)] = ((uint8_t)((1u & (v_chunk_bits >> 27u)))); self->private_data.f_scratch[(v_p0 + 5u)] = ((uint8_t)((1u & (v_chunk_bits >> 26u)))); self->private_data.f_scratch[(v_p0 + 6u)] = ((uint8_t)((1u & (v_chunk_bits >> 25u)))); self->private_data.f_scratch[(v_p0 + 7u)] = ((uint8_t)((1u & (v_chunk_bits >> 24u)))); self->private_data.f_scratch[(v_p0 + 8u)] = ((uint8_t)((1u & (v_chunk_bits >> 23u)))); self->private_data.f_scratch[(v_p0 + 9u)] = ((uint8_t)((1u & (v_chunk_bits >> 22u)))); self->private_data.f_scratch[(v_p0 + 10u)] = ((uint8_t)((1u & (v_chunk_bits >> 21u)))); self->private_data.f_scratch[(v_p0 + 11u)] = ((uint8_t)((1u & (v_chunk_bits >> 20u)))); self->private_data.f_scratch[(v_p0 + 12u)] = ((uint8_t)((1u & (v_chunk_bits >> 19u)))); self->private_data.f_scratch[(v_p0 + 13u)] = ((uint8_t)((1u & (v_chunk_bits >> 18u)))); self->private_data.f_scratch[(v_p0 + 14u)] = ((uint8_t)((1u & (v_chunk_bits >> 17u)))); self->private_data.f_scratch[(v_p0 + 15u)] = ((uint8_t)((1u & (v_chunk_bits >> 16u)))); self->private_data.f_scratch[(v_p0 + 16u)] = ((uint8_t)((1u & (v_chunk_bits >> 15u)))); self->private_data.f_scratch[(v_p0 + 17u)] = ((uint8_t)((1u & (v_chunk_bits >> 14u)))); self->private_data.f_scratch[(v_p0 + 18u)] = ((uint8_t)((1u & (v_chunk_bits >> 13u)))); self->private_data.f_scratch[(v_p0 + 19u)] = ((uint8_t)((1u & (v_chunk_bits >> 12u)))); self->private_data.f_scratch[(v_p0 + 20u)] = ((uint8_t)((1u & (v_chunk_bits >> 11u)))); self->private_data.f_scratch[(v_p0 + 21u)] = ((uint8_t)((1u & (v_chunk_bits >> 10u)))); self->private_data.f_scratch[(v_p0 + 22u)] = ((uint8_t)((1u & (v_chunk_bits >> 9u)))); self->private_data.f_scratch[(v_p0 + 23u)] = ((uint8_t)((1u & (v_chunk_bits >> 8u)))); self->private_data.f_scratch[(v_p0 + 24u)] = ((uint8_t)((1u & (v_chunk_bits >> 7u)))); self->private_data.f_scratch[(v_p0 + 25u)] = ((uint8_t)((1u & (v_chunk_bits >> 6u)))); self->private_data.f_scratch[(v_p0 + 26u)] = ((uint8_t)((1u & (v_chunk_bits >> 5u)))); self->private_data.f_scratch[(v_p0 + 27u)] = ((uint8_t)((1u & (v_chunk_bits >> 4u)))); self->private_data.f_scratch[(v_p0 + 28u)] = ((uint8_t)((1u & (v_chunk_bits >> 3u)))); self->private_data.f_scratch[(v_p0 + 29u)] = ((uint8_t)((1u & (v_chunk_bits >> 2u)))); self->private_data.f_scratch[(v_p0 + 30u)] = ((uint8_t)((1u & (v_chunk_bits >> 1u)))); self->private_data.f_scratch[(v_p0 + 31u)] = ((uint8_t)((1u & (v_chunk_bits >> 0u)))); v_p0 = ((v_p0 & 511u) + 32u); v_chunk_count -= 1u; } } else if (self->private_impl.f_bits_per_pixel == 2u) { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 15u) / 16u); v_chunk_count = wuffs_base__u32__min(v_chunk_count, 32u); while ((v_chunk_count > 0u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 4u)) { v_chunk_bits = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4u; self->private_data.f_scratch[(v_p0 + 0u)] = ((uint8_t)((3u & (v_chunk_bits >> 30u)))); self->private_data.f_scratch[(v_p0 + 1u)] = ((uint8_t)((3u & (v_chunk_bits >> 28u)))); self->private_data.f_scratch[(v_p0 + 2u)] = ((uint8_t)((3u & (v_chunk_bits >> 26u)))); self->private_data.f_scratch[(v_p0 + 3u)] = ((uint8_t)((3u & (v_chunk_bits >> 24u)))); self->private_data.f_scratch[(v_p0 + 4u)] = ((uint8_t)((3u & (v_chunk_bits >> 22u)))); self->private_data.f_scratch[(v_p0 + 5u)] = ((uint8_t)((3u & (v_chunk_bits >> 20u)))); self->private_data.f_scratch[(v_p0 + 6u)] = ((uint8_t)((3u & (v_chunk_bits >> 18u)))); self->private_data.f_scratch[(v_p0 + 7u)] = ((uint8_t)((3u & (v_chunk_bits >> 16u)))); self->private_data.f_scratch[(v_p0 + 8u)] = ((uint8_t)((3u & (v_chunk_bits >> 14u)))); self->private_data.f_scratch[(v_p0 + 9u)] = ((uint8_t)((3u & (v_chunk_bits >> 12u)))); self->private_data.f_scratch[(v_p0 + 10u)] = ((uint8_t)((3u & (v_chunk_bits >> 10u)))); self->private_data.f_scratch[(v_p0 + 11u)] = ((uint8_t)((3u & (v_chunk_bits >> 8u)))); self->private_data.f_scratch[(v_p0 + 12u)] = ((uint8_t)((3u & (v_chunk_bits >> 6u)))); self->private_data.f_scratch[(v_p0 + 13u)] = ((uint8_t)((3u & (v_chunk_bits >> 4u)))); self->private_data.f_scratch[(v_p0 + 14u)] = ((uint8_t)((3u & (v_chunk_bits >> 2u)))); self->private_data.f_scratch[(v_p0 + 15u)] = ((uint8_t)((3u & (v_chunk_bits >> 0u)))); v_p0 = ((v_p0 & 511u) + 16u); v_chunk_count -= 1u; } } else { v_chunk_count = ((wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x) + 7u) / 8u); v_chunk_count = wuffs_base__u32__min(v_chunk_count, 64u); while ((v_chunk_count > 0u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 4u)) { v_chunk_bits = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4u; self->private_data.f_scratch[(v_p0 + 0u)] = ((uint8_t)((15u & (v_chunk_bits >> 28u)))); self->private_data.f_scratch[(v_p0 + 1u)] = ((uint8_t)((15u & (v_chunk_bits >> 24u)))); self->private_data.f_scratch[(v_p0 + 2u)] = ((uint8_t)((15u & (v_chunk_bits >> 20u)))); self->private_data.f_scratch[(v_p0 + 3u)] = ((uint8_t)((15u & (v_chunk_bits >> 16u)))); self->private_data.f_scratch[(v_p0 + 4u)] = ((uint8_t)((15u & (v_chunk_bits >> 12u)))); self->private_data.f_scratch[(v_p0 + 5u)] = ((uint8_t)((15u & (v_chunk_bits >> 8u)))); self->private_data.f_scratch[(v_p0 + 6u)] = ((uint8_t)((15u & (v_chunk_bits >> 4u)))); self->private_data.f_scratch[(v_p0 + 7u)] = ((uint8_t)((15u & (v_chunk_bits >> 0u)))); v_p0 = ((v_p0 & 511u) + 8u); v_chunk_count -= 1u; } } v_p0 = wuffs_base__u32__min(v_p0, wuffs_base__u32__sat_sub(self->private_impl.f_width, self->private_impl.f_dst_x)); v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, v_p0)); if (v_n == 0u) { status = wuffs_base__make_status(wuffs_bmp__note__internal_note_short_read); goto ok; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); } status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_bmp__decoder__frame_dirty_rect( const wuffs_bmp__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func bmp.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_bmp__decoder__num_animation_loops( const wuffs_bmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func bmp.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__num_decoded_frame_configs( const wuffs_bmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func bmp.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bmp__decoder__num_decoded_frames( const wuffs_bmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func bmp.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__restart_frame( wuffs_bmp__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if (a_index != 0u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; self->private_impl.f_frame_config_io_position = a_io_position; return wuffs_base__make_status(NULL); } // -------- func bmp.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_bmp__decoder__set_report_metadata( wuffs_bmp__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func bmp.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bmp__decoder__tell_me_more( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_tell_me_more; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_bmp__decoder__do_tell_me_more(self, a_dst, a_minfo, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_bmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_tell_me_more = 0; goto exit; } goto suspend; suspend: self->private_impl.p_tell_me_more = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 4 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func bmp.decoder.do_tell_me_more WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__do_tell_me_more( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); if (self->private_impl.f_io_redirect_fourcc <= 1u) { status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; } if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, 1u, self->private_impl.f_io_redirect_fourcc, 0u, self->private_impl.f_io_redirect_pos, 18446744073709551615u); } self->private_impl.f_io_redirect_fourcc = 1u; goto ok; ok: goto exit; exit: return status; } // -------- func bmp.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_bmp__decoder__workbuf_len( const wuffs_bmp__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } // -------- func bmp.decoder.read_palette WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__read_palette( wuffs_bmp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_i = 0; uint32_t v_argb = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_read_palette; if (coro_susp_point) { v_i = self->private_data.s_read_palette.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_bitmap_info_len == 12u) { while ((v_i < 256u) && (self->private_impl.f_padding >= 3u)) { self->private_impl.f_padding -= 3u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 3)) { t_0 = ((uint32_t)(wuffs_base__peek_u24le__no_bounds_check(iop_a_src))); iop_a_src += 3; } else { self->private_data.s_read_palette.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_read_palette.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 16) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_argb = t_0; } v_argb |= 4278190080u; self->private_data.f_src_palette[((4u * v_i) + 0u)] = ((uint8_t)((v_argb >> 0u))); self->private_data.f_src_palette[((4u * v_i) + 1u)] = ((uint8_t)((v_argb >> 8u))); self->private_data.f_src_palette[((4u * v_i) + 2u)] = ((uint8_t)((v_argb >> 16u))); self->private_data.f_src_palette[((4u * v_i) + 3u)] = ((uint8_t)((v_argb >> 24u))); v_i += 1u; } } else { while ((v_i < 256u) && (self->private_impl.f_padding >= 4u)) { self->private_impl.f_padding -= 4u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_read_palette.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_read_palette.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_argb = t_1; } v_argb |= 4278190080u; self->private_data.f_src_palette[((4u * v_i) + 0u)] = ((uint8_t)((v_argb >> 0u))); self->private_data.f_src_palette[((4u * v_i) + 1u)] = ((uint8_t)((v_argb >> 8u))); self->private_data.f_src_palette[((4u * v_i) + 2u)] = ((uint8_t)((v_argb >> 16u))); self->private_data.f_src_palette[((4u * v_i) + 3u)] = ((uint8_t)((v_argb >> 24u))); v_i += 1u; } } while (v_i < 256u) { self->private_data.f_src_palette[((4u * v_i) + 0u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 1u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 2u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 3u)] = 255u; v_i += 1u; } goto ok; ok: self->private_impl.p_read_palette = 0; goto exit; } goto suspend; suspend: self->private_impl.p_read_palette = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_read_palette.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bmp.decoder.process_masks WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bmp__decoder__process_masks( wuffs_bmp__decoder* self) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_i = 0; uint32_t v_mask = 0; uint32_t v_n = 0; while (v_i < 4u) { v_mask = self->private_impl.f_channel_masks[v_i]; if (v_mask != 0u) { v_n = 0u; while ((v_mask & 1u) == 0u) { v_n += 1u; v_mask >>= 1u; } self->private_impl.f_channel_shifts[v_i] = ((uint8_t)((v_n & 31u))); v_n = 0u; while ((v_mask & 1u) == 1u) { v_n += 1u; v_mask >>= 1u; } if ((v_mask != 0u) || (v_n > 32u)) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } self->private_impl.f_channel_num_bits[v_i] = ((uint8_t)(v_n)); } else if (v_i != 3u) { status = wuffs_base__make_status(wuffs_bmp__error__bad_header); goto exit; } v_i += 1u; } goto ok; ok: goto exit; exit: return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BMP) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BZIP2) // ---------------- Status Codes Implementations const char wuffs_bzip2__error__bad_huffman_code_over_subscribed[] = "#bzip2: bad Huffman code (over-subscribed)"; const char wuffs_bzip2__error__bad_huffman_code_under_subscribed[] = "#bzip2: bad Huffman code (under-subscribed)"; const char wuffs_bzip2__error__bad_block_header[] = "#bzip2: bad block header"; const char wuffs_bzip2__error__bad_block_length[] = "#bzip2: bad block length"; const char wuffs_bzip2__error__bad_checksum[] = "#bzip2: bad checksum"; const char wuffs_bzip2__error__bad_header[] = "#bzip2: bad header"; const char wuffs_bzip2__error__bad_number_of_sections[] = "#bzip2: bad number of sections"; const char wuffs_bzip2__error__truncated_input[] = "#bzip2: truncated input"; const char wuffs_bzip2__error__unsupported_block_randomization[] = "#bzip2: unsupported block randomization"; const char wuffs_bzip2__error__internal_error_inconsistent_huffman_decoder_state[] = "#bzip2: internal error: inconsistent Huffman decoder state"; // ---------------- Private Consts static const uint8_t WUFFS_BZIP2__CLAMP_TO_5[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 1u, 2u, 3u, 4u, 5u, 5u, 5u, }; static const uint32_t WUFFS_BZIP2__REV_CRC32_TABLE[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 79764919u, 159529838u, 222504665u, 319059676u, 398814059u, 445009330u, 507990021u, 638119352u, 583659535u, 797628118u, 726387553u, 890018660u, 835552979u, 1015980042u, 944750013u, 1276238704u, 1221641927u, 1167319070u, 1095957929u, 1595256236u, 1540665371u, 1452775106u, 1381403509u, 1780037320u, 1859660671u, 1671105958u, 1733955601u, 2031960084u, 2111593891u, 1889500026u, 1952343757u, 2552477408u, 2632100695u, 2443283854u, 2506133561u, 2334638140u, 2414271883u, 2191915858u, 2254759653u, 3190512472u, 3135915759u, 3081330742u, 3009969537u, 2905550212u, 2850959411u, 2762807018u, 2691435357u, 3560074640u, 3505614887u, 3719321342u, 3648080713u, 3342211916u, 3287746299u, 3467911202u, 3396681109u, 4063920168u, 4143685023u, 4223187782u, 4286162673u, 3779000052u, 3858754371u, 3904687514u, 3967668269u, 881225847u, 809987520u, 1023691545u, 969234094u, 662832811u, 591600412u, 771767749u, 717299826u, 311336399u, 374308984u, 453813921u, 533576470u, 25881363u, 88864420u, 134795389u, 214552010u, 2023205639u, 2086057648u, 1897238633u, 1976864222u, 1804852699u, 1867694188u, 1645340341u, 1724971778u, 1587496639u, 1516133128u, 1461550545u, 1406951526u, 1302016099u, 1230646740u, 1142491917u, 1087903418u, 2896545431u, 2825181984u, 2770861561u, 2716262478u, 3215044683u, 3143675388u, 3055782693u, 3001194130u, 2326604591u, 2389456536u, 2200899649u, 2280525302u, 2578013683u, 2640855108u, 2418763421u, 2498394922u, 3769900519u, 3832873040u, 3912640137u, 3992402750u, 4088425275u, 4151408268u, 4197601365u, 4277358050u, 3334271071u, 3263032808u, 3476998961u, 3422541446u, 3585640067u, 3514407732u, 3694837229u, 3640369242u, 1762451694u, 1842216281u, 1619975040u, 1682949687u, 2047383090u, 2127137669u, 1938468188u, 2001449195u, 1325665622u, 1271206113u, 1183200824u, 1111960463u, 1543535498u, 1489069629u, 1434599652u, 1363369299u, 622672798u, 568075817u, 748617968u, 677256519u, 907627842u, 853037301u, 1067152940u, 995781531u, 51762726u, 131386257u, 177728840u, 240578815u, 269590778u, 349224269u, 429104020u, 491947555u, 4046411278u, 4126034873u, 4172115296u, 4234965207u, 3794477266u, 3874110821u, 3953728444u, 4016571915u, 3609705398u, 3555108353u, 3735388376u, 3664026991u, 3290680682u, 3236090077u, 3449943556u, 3378572211u, 3174993278u, 3120533705u, 3032266256u, 2961025959u, 2923101090u, 2868635157u, 2813903052u, 2742672763u, 2604032198u, 2683796849u, 2461293480u, 2524268063u, 2284983834u, 2364738477u, 2175806836u, 2238787779u, 1569362073u, 1498123566u, 1409854455u, 1355396672u, 1317987909u, 1246755826u, 1192025387u, 1137557660u, 2072149281u, 2135122070u, 1912620623u, 1992383480u, 1753615357u, 1816598090u, 1627664531u, 1707420964u, 295390185u, 358241886u, 404320391u, 483945776u, 43990325u, 106832002u, 186451547u, 266083308u, 932423249u, 861060070u, 1041341759u, 986742920u, 613929101u, 542559546u, 756411363u, 701822548u, 3316196985u, 3244833742u, 3425377559u, 3370778784u, 3601682597u, 3530312978u, 3744426955u, 3689838204u, 3819031489u, 3881883254u, 3928223919u, 4007849240u, 4037393693u, 4100235434u, 4180117107u, 4259748804u, 2310601993u, 2373574846u, 2151335527u, 2231098320u, 2596047829u, 2659030626u, 2470359227u, 2550115596u, 2947551409u, 2876312838u, 2788305887u, 2733848168u, 3165939309u, 3094707162u, 3040238851u, 2985771188u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__do_transform_io( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__prepare_block( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__read_code_lengths( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__build_huffman_tree( wuffs_bzip2__decoder* self, uint32_t a_which); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__build_huffman_table( wuffs_bzip2__decoder* self, uint32_t a_which); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__invert_bwt( wuffs_bzip2__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__flush_fast( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__flush_slow( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__decode_huffman_fast( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__decode_huffman_slow( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_bzip2__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_bzip2__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_bzip2__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_bzip2__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_bzip2__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_bzip2__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_bzip2__decoder__initialize( wuffs_bzip2__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_bzip2__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_bzip2__decoder* wuffs_bzip2__decoder__alloc(void) { wuffs_bzip2__decoder* x = (wuffs_bzip2__decoder*)(calloc(1, sizeof(wuffs_bzip2__decoder))); if (!x) { return NULL; } if (wuffs_bzip2__decoder__initialize( x, sizeof(wuffs_bzip2__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_bzip2__decoder(void) { return sizeof(wuffs_bzip2__decoder); } // ---------------- Function Implementations // -------- func bzip2.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_bzip2__decoder__get_quirk( const wuffs_bzip2__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if ((a_key == 1u) && self->private_impl.f_ignore_checksum) { return 1u; } return 0u; } // -------- func bzip2.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bzip2__decoder__set_quirk( wuffs_bzip2__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func bzip2.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_bzip2__decoder__dst_history_retain_length( const wuffs_bzip2__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func bzip2.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_bzip2__decoder__workbuf_len( const wuffs_bzip2__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } // -------- func bzip2.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_bzip2__decoder__transform_io( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_bzip2__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_bzip2__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func bzip2.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__do_transform_io( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_i = 0; uint64_t v_tag = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_final_checksum_want = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; if (coro_susp_point) { v_i = self->private_data.s_do_transform_io.v_i; v_tag = self->private_data.s_do_transform_io.v_tag; v_final_checksum_want = self->private_data.s_do_transform_io.v_final_checksum_want; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 66u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_c8 != 90u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_c8 != 104u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if ((v_c8 < 49u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_header); goto exit; } self->private_impl.f_max_incl_block_size = (((uint32_t)(((uint8_t)(v_c8 - 48u)))) * 100000u); while (true) { v_tag = 0u; v_i = 0u; while (v_i < 48u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } v_tag <<= 1u; v_tag |= ((uint64_t)((self->private_impl.f_bits >> 31u))); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } if (v_tag == 25779555029136u) { break; } else if (v_tag != 54156738319193u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); status = wuffs_bzip2__decoder__prepare_block(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_block_size = 0u; self->private_impl.f_decode_huffman_finished = false; self->private_impl.f_decode_huffman_which = WUFFS_BZIP2__CLAMP_TO_5[((uint8_t)(self->private_data.f_huffman_selectors[0u] & 7u))]; self->private_impl.f_decode_huffman_ticks = 50u; self->private_impl.f_decode_huffman_section = 0u; self->private_impl.f_decode_huffman_run_shift = 0u; while ( ! self->private_impl.f_decode_huffman_finished) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_bzip2__decoder__decode_huffman_fast(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } else if (self->private_impl.f_decode_huffman_finished) { break; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); status = wuffs_bzip2__decoder__decode_huffman_slow(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } wuffs_bzip2__decoder__invert_bwt(self); self->private_impl.f_block_checksum_have = 4294967295u; if (self->private_impl.f_original_pointer >= self->private_impl.f_block_size) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } self->private_impl.f_flush_pointer = (self->private_data.f_bwt[self->private_impl.f_original_pointer] >> 12u); self->private_impl.f_flush_repeat_count = 0u; self->private_impl.f_flush_prev = 0u; while (self->private_impl.f_block_size > 0u) { wuffs_bzip2__decoder__flush_fast(self, a_dst); if (self->private_impl.f_block_size <= 0u) { break; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_bzip2__decoder__flush_slow(self, a_dst); if (status.repr) { goto suspend; } } self->private_impl.f_block_checksum_have ^= 4294967295u; if ( ! self->private_impl.f_ignore_checksum && (self->private_impl.f_block_checksum_have != self->private_impl.f_block_checksum_want)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_checksum); goto exit; } self->private_impl.f_final_checksum_have = (self->private_impl.f_block_checksum_have ^ ((self->private_impl.f_final_checksum_have >> 31u) | ((uint32_t)(self->private_impl.f_final_checksum_have << 1u)))); } v_final_checksum_want = 0u; v_i = 0u; while (v_i < 32u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } v_final_checksum_want <<= 1u; v_final_checksum_want |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } if ( ! self->private_impl.f_ignore_checksum && (self->private_impl.f_final_checksum_have != v_final_checksum_want)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_checksum); goto exit; } goto ok; ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_transform_io.v_i = v_i; self->private_data.s_do_transform_io.v_tag = v_tag; self->private_data.s_do_transform_io.v_final_checksum_want = v_final_checksum_want; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bzip2.decoder.prepare_block WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__prepare_block( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_i = 0; uint32_t v_j = 0; uint32_t v_selector = 0; uint32_t v_sel_ff = 0; uint8_t v_movee = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_prepare_block; if (coro_susp_point) { v_i = self->private_data.s_prepare_block.v_i; v_selector = self->private_data.s_prepare_block.v_selector; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_block_checksum_want = 0u; v_i = 0u; while (v_i < 32u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } self->private_impl.f_block_checksum_want <<= 1u; self->private_impl.f_block_checksum_want |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } if ((self->private_impl.f_bits >> 31u) != 0u) { status = wuffs_base__make_status(wuffs_bzip2__error__unsupported_block_randomization); goto exit; } self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; self->private_impl.f_original_pointer = 0u; v_i = 0u; while (v_i < 24u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } self->private_impl.f_original_pointer <<= 1u; self->private_impl.f_original_pointer |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } v_i = 0u; while (v_i < 256u) { self->private_data.f_presence[v_i] = 0u; v_i += 1u; } v_i = 0u; while (v_i < 256u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } if ((self->private_impl.f_bits >> 31u) != 0u) { self->private_data.f_presence[v_i] = 1u; } self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 16u; } self->private_data.f_scratch = 0u; v_i = 0u; while (v_i < 256u) { if (self->private_data.f_presence[v_i] == 0u) { v_i += 16u; continue; } while (true) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } self->private_data.f_scratch += (self->private_impl.f_bits >> 31u); self->private_data.f_presence[(v_i & 255u)] = ((uint8_t)((self->private_impl.f_bits >> 31u))); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; if ((v_i & 15u) == 0u) { break; } } } if ((self->private_data.f_scratch < 1u) || (256u < self->private_data.f_scratch)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } self->private_impl.f_num_symbols = (self->private_data.f_scratch + 2u); self->private_data.f_scratch = 0u; v_i = 0u; while (v_i < 3u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } self->private_data.f_scratch <<= 1u; self->private_data.f_scratch |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } if ((self->private_data.f_scratch < 2u) || (6u < self->private_data.f_scratch)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } self->private_impl.f_num_huffman_codes = self->private_data.f_scratch; self->private_data.f_scratch = 0u; v_i = 0u; while (v_i < 15u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } self->private_data.f_scratch <<= 1u; self->private_data.f_scratch |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } if ((self->private_data.f_scratch < 1u) || (18001u < self->private_data.f_scratch)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } self->private_impl.f_num_sections = self->private_data.f_scratch; v_i = 0u; while (v_i < self->private_impl.f_num_huffman_codes) { self->private_data.f_mtft[v_i] = ((uint8_t)(v_i)); v_i += 1u; } v_i = 0u; while (v_i < self->private_impl.f_num_sections) { v_selector = 0u; while (true) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_7 = *iop_a_src++; v_c8 = t_7; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } if ((self->private_impl.f_bits >> 31u) == 0u) { self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; break; } self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_selector += 1u; if (v_selector >= self->private_impl.f_num_huffman_codes) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } } if (v_selector == 0u) { self->private_data.f_huffman_selectors[v_i] = self->private_data.f_mtft[0u]; } else { v_sel_ff = (v_selector & 255u); v_movee = self->private_data.f_mtft[v_sel_ff]; wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(self->private_data.f_mtft, 1, (1u + v_sel_ff)), wuffs_base__make_slice_u8(self->private_data.f_mtft, v_sel_ff)); self->private_data.f_mtft[0u] = v_movee; self->private_data.f_huffman_selectors[v_i] = v_movee; } v_i += 1u; } v_i = 0u; while (v_i < self->private_impl.f_num_huffman_codes) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_bzip2__decoder__read_code_lengths(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } v_status = wuffs_bzip2__decoder__build_huffman_tree(self, v_i); if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } wuffs_bzip2__decoder__build_huffman_table(self, v_i); v_i += 1u; } v_i = 0u; v_j = 0u; while (v_i < 256u) { if (self->private_data.f_presence[v_i] != 0u) { self->private_data.f_mtft[(v_j & 255u)] = ((uint8_t)(v_i)); v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 256u) { self->private_data.f_letter_counts[v_i] = 0u; v_i += 1u; } goto ok; ok: self->private_impl.p_prepare_block = 0; goto exit; } goto suspend; suspend: self->private_impl.p_prepare_block = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_prepare_block.v_i = v_i; self->private_data.s_prepare_block.v_selector = v_selector; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bzip2.decoder.read_code_lengths WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__read_code_lengths( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_i = 0; uint32_t v_code_length = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_read_code_lengths; if (coro_susp_point) { v_i = self->private_data.s_read_code_lengths.v_i; v_code_length = self->private_data.s_read_code_lengths.v_code_length; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_code_lengths_bitmask = 0u; v_i = 0u; while (v_i < 5u) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } v_code_length <<= 1u; v_code_length |= (self->private_impl.f_bits >> 31u); self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; v_i += 1u; } v_i = 0u; while (v_i < self->private_impl.f_num_symbols) { while (true) { if ((v_code_length < 1u) || (20u < v_code_length)) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_header); goto exit; } if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } if ((self->private_impl.f_bits >> 31u) == 0u) { self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; break; } self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } if ((self->private_impl.f_bits >> 31u) == 0u) { v_code_length += 1u; } else { v_code_length -= 1u; } self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; } self->private_impl.f_code_lengths_bitmask |= (((uint32_t)(1u)) << (v_code_length & 31u)); self->private_data.f_bwt[v_i] = v_code_length; v_i += 1u; } goto ok; ok: self->private_impl.p_read_code_lengths = 0; goto exit; } goto suspend; suspend: self->private_impl.p_read_code_lengths = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_read_code_lengths.v_i = v_i; self->private_data.s_read_code_lengths.v_code_length = v_code_length; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bzip2.decoder.build_huffman_tree WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__build_huffman_tree( wuffs_bzip2__decoder* self, uint32_t a_which) { uint32_t v_code_length = 0; uint32_t v_symbol_index = 0; uint32_t v_num_branch_nodes = 0; uint32_t v_stack_height = 0; uint32_t v_stack_values[21] = {0}; uint32_t v_node_index = 0; uint16_t v_leaf_value = 0; self->private_data.f_huffman_trees[a_which][0u][0u] = 0u; self->private_data.f_huffman_trees[a_which][0u][1u] = 0u; v_num_branch_nodes = 1u; v_stack_height = 1u; v_stack_values[0u] = 0u; v_code_length = 1u; while (v_code_length <= 20u) { if ((self->private_impl.f_code_lengths_bitmask & (((uint32_t)(1u)) << v_code_length)) == 0u) { v_code_length += 1u; continue; } v_symbol_index = 0u; while (v_symbol_index < self->private_impl.f_num_symbols) { if (self->private_data.f_bwt[v_symbol_index] != v_code_length) { v_symbol_index += 1u; continue; } while (true) { if (v_stack_height <= 0u) { return wuffs_base__make_status(wuffs_bzip2__error__bad_huffman_code_over_subscribed); } else if (v_stack_height >= v_code_length) { break; } v_node_index = v_stack_values[(v_stack_height - 1u)]; if (self->private_data.f_huffman_trees[a_which][v_node_index][0u] == 0u) { self->private_data.f_huffman_trees[a_which][v_node_index][0u] = ((uint16_t)(v_num_branch_nodes)); } else { self->private_data.f_huffman_trees[a_which][v_node_index][1u] = ((uint16_t)(v_num_branch_nodes)); } if (v_num_branch_nodes >= 257u) { return wuffs_base__make_status(wuffs_bzip2__error__bad_huffman_code_under_subscribed); } v_stack_values[v_stack_height] = v_num_branch_nodes; self->private_data.f_huffman_trees[a_which][v_num_branch_nodes][0u] = 0u; self->private_data.f_huffman_trees[a_which][v_num_branch_nodes][1u] = 0u; v_num_branch_nodes += 1u; v_stack_height += 1u; } v_node_index = v_stack_values[(v_stack_height - 1u)]; if (v_symbol_index < 2u) { v_leaf_value = ((uint16_t)((769u + v_symbol_index))); } else if ((v_symbol_index + 1u) < self->private_impl.f_num_symbols) { v_leaf_value = ((uint16_t)((511u + v_symbol_index))); } else { v_leaf_value = 768u; } if (self->private_data.f_huffman_trees[a_which][v_node_index][0u] == 0u) { self->private_data.f_huffman_trees[a_which][v_node_index][0u] = v_leaf_value; } else { self->private_data.f_huffman_trees[a_which][v_node_index][1u] = v_leaf_value; v_stack_height -= 1u; while (v_stack_height > 0u) { v_node_index = v_stack_values[(v_stack_height - 1u)]; if (self->private_data.f_huffman_trees[a_which][v_node_index][1u] == 0u) { break; } v_stack_height -= 1u; } } v_symbol_index += 1u; } v_code_length += 1u; } if (v_stack_height != 0u) { return wuffs_base__make_status(wuffs_bzip2__error__bad_huffman_code_under_subscribed); } return wuffs_base__make_status(NULL); } // -------- func bzip2.decoder.build_huffman_table WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__build_huffman_table( wuffs_bzip2__decoder* self, uint32_t a_which) { uint32_t v_i = 0; uint32_t v_bits = 0; uint16_t v_n_bits = 0; uint16_t v_child = 0; while (v_i < 256u) { v_bits = (v_i << 24u); v_n_bits = 0u; v_child = 0u; while ((v_child < 257u) && (v_n_bits < 8u)) { v_child = self->private_data.f_huffman_trees[a_which][v_child][(v_bits >> 31u)]; v_bits <<= 1u; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_n_bits += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } self->private_data.f_huffman_tables[a_which][v_i] = ((uint16_t)(((uint16_t)(v_child | ((uint16_t)(v_n_bits << 12u)))))); v_i += 1u; } return wuffs_base__make_empty_struct(); } // -------- func bzip2.decoder.invert_bwt WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__invert_bwt( wuffs_bzip2__decoder* self) { uint32_t v_i = 0; uint32_t v_letter = 0; uint32_t v_sum = 0; uint32_t v_old_sum = 0; v_sum = 0u; v_i = 0u; while (v_i < 256u) { v_old_sum = v_sum; v_sum += self->private_data.f_letter_counts[v_i]; self->private_data.f_letter_counts[v_i] = v_old_sum; v_i += 1u; } v_i = 0u; while (v_i < self->private_impl.f_block_size) { v_letter = (self->private_data.f_bwt[v_i] & 255u); self->private_data.f_bwt[(self->private_data.f_letter_counts[v_letter] & 1048575u)] |= (v_i << 12u); self->private_data.f_letter_counts[v_letter] += 1u; v_i += 1u; } return wuffs_base__make_empty_struct(); } // -------- func bzip2.decoder.flush_fast WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_bzip2__decoder__flush_fast( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst) { uint32_t v_flush_pointer = 0; uint32_t v_flush_repeat_count = 0; uint8_t v_flush_prev = 0; uint32_t v_block_checksum_have = 0; uint32_t v_block_size = 0; uint32_t v_entry = 0; uint8_t v_curr = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } v_flush_pointer = self->private_impl.f_flush_pointer; v_flush_repeat_count = self->private_impl.f_flush_repeat_count; v_flush_prev = self->private_impl.f_flush_prev; v_block_checksum_have = self->private_impl.f_block_checksum_have; v_block_size = self->private_impl.f_block_size; while ((v_block_size > 0u) && (((uint64_t)(io2_a_dst - iop_a_dst)) >= 255u)) { if (v_flush_repeat_count < 4u) { v_entry = self->private_data.f_bwt[v_flush_pointer]; v_curr = ((uint8_t)(v_entry)); v_flush_pointer = (v_entry >> 12u); if (v_curr == v_flush_prev) { v_flush_repeat_count += 1u; } else { v_flush_repeat_count = 1u; } v_block_checksum_have = (WUFFS_BZIP2__REV_CRC32_TABLE[((uint8_t)(((uint8_t)((v_block_checksum_have >> 24u))) ^ v_curr))] ^ ((uint32_t)(v_block_checksum_have << 8u))); (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, v_curr), iop_a_dst += 1); v_flush_prev = v_curr; v_block_size -= 1u; } else { v_entry = self->private_data.f_bwt[v_flush_pointer]; v_curr = ((uint8_t)(v_entry)); v_flush_pointer = (v_entry >> 12u); v_flush_repeat_count = ((uint32_t)(v_curr)); while (v_flush_repeat_count > 0u) { v_block_checksum_have = (WUFFS_BZIP2__REV_CRC32_TABLE[((uint8_t)(((uint8_t)((v_block_checksum_have >> 24u))) ^ v_flush_prev))] ^ ((uint32_t)(v_block_checksum_have << 8u))); if (((uint64_t)(io2_a_dst - iop_a_dst)) > 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, v_flush_prev), iop_a_dst += 1); } v_flush_repeat_count -= 1u; } v_flush_repeat_count = 0u; v_flush_prev = v_curr; v_block_size -= 1u; } } self->private_impl.f_flush_pointer = v_flush_pointer; self->private_impl.f_flush_repeat_count = v_flush_repeat_count; self->private_impl.f_flush_prev = v_flush_prev; self->private_impl.f_block_checksum_have = v_block_checksum_have; if (v_block_size <= 900000u) { self->private_impl.f_block_size = v_block_size; } if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } return wuffs_base__make_empty_struct(); } // -------- func bzip2.decoder.flush_slow WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__flush_slow( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_dst) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_flush_pointer = 0; uint32_t v_flush_repeat_count = 0; uint8_t v_flush_prev = 0; uint32_t v_block_checksum_have = 0; uint32_t v_block_size = 0; uint32_t v_entry = 0; uint8_t v_curr = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } uint32_t coro_susp_point = self->private_impl.p_flush_slow; if (coro_susp_point) { v_flush_pointer = self->private_data.s_flush_slow.v_flush_pointer; v_flush_repeat_count = self->private_data.s_flush_slow.v_flush_repeat_count; v_flush_prev = self->private_data.s_flush_slow.v_flush_prev; v_block_checksum_have = self->private_data.s_flush_slow.v_block_checksum_have; v_block_size = self->private_data.s_flush_slow.v_block_size; v_curr = self->private_data.s_flush_slow.v_curr; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_flush_pointer = self->private_impl.f_flush_pointer; v_flush_repeat_count = self->private_impl.f_flush_repeat_count; v_flush_prev = self->private_impl.f_flush_prev; v_block_checksum_have = self->private_impl.f_block_checksum_have; v_block_size = self->private_impl.f_block_size; while ((v_block_size > 0u) && ! (self->private_impl.p_flush_slow != 0)) { if (v_flush_repeat_count < 4u) { v_entry = self->private_data.f_bwt[v_flush_pointer]; v_curr = ((uint8_t)(v_entry)); v_flush_pointer = (v_entry >> 12u); if (v_curr == v_flush_prev) { v_flush_repeat_count += 1u; } else { v_flush_repeat_count = 1u; } v_block_checksum_have = (WUFFS_BZIP2__REV_CRC32_TABLE[((uint8_t)(((uint8_t)((v_block_checksum_have >> 24u))) ^ v_curr))] ^ ((uint32_t)(v_block_checksum_have << 8u))); self->private_data.s_flush_slow.scratch = v_curr; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (iop_a_dst == io2_a_dst) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); goto suspend; } *iop_a_dst++ = ((uint8_t)(self->private_data.s_flush_slow.scratch)); v_flush_prev = v_curr; v_block_size -= 1u; } else { v_entry = self->private_data.f_bwt[v_flush_pointer]; v_curr = ((uint8_t)(v_entry)); v_flush_pointer = (v_entry >> 12u); v_flush_repeat_count = ((uint32_t)(v_curr)); while (v_flush_repeat_count > 0u) { v_block_checksum_have = (WUFFS_BZIP2__REV_CRC32_TABLE[((uint8_t)(((uint8_t)((v_block_checksum_have >> 24u))) ^ v_flush_prev))] ^ ((uint32_t)(v_block_checksum_have << 8u))); self->private_data.s_flush_slow.scratch = v_flush_prev; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (iop_a_dst == io2_a_dst) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); goto suspend; } *iop_a_dst++ = ((uint8_t)(self->private_data.s_flush_slow.scratch)); v_flush_repeat_count -= 1u; } v_flush_repeat_count = 0u; v_flush_prev = v_curr; v_block_size -= 1u; } } self->private_impl.f_flush_pointer = v_flush_pointer; self->private_impl.f_flush_repeat_count = v_flush_repeat_count; self->private_impl.f_flush_prev = v_flush_prev; self->private_impl.f_block_checksum_have = v_block_checksum_have; if (v_block_size <= 900000u) { self->private_impl.f_block_size = v_block_size; } goto ok; ok: self->private_impl.p_flush_slow = 0; goto exit; } goto suspend; suspend: self->private_impl.p_flush_slow = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_flush_slow.v_flush_pointer = v_flush_pointer; self->private_data.s_flush_slow.v_flush_repeat_count = v_flush_repeat_count; self->private_data.s_flush_slow.v_flush_prev = v_flush_prev; self->private_data.s_flush_slow.v_block_checksum_have = v_block_checksum_have; self->private_data.s_flush_slow.v_block_size = v_block_size; self->private_data.s_flush_slow.v_curr = v_curr; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } return status; } // -------- func bzip2.decoder.decode_huffman_fast WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__decode_huffman_fast( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_block_size = 0; uint8_t v_which = 0; uint32_t v_ticks = 0; uint32_t v_section = 0; uint32_t v_run_shift = 0; uint16_t v_table_entry = 0; uint16_t v_child = 0; uint32_t v_child_ff = 0; uint32_t v_i = 0; uint32_t v_j = 0; uint32_t v_output = 0; uint32_t v_run = 0; uint32_t v_mtft0 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_bits = self->private_impl.f_bits; v_n_bits = self->private_impl.f_n_bits; v_block_size = self->private_impl.f_block_size; v_which = self->private_impl.f_decode_huffman_which; v_ticks = self->private_impl.f_decode_huffman_ticks; v_section = self->private_impl.f_decode_huffman_section; v_run_shift = self->private_impl.f_decode_huffman_run_shift; while (((uint64_t)(io2_a_src - iop_a_src)) >= 4u) { if (v_ticks > 0u) { v_ticks -= 1u; } else { v_ticks = 49u; v_section += 1u; if (v_section >= self->private_impl.f_num_sections) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_number_of_sections); goto exit; } v_which = WUFFS_BZIP2__CLAMP_TO_5[((uint8_t)(self->private_data.f_huffman_selectors[(v_section & 32767u)] & 7u))]; } v_bits |= (wuffs_base__peek_u32be__no_bounds_check(iop_a_src) >> v_n_bits); iop_a_src += ((31u - v_n_bits) >> 3u); v_n_bits |= 24u; v_table_entry = self->private_data.f_huffman_tables[v_which][(v_bits >> 24u)]; v_bits <<= ((uint16_t)(v_table_entry >> 12u)); v_n_bits -= ((uint32_t)(((uint16_t)(v_table_entry >> 12u)))); v_child = ((uint16_t)(v_table_entry & 1023u)); while (v_child < 257u) { v_child = self->private_data.f_huffman_trees[v_which][v_child][(v_bits >> 31u)]; v_bits <<= 1u; if (v_n_bits <= 0u) { status = wuffs_base__make_status(wuffs_bzip2__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_n_bits -= 1u; } if (v_child < 768u) { v_child_ff = ((uint32_t)(((uint16_t)(v_child & 255u)))); v_output = ((uint32_t)(self->private_data.f_mtft[v_child_ff])); wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(self->private_data.f_mtft, 1, (1u + v_child_ff)), wuffs_base__make_slice_u8(self->private_data.f_mtft, v_child_ff)); self->private_data.f_mtft[0u] = ((uint8_t)(v_output)); self->private_data.f_letter_counts[v_output] += 1u; self->private_data.f_bwt[v_block_size] = v_output; if (v_block_size >= self->private_impl.f_max_incl_block_size) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } v_block_size += 1u; v_run_shift = 0u; continue; } else if (v_child == 768u) { self->private_impl.f_decode_huffman_finished = true; break; } if (v_run_shift >= 23u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } v_run = ((((uint32_t)(v_child)) & 3u) << v_run_shift); v_run_shift += 1u; v_i = v_block_size; v_j = (v_run + v_block_size); if (v_j > self->private_impl.f_max_incl_block_size) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } v_block_size = v_j; v_mtft0 = ((uint32_t)(self->private_data.f_mtft[0u])); self->private_data.f_letter_counts[v_mtft0] += v_run; while (v_i < v_j) { self->private_data.f_bwt[v_i] = v_mtft0; v_i += 1u; } } self->private_impl.f_bits = v_bits; self->private_impl.f_n_bits = v_n_bits; self->private_impl.f_block_size = v_block_size; self->private_impl.f_decode_huffman_which = v_which; self->private_impl.f_decode_huffman_ticks = v_ticks; self->private_impl.f_decode_huffman_section = v_section; self->private_impl.f_decode_huffman_run_shift = v_run_shift; status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func bzip2.decoder.decode_huffman_slow WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_bzip2__decoder__decode_huffman_slow( wuffs_bzip2__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_node_index = 0; uint16_t v_child = 0; uint32_t v_child_ff = 0; uint32_t v_i = 0; uint32_t v_j = 0; uint32_t v_output = 0; uint32_t v_run = 0; uint32_t v_mtft0 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_huffman_slow; if (coro_susp_point) { v_node_index = self->private_data.s_decode_huffman_slow.v_node_index; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while ( ! (self->private_impl.p_decode_huffman_slow != 0)) { if (self->private_impl.f_decode_huffman_ticks > 0u) { self->private_impl.f_decode_huffman_ticks -= 1u; } else { self->private_impl.f_decode_huffman_ticks = 49u; self->private_impl.f_decode_huffman_section += 1u; if (self->private_impl.f_decode_huffman_section >= self->private_impl.f_num_sections) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_number_of_sections); goto exit; } self->private_impl.f_decode_huffman_which = WUFFS_BZIP2__CLAMP_TO_5[((uint8_t)(self->private_data.f_huffman_selectors[(self->private_impl.f_decode_huffman_section & 32767u)] & 7u))]; } v_node_index = 0u; while (true) { if (self->private_impl.f_n_bits <= 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = (((uint32_t)(v_c8)) << 24u); self->private_impl.f_n_bits = 8u; } v_child = self->private_data.f_huffman_trees[self->private_impl.f_decode_huffman_which][v_node_index][(self->private_impl.f_bits >> 31u)]; self->private_impl.f_bits <<= 1u; self->private_impl.f_n_bits -= 1u; if (v_child < 257u) { v_node_index = ((uint32_t)(v_child)); continue; } else if (v_child < 768u) { v_child_ff = ((uint32_t)(((uint16_t)(v_child & 255u)))); v_output = ((uint32_t)(self->private_data.f_mtft[v_child_ff])); wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(self->private_data.f_mtft, 1, (1u + v_child_ff)), wuffs_base__make_slice_u8(self->private_data.f_mtft, v_child_ff)); self->private_data.f_mtft[0u] = ((uint8_t)(v_output)); self->private_data.f_letter_counts[v_output] += 1u; self->private_data.f_bwt[self->private_impl.f_block_size] = v_output; if (self->private_impl.f_block_size >= self->private_impl.f_max_incl_block_size) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } self->private_impl.f_block_size += 1u; self->private_impl.f_decode_huffman_run_shift = 0u; break; } else if (v_child == 768u) { self->private_impl.f_decode_huffman_finished = true; goto label__outer__break; } if (self->private_impl.f_decode_huffman_run_shift >= 23u) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } v_run = ((((uint32_t)(v_child)) & 3u) << self->private_impl.f_decode_huffman_run_shift); self->private_impl.f_decode_huffman_run_shift += 1u; v_i = self->private_impl.f_block_size; v_j = (v_run + self->private_impl.f_block_size); if (v_j > self->private_impl.f_max_incl_block_size) { status = wuffs_base__make_status(wuffs_bzip2__error__bad_block_length); goto exit; } self->private_impl.f_block_size = v_j; v_mtft0 = ((uint32_t)(self->private_data.f_mtft[0u])); self->private_data.f_letter_counts[v_mtft0] += v_run; while (v_i < v_j) { self->private_data.f_bwt[v_i] = v_mtft0; v_i += 1u; } break; } } label__outer__break:; goto ok; ok: self->private_impl.p_decode_huffman_slow = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_huffman_slow = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_huffman_slow.v_node_index = v_node_index; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BZIP2) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CBOR) // ---------------- Status Codes Implementations const char wuffs_cbor__error__bad_input[] = "#cbor: bad input"; const char wuffs_cbor__error__unsupported_recursion_depth[] = "#cbor: unsupported recursion depth"; const char wuffs_cbor__error__internal_error_inconsistent_i_o[] = "#cbor: internal error: inconsistent I/O"; const char wuffs_cbor__error__internal_error_inconsistent_token_length[] = "#cbor: internal error: inconsistent token length"; // ---------------- Private Consts static const uint32_t WUFFS_CBOR__LITERALS[4] WUFFS_BASE__POTENTIALLY_UNUSED = { 8388612u, 8388616u, 8388610u, 8388609u, }; static const uint8_t WUFFS_CBOR__TOKEN_LENGTHS[32] WUFFS_BASE__POTENTIALLY_UNUSED = { 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 2u, 3u, 5u, 9u, 0u, 0u, 0u, 1u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes // ---------------- VTables const wuffs_base__token_decoder__func_ptrs wuffs_cbor__decoder__func_ptrs_for__wuffs_base__token_decoder = { (wuffs_base__status(*)(void*, wuffs_base__token_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_cbor__decoder__decode_tokens), (uint64_t(*)(const void*, uint32_t))(&wuffs_cbor__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_cbor__decoder__set_quirk), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_cbor__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_cbor__decoder__initialize( wuffs_cbor__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__token_decoder.vtable_name = wuffs_base__token_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__token_decoder.function_pointers = (const void*)(&wuffs_cbor__decoder__func_ptrs_for__wuffs_base__token_decoder); return wuffs_base__make_status(NULL); } wuffs_cbor__decoder* wuffs_cbor__decoder__alloc(void) { wuffs_cbor__decoder* x = (wuffs_cbor__decoder*)(calloc(1, sizeof(wuffs_cbor__decoder))); if (!x) { return NULL; } if (wuffs_cbor__decoder__initialize( x, sizeof(wuffs_cbor__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_cbor__decoder(void) { return sizeof(wuffs_cbor__decoder); } // ---------------- Function Implementations // -------- func cbor.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_cbor__decoder__get_quirk( const wuffs_cbor__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func cbor.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_cbor__decoder__set_quirk( wuffs_cbor__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func cbor.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_cbor__decoder__workbuf_len( const wuffs_cbor__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__empty_range_ii_u64(); } // -------- func cbor.decoder.decode_tokens WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_cbor__decoder__decode_tokens( wuffs_cbor__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_string_length = 0; uint64_t v_n64 = 0; uint32_t v_depth = 0; uint32_t v_stack_byte = 0; uint32_t v_stack_bit = 0; uint32_t v_stack_val = 0; uint32_t v_token_length = 0; uint32_t v_vminor = 0; uint32_t v_vminor_alt = 0; uint32_t v_continued = 0; uint8_t v_c8 = 0; uint8_t v_c_major = 0; uint8_t v_c_minor = 0; bool v_tagged = false; uint8_t v_indefinite_string_major_type = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_tokens; if (coro_susp_point) { v_string_length = self->private_data.s_decode_tokens.v_string_length; v_depth = self->private_data.s_decode_tokens.v_depth; v_tagged = self->private_data.s_decode_tokens.v_tagged; v_indefinite_string_major_type = self->private_data.s_decode_tokens.v_indefinite_string_major_type; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_end_of_data) { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } label__outer__continue:; while (true) { while (true) { do { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); goto label__outer__continue; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); goto label__outer__continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if ((v_indefinite_string_major_type != 0u) && (v_indefinite_string_major_type != ((uint8_t)(v_c8 >> 5u)))) { if (v_c8 != 255u) { status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } v_vminor = 4194560u; if (v_indefinite_string_major_type == 3u) { v_vminor |= 19u; } v_indefinite_string_major_type = 0u; iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } iop_a_src += 1u; v_c_major = ((uint8_t)(((uint8_t)(v_c8 >> 5u)))); v_c_minor = ((uint8_t)(v_c8 & 31u)); if (v_c_minor < 24u) { v_string_length = ((uint64_t)(v_c_minor)); } else { while (true) { if (v_c_minor == 24u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 1u) { v_string_length = ((uint64_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))); iop_a_src += 1u; break; } } else if (v_c_minor == 25u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 2u) { v_string_length = ((uint64_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2u; break; } } else if (v_c_minor == 26u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 4u) { v_string_length = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4u; break; } } else if (v_c_minor == 27u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 8u) { v_string_length = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8u; break; } } else { v_string_length = 0u; break; } if (iop_a_src > io1_a_src) { iop_a_src--; if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); goto label__outer__continue; } status = wuffs_base__make_status(wuffs_cbor__error__internal_error_inconsistent_i_o); goto exit; } } if (v_c_major == 0u) { if (v_c_minor < 26u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((14680064u | ((uint32_t)((v_string_length & 65535u)))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor < 28u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((14680064u | ((uint32_t)((v_string_length >> 46u)))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); *iop_a_dst++ = wuffs_base__make_token( (~(v_string_length & 70368744177663u) << WUFFS_BASE__TOKEN__VALUE_EXTENSION__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } } else if (v_c_major == 1u) { if (v_c_minor < 26u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((12582912u | (2097151u - ((uint32_t)((v_string_length & 65535u))))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor < 28u) { if (v_string_length < 9223372036854775808u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((12582912u | (2097151u - ((uint32_t)((v_string_length >> 46u))))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); *iop_a_dst++ = wuffs_base__make_token( (~((18446744073709551615u - v_string_length) & 70368744177663u) << WUFFS_BASE__TOKEN__VALUE_EXTENSION__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } else { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(787997u)) << WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT) | (((uint64_t)(16777216u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(9u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } goto label__goto_parsed_a_leaf_value__break; } } else if (v_c_major == 2u) { if (v_c_minor < 28u) { if (v_string_length == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194560u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194560u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } else if (v_c_minor == 31u) { if (v_indefinite_string_major_type != 0u) { break; } v_indefinite_string_major_type = 2u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194560u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__outer__continue; } else { break; } while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); continue; } v_n64 = wuffs_base__u64__min(v_string_length, ((uint64_t)(io2_a_src - iop_a_src))); v_token_length = ((uint32_t)((v_n64 & 65535u))); if (v_n64 > 65535u) { v_token_length = 65535u; } else if (v_token_length <= 0u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); continue; } if (((uint64_t)(io2_a_src - iop_a_src)) < ((uint64_t)(v_token_length))) { status = wuffs_base__make_status(wuffs_cbor__error__internal_error_inconsistent_token_length); goto exit; } v_string_length -= ((uint64_t)(v_token_length)); v_continued = 0u; if ((v_string_length > 0u) || (v_indefinite_string_major_type > 0u)) { v_continued = 1u; } iop_a_src += v_token_length; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194816u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_continued)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_token_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (v_string_length > 0u) { continue; } else if (v_indefinite_string_major_type > 0u) { goto label__outer__continue; } goto label__goto_parsed_a_leaf_value__break; } } else if (v_c_major == 3u) { if (v_c_minor < 28u) { if (v_string_length == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194579u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194579u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } else if (v_c_minor == 31u) { if (v_indefinite_string_major_type != 0u) { break; } v_indefinite_string_major_type = 3u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194579u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__outer__continue; } else { break; } while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); continue; } v_n64 = wuffs_base__u64__min(v_string_length, 65535u); v_n64 = ((uint64_t)(wuffs_base__utf_8__longest_valid_prefix(iop_a_src, ((size_t)(wuffs_base__u64__min(((uint64_t)(io2_a_src - iop_a_src)), v_n64)))))); v_token_length = ((uint32_t)((v_n64 & 65535u))); if (v_token_length <= 0u) { if ((a_src && a_src->meta.closed) || (((uint64_t)(io2_a_src - iop_a_src)) >= 4u)) { status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); continue; } if (((uint64_t)(io2_a_src - iop_a_src)) < ((uint64_t)(v_token_length))) { status = wuffs_base__make_status(wuffs_cbor__error__internal_error_inconsistent_token_length); goto exit; } v_string_length -= ((uint64_t)(v_token_length)); v_continued = 0u; if ((v_string_length > 0u) || (v_indefinite_string_major_type > 0u)) { v_continued = 1u; } iop_a_src += v_token_length; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_continued)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_token_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (v_string_length > 0u) { continue; } else if (v_indefinite_string_major_type > 0u) { goto label__outer__continue; } goto label__goto_parsed_a_leaf_value__break; } } else if (v_c_major == 4u) { if (WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor] == 0u) { break; } else if (v_depth >= 1024u) { v_token_length = ((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])); while ((v_token_length > 0u) && (iop_a_src > io1_a_src)) { iop_a_src--; v_token_length -= 1u; } status = wuffs_base__make_status(wuffs_cbor__error__unsupported_recursion_depth); goto exit; } v_vminor = 2105361u; v_vminor_alt = 2101282u; if (v_depth > 0u) { v_stack_byte = ((v_depth - 1u) / 16u); v_stack_bit = (((v_depth - 1u) & 15u) * 2u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { v_vminor = 2105377u; v_vminor_alt = 2105378u; } else { v_vminor = 2105409u; v_vminor_alt = 2113570u; } } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (v_c_minor == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor_alt)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } v_stack_byte = (v_depth / 16u); v_stack_bit = ((v_depth & 15u) * 2u); self->private_data.f_stack[v_stack_byte] &= (4294967295u ^ (((uint32_t)(3u)) << v_stack_bit)); self->private_data.f_container_num_remaining[v_depth] = v_string_length; v_depth += 1u; v_tagged = false; goto label__outer__continue; } else if (v_c_major == 5u) { if (WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor] == 0u) { break; } else if (v_depth >= 1024u) { v_token_length = ((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])); while ((v_token_length > 0u) && (iop_a_src > io1_a_src)) { iop_a_src--; v_token_length -= 1u; } status = wuffs_base__make_status(wuffs_cbor__error__unsupported_recursion_depth); goto exit; } v_vminor = 2113553u; v_vminor_alt = 2101314u; if (v_depth > 0u) { v_stack_byte = ((v_depth - 1u) / 16u); v_stack_bit = (((v_depth - 1u) & 15u) * 2u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { v_vminor = 2113569u; v_vminor_alt = 2105410u; } else { v_vminor = 2113601u; v_vminor_alt = 2113602u; } } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (v_c_minor == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor_alt)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } v_stack_byte = (v_depth / 16u); v_stack_bit = ((v_depth & 15u) * 2u); self->private_data.f_stack[v_stack_byte] |= (((uint32_t)(3u)) << v_stack_bit); self->private_data.f_container_num_remaining[v_depth] = v_string_length; v_depth += 1u; v_tagged = false; goto label__outer__continue; } else if (v_c_major == 6u) { if (v_c_minor >= 28u) { break; } if (v_string_length < 262144u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(787997u)) << WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT) | (((uint64_t)((4194304u | ((uint32_t)(v_string_length))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } else { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(787997u)) << WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT) | (((uint64_t)((4194304u | ((uint32_t)((v_string_length >> 46u)))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); *iop_a_dst++ = wuffs_base__make_token( (~(v_string_length & 70368744177663u) << WUFFS_BASE__TOKEN__VALUE_EXTENSION__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } v_tagged = true; goto label__outer__continue; } else if (v_c_major == 7u) { if (v_c_minor < 20u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(787997u)) << WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT) | (((uint64_t)((8388608u | ((uint32_t)((v_string_length & 255u)))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor < 24u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(WUFFS_CBOR__LITERALS[((uint8_t)(v_c_minor & 3u))])) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor == 24u) { if (v_string_length < 24u) { if ( ! (iop_a_src > io1_a_src)) { status = wuffs_base__make_status(wuffs_cbor__error__internal_error_inconsistent_i_o); goto exit; } iop_a_src--; break; } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(787997u)) << WUFFS_BASE__TOKEN__VALUE_MAJOR__SHIFT) | (((uint64_t)((8388608u | ((uint32_t)((v_string_length & 255u)))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor < 28u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(10490113u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(((uint32_t)(WUFFS_CBOR__TOKEN_LENGTHS[v_c_minor])))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } else if (v_c_minor == 31u) { if (v_tagged || (v_depth <= 0u)) { break; } v_depth -= 1u; if (self->private_data.f_container_num_remaining[v_depth] != 0u) { break; } v_stack_byte = (v_depth / 16u); v_stack_bit = ((v_depth & 15u) * 2u); v_stack_val = (3u & (self->private_data.f_stack[v_stack_byte] >> v_stack_bit)); if (v_stack_val == 1u) { break; } if (v_stack_val != 3u) { v_vminor_alt = 2097186u; } else { v_vminor_alt = 2097218u; } if (v_depth <= 0u) { v_vminor_alt |= 4096u; } else { v_stack_byte = ((v_depth - 1u) / 16u); v_stack_bit = (((v_depth - 1u) & 15u) * 2u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { v_vminor_alt |= 8192u; } else { v_vminor_alt |= 16384u; } } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor_alt)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__goto_parsed_a_leaf_value__break; } } } while (0); if (iop_a_src > io1_a_src) { iop_a_src--; status = wuffs_base__make_status(wuffs_cbor__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_cbor__error__internal_error_inconsistent_i_o); goto exit; } label__goto_parsed_a_leaf_value__break:; v_tagged = false; while (v_depth > 0u) { v_stack_byte = ((v_depth - 1u) / 16u); v_stack_bit = (((v_depth - 1u) & 15u) * 2u); self->private_data.f_stack[v_stack_byte] ^= (((uint32_t)(1u)) << (v_stack_bit + 1u)); if (1u == (3u & (self->private_data.f_stack[v_stack_byte] >> v_stack_bit))) { goto label__outer__continue; } if (self->private_data.f_container_num_remaining[(v_depth - 1u)] <= 0u) { goto label__outer__continue; } self->private_data.f_container_num_remaining[(v_depth - 1u)] -= 1u; if (self->private_data.f_container_num_remaining[(v_depth - 1u)] > 0u) { goto label__outer__continue; } while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); continue; } v_depth -= 1u; v_stack_byte = (v_depth / 16u); v_stack_bit = ((v_depth & 15u) * 2u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { v_vminor_alt = 2097186u; } else { v_vminor_alt = 2097218u; } if (v_depth <= 0u) { v_vminor_alt |= 4096u; } else { v_stack_byte = ((v_depth - 1u) / 16u); v_stack_bit = (((v_depth - 1u) & 15u) * 2u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { v_vminor_alt |= 8192u; } else { v_vminor_alt |= 16384u; } } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor_alt)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } break; } self->private_impl.f_end_of_data = true; ok: self->private_impl.p_decode_tokens = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_tokens = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; self->private_data.s_decode_tokens.v_string_length = v_string_length; self->private_data.s_decode_tokens.v_depth = v_depth; self->private_data.s_decode_tokens.v_tagged = v_tagged; self->private_data.s_decode_tokens.v_indefinite_string_major_type = v_indefinite_string_major_type; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CBOR) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC32) // ---------------- Status Codes Implementations // ---------------- Private Consts static const uint32_t WUFFS_CRC32__IEEE_TABLE[16][256] WUFFS_BASE__POTENTIALLY_UNUSED = { { 0u, 1996959894u, 3993919788u, 2567524794u, 124634137u, 1886057615u, 3915621685u, 2657392035u, 249268274u, 2044508324u, 3772115230u, 2547177864u, 162941995u, 2125561021u, 3887607047u, 2428444049u, 498536548u, 1789927666u, 4089016648u, 2227061214u, 450548861u, 1843258603u, 4107580753u, 2211677639u, 325883990u, 1684777152u, 4251122042u, 2321926636u, 335633487u, 1661365465u, 4195302755u, 2366115317u, 997073096u, 1281953886u, 3579855332u, 2724688242u, 1006888145u, 1258607687u, 3524101629u, 2768942443u, 901097722u, 1119000684u, 3686517206u, 2898065728u, 853044451u, 1172266101u, 3705015759u, 2882616665u, 651767980u, 1373503546u, 3369554304u, 3218104598u, 565507253u, 1454621731u, 3485111705u, 3099436303u, 671266974u, 1594198024u, 3322730930u, 2970347812u, 795835527u, 1483230225u, 3244367275u, 3060149565u, 1994146192u, 31158534u, 2563907772u, 4023717930u, 1907459465u, 112637215u, 2680153253u, 3904427059u, 2013776290u, 251722036u, 2517215374u, 3775830040u, 2137656763u, 141376813u, 2439277719u, 3865271297u, 1802195444u, 476864866u, 2238001368u, 4066508878u, 1812370925u, 453092731u, 2181625025u, 4111451223u, 1706088902u, 314042704u, 2344532202u, 4240017532u, 1658658271u, 366619977u, 2362670323u, 4224994405u, 1303535960u, 984961486u, 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3853125400u, 3429020650u, 1644831355u, 2683558414u, 832261023u, 408158061u, 3057348348u, 953223622u, 2528745559u, 3211865253u, 286899508u, 3974120769u, 1116263632u, 1799381026u, 3307794867u, 2917509143u, 59586950u, 709201268u, 2217549029u, 2043995280u, 3619452161u, 4269064691u, 1344032866u, 3740677976u, 1889445577u, 1498812987u, 4148069290u, 180845535u, 2762992206u, 2372361916u, 588238637u, 1921194766u, 3706423967u, 4112727661u, 1531686908u, 2796705673u, 148555288u, 554857194u, 2407195515u, 26248257u, 2952271312u, 2251333922u, 676868275u, 3584149702u, 2076793175u, 1375858085u, 4234771508u, 2493785488u, 986493953u, 319029491u, 3178008930u, 1083533591u, 4009621638u, 3342158964u, 1767759333u, 3887577823u, 1239362382u, 1612160956u, 3464433197u, 864482904u, 2649647049u, 3022443323u, 441336490u, 1706844275u, 3419730402u, 3793503504u, 1282724993u, 2978819316u, 535149925u, 908921239u, 2554697734u, 380632892u, 3100077741u, 2433735263u, 1063734222u, 3265180603u, 1828069930u, 1161729752u, 3948283721u, 2207997677u, 770953084u, 71007118u, 2857626143u, 1470763626u, 4190274555u, 3490330377u, 2120394392u, 4035494306u, 1591758899u, 1999168705u, 3644880208u, 616140069u, 2328960180u, 2736367686u, 225524183u, }, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up__choosy_default( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up_arm_crc32( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up_x86_sse42( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ---------------- VTables const wuffs_base__hasher_u32__func_ptrs wuffs_crc32__ieee_hasher__func_ptrs_for__wuffs_base__hasher_u32 = { (uint32_t(*)(const void*))(&wuffs_crc32__ieee_hasher__checksum_u32), (uint64_t(*)(const void*, uint32_t))(&wuffs_crc32__ieee_hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_crc32__ieee_hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_crc32__ieee_hasher__update), (uint32_t(*)(void*, wuffs_base__slice_u8))(&wuffs_crc32__ieee_hasher__update_u32), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_crc32__ieee_hasher__initialize( wuffs_crc32__ieee_hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_up = &wuffs_crc32__ieee_hasher__up__choosy_default; self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_u32.vtable_name = wuffs_base__hasher_u32__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_u32.function_pointers = (const void*)(&wuffs_crc32__ieee_hasher__func_ptrs_for__wuffs_base__hasher_u32); return wuffs_base__make_status(NULL); } wuffs_crc32__ieee_hasher* wuffs_crc32__ieee_hasher__alloc(void) { wuffs_crc32__ieee_hasher* x = (wuffs_crc32__ieee_hasher*)(calloc(1, sizeof(wuffs_crc32__ieee_hasher))); if (!x) { return NULL; } if (wuffs_crc32__ieee_hasher__initialize( x, sizeof(wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_crc32__ieee_hasher(void) { return sizeof(wuffs_crc32__ieee_hasher); } // ---------------- Function Implementations // -------- func crc32.ieee_hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc32__ieee_hasher__get_quirk( const wuffs_crc32__ieee_hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func crc32.ieee_hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_crc32__ieee_hasher__set_quirk( wuffs_crc32__ieee_hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func crc32.ieee_hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_crc32__ieee_hasher__update( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if (self->private_impl.f_state == 0u) { self->private_impl.choosy_up = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) wuffs_base__cpu_arch__have_arm_crc32() ? &wuffs_crc32__ieee_hasher__up_arm_crc32 : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_crc32__ieee_hasher__up_x86_sse42 : #endif self->private_impl.choosy_up); } wuffs_crc32__ieee_hasher__up(self, a_x); return wuffs_base__make_empty_struct(); } // -------- func crc32.ieee_hasher.update_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_crc32__ieee_hasher__update_u32( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } wuffs_crc32__ieee_hasher__update(self, a_x); return self->private_impl.f_state; } // -------- func crc32.ieee_hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { return (*self->private_impl.choosy_up)(self, a_x); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up__choosy_default( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_s = 0; wuffs_base__slice_u8 v_p = {0}; v_s = (4294967295u ^ self->private_impl.f_state); { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 16; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 32) * 32)); while (v_p.ptr < i_end0_p) { v_s ^= ((((uint32_t)(v_p.ptr[0u])) << 0u) | (((uint32_t)(v_p.ptr[1u])) << 8u) | (((uint32_t)(v_p.ptr[2u])) << 16u) | (((uint32_t)(v_p.ptr[3u])) << 24u)); v_s = (WUFFS_CRC32__IEEE_TABLE[0u][v_p.ptr[15u]] ^ WUFFS_CRC32__IEEE_TABLE[1u][v_p.ptr[14u]] ^ WUFFS_CRC32__IEEE_TABLE[2u][v_p.ptr[13u]] ^ WUFFS_CRC32__IEEE_TABLE[3u][v_p.ptr[12u]] ^ WUFFS_CRC32__IEEE_TABLE[4u][v_p.ptr[11u]] ^ WUFFS_CRC32__IEEE_TABLE[5u][v_p.ptr[10u]] ^ WUFFS_CRC32__IEEE_TABLE[6u][v_p.ptr[9u]] ^ WUFFS_CRC32__IEEE_TABLE[7u][v_p.ptr[8u]] ^ WUFFS_CRC32__IEEE_TABLE[8u][v_p.ptr[7u]] ^ WUFFS_CRC32__IEEE_TABLE[9u][v_p.ptr[6u]] ^ WUFFS_CRC32__IEEE_TABLE[10u][v_p.ptr[5u]] ^ WUFFS_CRC32__IEEE_TABLE[11u][v_p.ptr[4u]] ^ WUFFS_CRC32__IEEE_TABLE[12u][(255u & (v_s >> 24u))] ^ WUFFS_CRC32__IEEE_TABLE[13u][(255u & (v_s >> 16u))] ^ WUFFS_CRC32__IEEE_TABLE[14u][(255u & (v_s >> 8u))] ^ WUFFS_CRC32__IEEE_TABLE[15u][(255u & (v_s >> 0u))]); v_p.ptr += 16; v_s ^= ((((uint32_t)(v_p.ptr[0u])) << 0u) | (((uint32_t)(v_p.ptr[1u])) << 8u) | (((uint32_t)(v_p.ptr[2u])) << 16u) | (((uint32_t)(v_p.ptr[3u])) << 24u)); v_s = (WUFFS_CRC32__IEEE_TABLE[0u][v_p.ptr[15u]] ^ WUFFS_CRC32__IEEE_TABLE[1u][v_p.ptr[14u]] ^ WUFFS_CRC32__IEEE_TABLE[2u][v_p.ptr[13u]] ^ WUFFS_CRC32__IEEE_TABLE[3u][v_p.ptr[12u]] ^ WUFFS_CRC32__IEEE_TABLE[4u][v_p.ptr[11u]] ^ WUFFS_CRC32__IEEE_TABLE[5u][v_p.ptr[10u]] ^ WUFFS_CRC32__IEEE_TABLE[6u][v_p.ptr[9u]] ^ WUFFS_CRC32__IEEE_TABLE[7u][v_p.ptr[8u]] ^ WUFFS_CRC32__IEEE_TABLE[8u][v_p.ptr[7u]] ^ WUFFS_CRC32__IEEE_TABLE[9u][v_p.ptr[6u]] ^ WUFFS_CRC32__IEEE_TABLE[10u][v_p.ptr[5u]] ^ WUFFS_CRC32__IEEE_TABLE[11u][v_p.ptr[4u]] ^ WUFFS_CRC32__IEEE_TABLE[12u][(255u & (v_s >> 24u))] ^ WUFFS_CRC32__IEEE_TABLE[13u][(255u & (v_s >> 16u))] ^ WUFFS_CRC32__IEEE_TABLE[14u][(255u & (v_s >> 8u))] ^ WUFFS_CRC32__IEEE_TABLE[15u][(255u & (v_s >> 0u))]); v_p.ptr += 16; } v_p.len = 16; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 16) * 16)); while (v_p.ptr < i_end1_p) { v_s ^= ((((uint32_t)(v_p.ptr[0u])) << 0u) | (((uint32_t)(v_p.ptr[1u])) << 8u) | (((uint32_t)(v_p.ptr[2u])) << 16u) | (((uint32_t)(v_p.ptr[3u])) << 24u)); v_s = (WUFFS_CRC32__IEEE_TABLE[0u][v_p.ptr[15u]] ^ WUFFS_CRC32__IEEE_TABLE[1u][v_p.ptr[14u]] ^ WUFFS_CRC32__IEEE_TABLE[2u][v_p.ptr[13u]] ^ WUFFS_CRC32__IEEE_TABLE[3u][v_p.ptr[12u]] ^ WUFFS_CRC32__IEEE_TABLE[4u][v_p.ptr[11u]] ^ WUFFS_CRC32__IEEE_TABLE[5u][v_p.ptr[10u]] ^ WUFFS_CRC32__IEEE_TABLE[6u][v_p.ptr[9u]] ^ WUFFS_CRC32__IEEE_TABLE[7u][v_p.ptr[8u]] ^ WUFFS_CRC32__IEEE_TABLE[8u][v_p.ptr[7u]] ^ WUFFS_CRC32__IEEE_TABLE[9u][v_p.ptr[6u]] ^ WUFFS_CRC32__IEEE_TABLE[10u][v_p.ptr[5u]] ^ WUFFS_CRC32__IEEE_TABLE[11u][v_p.ptr[4u]] ^ WUFFS_CRC32__IEEE_TABLE[12u][(255u & (v_s >> 24u))] ^ WUFFS_CRC32__IEEE_TABLE[13u][(255u & (v_s >> 16u))] ^ WUFFS_CRC32__IEEE_TABLE[14u][(255u & (v_s >> 8u))] ^ WUFFS_CRC32__IEEE_TABLE[15u][(255u & (v_s >> 0u))]); v_p.ptr += 16; } v_p.len = 1; const uint8_t* i_end2_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end2_p) { v_s = (WUFFS_CRC32__IEEE_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ v_p.ptr[0u]))] ^ (v_s >> 8u)); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_state = (4294967295u ^ v_s); return wuffs_base__make_empty_struct(); } // -------- func crc32.ieee_hasher.checksum_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_crc32__ieee_hasher__checksum_u32( const wuffs_crc32__ieee_hasher* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_state; } // ‼ WUFFS MULTI-FILE SECTION +arm_crc32 // -------- func crc32.ieee_hasher.up_arm_crc32 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up_arm_crc32( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { wuffs_base__slice_u8 v_p = {0}; uint32_t v_s = 0; v_s = (4294967295u ^ self->private_impl.f_state); while ((((uint64_t)(a_x.len)) > 0u) && ((15u & ((uint32_t)(0xFFFu & (uintptr_t)(a_x.ptr)))) != 0u)) { v_s = __crc32b(v_s, a_x.ptr[0u]); a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 8; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 128) * 128)); while (v_p.ptr < i_end0_p) { v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; } v_p.len = 8; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 8) * 8)); while (v_p.ptr < i_end1_p) { v_s = __crc32d(v_s, wuffs_base__peek_u64le__no_bounds_check(v_p.ptr)); v_p.ptr += 8; } v_p.len = 1; const uint8_t* i_end2_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end2_p) { v_s = __crc32b(v_s, v_p.ptr[0u]); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_state = (4294967295u ^ v_s); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_CRC32) // ‼ WUFFS MULTI-FILE SECTION -arm_crc32 // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func crc32.ieee_hasher.up_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc32__ieee_hasher__up_x86_sse42( wuffs_crc32__ieee_hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_s = 0; __m128i v_kk = {0}; __m128i v_x0 = {0}; __m128i v_x1 = {0}; __m128i v_x2 = {0}; __m128i v_x3 = {0}; __m128i v_x4 = {0}; __m128i v_x5 = {0}; __m128i v_x6 = {0}; __m128i v_x7 = {0}; __m128i v_y0 = {0}; __m128i v_y1 = {0}; __m128i v_y2 = {0}; __m128i v_y3 = {0}; __m128i v_y4 = {0}; __m128i v_y5 = {0}; __m128i v_y6 = {0}; __m128i v_y7 = {0}; v_s = (4294967295u ^ self->private_impl.f_state); while ((((uint64_t)(a_x.len)) > 0u) && ((15u & ((uint32_t)(0xFFFu & (uintptr_t)(a_x.ptr)))) != 0u)) { v_s = (WUFFS_CRC32__IEEE_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ a_x.ptr[0u]))] ^ (v_s >> 8u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } if (((uint64_t)(a_x.len)) >= 128u) { v_x0 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u)); v_x1 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u)); v_x2 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u)); v_x3 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u)); v_x4 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 64u)); v_x5 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 80u)); v_x6 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 96u)); v_x7 = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 112u)); v_kk = _mm_set_epi32((int32_t)(0u), (int32_t)(2433674945u), (int32_t)(0u), (int32_t)(872412467u)); v_x0 = _mm_xor_si128(v_x0, _mm_cvtsi32_si128((int32_t)(v_s))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 128u); while (((uint64_t)(a_x.len)) >= 128u) { v_y0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(0u)); v_x0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(17u)); v_y1 = _mm_clmulepi64_si128(v_x1, v_kk, (int32_t)(0u)); v_x1 = _mm_clmulepi64_si128(v_x1, v_kk, (int32_t)(17u)); v_y2 = _mm_clmulepi64_si128(v_x2, v_kk, (int32_t)(0u)); v_x2 = _mm_clmulepi64_si128(v_x2, v_kk, (int32_t)(17u)); v_y3 = _mm_clmulepi64_si128(v_x3, v_kk, (int32_t)(0u)); v_x3 = _mm_clmulepi64_si128(v_x3, v_kk, (int32_t)(17u)); v_y4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(0u)); v_x4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(17u)); v_y5 = _mm_clmulepi64_si128(v_x5, v_kk, (int32_t)(0u)); v_x5 = _mm_clmulepi64_si128(v_x5, v_kk, (int32_t)(17u)); v_y6 = _mm_clmulepi64_si128(v_x6, v_kk, (int32_t)(0u)); v_x6 = _mm_clmulepi64_si128(v_x6, v_kk, (int32_t)(17u)); v_y7 = _mm_clmulepi64_si128(v_x7, v_kk, (int32_t)(0u)); v_x7 = _mm_clmulepi64_si128(v_x7, v_kk, (int32_t)(17u)); v_y0 = _mm_xor_si128(v_y0, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u))); v_x0 = _mm_xor_si128(v_x0, v_y0); v_y1 = _mm_xor_si128(v_y1, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u))); v_x1 = _mm_xor_si128(v_x1, v_y1); v_y2 = _mm_xor_si128(v_y2, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u))); v_x2 = _mm_xor_si128(v_x2, v_y2); v_y3 = _mm_xor_si128(v_y3, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u))); v_x3 = _mm_xor_si128(v_x3, v_y3); v_y4 = _mm_xor_si128(v_y4, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 64u))); v_x4 = _mm_xor_si128(v_x4, v_y4); v_y5 = _mm_xor_si128(v_y5, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 80u))); v_x5 = _mm_xor_si128(v_x5, v_y5); v_y6 = _mm_xor_si128(v_y6, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 96u))); v_x6 = _mm_xor_si128(v_x6, v_y6); v_y7 = _mm_xor_si128(v_y7, _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 112u))); v_x7 = _mm_xor_si128(v_x7, v_y7); a_x = wuffs_base__slice_u8__subslice_i(a_x, 128u); } v_kk = _mm_set_epi32((int32_t)(0u), (int32_t)(3433693342u), (int32_t)(0u), (int32_t)(2926088593u)); v_y0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(0u)); v_x0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(17u)); v_y2 = _mm_clmulepi64_si128(v_x2, v_kk, (int32_t)(0u)); v_x2 = _mm_clmulepi64_si128(v_x2, v_kk, (int32_t)(17u)); v_y4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(0u)); v_x4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(17u)); v_y6 = _mm_clmulepi64_si128(v_x6, v_kk, (int32_t)(0u)); v_x6 = _mm_clmulepi64_si128(v_x6, v_kk, (int32_t)(17u)); v_y0 = _mm_xor_si128(v_y0, v_x1); v_x0 = _mm_xor_si128(v_x0, v_y0); v_y2 = _mm_xor_si128(v_y2, v_x3); v_x2 = _mm_xor_si128(v_x2, v_y2); v_y4 = _mm_xor_si128(v_y4, v_x5); v_x4 = _mm_xor_si128(v_x4, v_y4); v_y6 = _mm_xor_si128(v_y6, v_x7); v_x6 = _mm_xor_si128(v_x6, v_y6); v_kk = _mm_set_epi32((int32_t)(0u), (int32_t)(2166711591u), (int32_t)(0u), (int32_t)(4057597354u)); v_y0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(0u)); v_x0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(17u)); v_y4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(0u)); v_x4 = _mm_clmulepi64_si128(v_x4, v_kk, (int32_t)(17u)); v_y0 = _mm_xor_si128(v_y0, v_x2); v_x0 = _mm_xor_si128(v_x0, v_y0); v_y4 = _mm_xor_si128(v_y4, v_x6); v_x4 = _mm_xor_si128(v_x4, v_y4); v_kk = _mm_set_epi32((int32_t)(0u), (int32_t)(496309207u), (int32_t)(0u), (int32_t)(2402626965u)); v_y0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(0u)); v_x0 = _mm_clmulepi64_si128(v_x0, v_kk, (int32_t)(17u)); v_y0 = _mm_xor_si128(v_y0, v_x4); v_x0 = _mm_xor_si128(v_x0, v_y0); v_kk = _mm_set_epi32((int32_t)(1u), (int32_t)(3681617473u), (int32_t)(3034951717u), (int32_t)(4144043585u)); v_s = ((uint32_t)(_mm_extract_epi32(_mm_clmulepi64_si128(_mm_clmulepi64_si128(_mm_cvtsi64_si128((int64_t)(((uint64_t)(_mm_extract_epi64(v_x0, (int32_t)(0u)))))), v_kk, (int32_t)(0u)), v_kk, (int32_t)(16u)), (int32_t)(2u)))); v_kk = _mm_set_epi32((int32_t)(1u), (int32_t)(3681617473u), (int32_t)(3034951717u), (int32_t)(4144043585u)); v_s = ((uint32_t)(_mm_extract_epi32(_mm_clmulepi64_si128(_mm_clmulepi64_si128(_mm_cvtsi64_si128((int64_t)((((uint64_t)(_mm_extract_epi64(v_x0, (int32_t)(1u)))) ^ ((uint64_t)(v_s))))), v_kk, (int32_t)(0u)), v_kk, (int32_t)(16u)), (int32_t)(2u)))); } while (((uint64_t)(a_x.len)) >= 8u) { v_kk = _mm_set_epi32((int32_t)(1u), (int32_t)(3681617473u), (int32_t)(3034951717u), (int32_t)(4144043585u)); v_s = ((uint32_t)(_mm_extract_epi32(_mm_clmulepi64_si128(_mm_clmulepi64_si128(_mm_cvtsi64_si128((int64_t)((wuffs_base__peek_u64le__no_bounds_check(a_x.ptr) ^ ((uint64_t)(v_s))))), v_kk, (int32_t)(0u)), v_kk, (int32_t)(16u)), (int32_t)(2u)))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 8u); } while (((uint64_t)(a_x.len)) > 0u) { v_s = (WUFFS_CRC32__IEEE_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ a_x.ptr[0u]))] ^ (v_s >> 8u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } self->private_impl.f_state = (4294967295u ^ v_s); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC32) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC64) // ---------------- Status Codes Implementations // ---------------- Private Consts static const uint64_t WUFFS_CRC64__ECMA_TABLE[8][256] WUFFS_BASE__POTENTIALLY_UNUSED = { { 0u, 12911341560706588527u, 17619267392293085275u, 5164075066763771700u, 8921845837811637811u, 14483170935171449180u, 10328150133527543400u, 4357999468653093127u, 17843691675623275622u, 4940391307328217865u, 226782375002905661u, 12685511915359257426u, 10119945210068853333u, 4566377562367245626u, 8715998937306186254u, 14689403211693301089u, 9051005139383707209u, 14895072503764629798u, 9880782614656435730u, 4193374422961527165u, 453564750005811322u, 13070904082541799189u, 17496296445768931361u, 4747102235666401102u, 9960315520700766767u, 4113029525020509504u, 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4629793036166665723u, 11168576964637084347u, 15347691128931141778u, 1027777753507534802u, 17534896747071563927u, 3019349226222860247u, 11220431689754577048u, 4686116923914377176u, 13552315720802183325u, 7398828111596124125u, 5362628359632734342u, 10436379358185592774u, 7912374160093407363u, 13218332977821366211u, 369553541361633420u, 16113456511805446092u, 2487515902914439305u, 17887166489985742793u, 8865757316743550527u, 11653040814255671679u, 6677988576850966074u, 9660905738751846778u, 3765703796660934197u, 17220887603689539957u, 1434383093523822128u, 14508740362393577840u, 16546065181022836267u, 4549193289962883435u, 13995757083443852846u, 1766676892172462446u, 12309576339732698657u, 8100554995509053793u, 10192175931700983332u, 6327407589325138276u, }, }; static const uint8_t WUFFS_CRC64__ECMA_X86_SSE42_FOLD1[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 228u, 58u, 57u, 202u, 151u, 212u, 93u, 224u, 64u, 95u, 135u, 199u, 175u, 149u, 190u, 218u, }; static const uint8_t WUFFS_CRC64__ECMA_X86_SSE42_FOLD2[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 68u, 250u, 158u, 138u, 0u, 91u, 9u, 96u, 81u, 175u, 225u, 15u, 163u, 83u, 230u, 59u, }; static const uint8_t WUFFS_CRC64__ECMA_X86_SSE42_FOLD4[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 243u, 65u, 212u, 157u, 187u, 239u, 227u, 106u, 244u, 45u, 132u, 167u, 84u, 96u, 31u, 8u, }; static const uint8_t WUFFS_CRC64__ECMA_X86_SSE42_FOLD8[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 16u, 204u, 79u, 29u, 215u, 87u, 135u, 64u, 231u, 61u, 247u, 42u, 107u, 216u, 215u, }; static const uint8_t WUFFS_CRC64__ECMA_X86_SSE42_MUPX[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 213u, 99u, 41u, 23u, 108u, 70u, 62u, 156u, 133u, 30u, 14u, 175u, 43u, 175u, 216u, 146u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up__choosy_default( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up_x86_sse42( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ---------------- VTables const wuffs_base__hasher_u64__func_ptrs wuffs_crc64__ecma_hasher__func_ptrs_for__wuffs_base__hasher_u64 = { (uint64_t(*)(const void*))(&wuffs_crc64__ecma_hasher__checksum_u64), (uint64_t(*)(const void*, uint32_t))(&wuffs_crc64__ecma_hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_crc64__ecma_hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_crc64__ecma_hasher__update), (uint64_t(*)(void*, wuffs_base__slice_u8))(&wuffs_crc64__ecma_hasher__update_u64), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_crc64__ecma_hasher__initialize( wuffs_crc64__ecma_hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_up = &wuffs_crc64__ecma_hasher__up__choosy_default; self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_u64.vtable_name = wuffs_base__hasher_u64__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_u64.function_pointers = (const void*)(&wuffs_crc64__ecma_hasher__func_ptrs_for__wuffs_base__hasher_u64); return wuffs_base__make_status(NULL); } wuffs_crc64__ecma_hasher* wuffs_crc64__ecma_hasher__alloc(void) { wuffs_crc64__ecma_hasher* x = (wuffs_crc64__ecma_hasher*)(calloc(1, sizeof(wuffs_crc64__ecma_hasher))); if (!x) { return NULL; } if (wuffs_crc64__ecma_hasher__initialize( x, sizeof(wuffs_crc64__ecma_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_crc64__ecma_hasher(void) { return sizeof(wuffs_crc64__ecma_hasher); } // ---------------- Function Implementations // -------- func crc64.ecma_hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__get_quirk( const wuffs_crc64__ecma_hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func crc64.ecma_hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_crc64__ecma_hasher__set_quirk( wuffs_crc64__ecma_hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func crc64.ecma_hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_crc64__ecma_hasher__update( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if (self->private_impl.f_state == 0u) { self->private_impl.choosy_up = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_crc64__ecma_hasher__up_x86_sse42 : #endif self->private_impl.choosy_up); } wuffs_crc64__ecma_hasher__up(self, a_x); return wuffs_base__make_empty_struct(); } // -------- func crc64.ecma_hasher.update_u64 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__update_u64( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } wuffs_crc64__ecma_hasher__update(self, a_x); return wuffs_crc64__ecma_hasher__checksum_u64(self); } // -------- func crc64.ecma_hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x) { return (*self->private_impl.choosy_up)(self, a_x); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up__choosy_default( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x) { uint64_t v_s = 0; wuffs_base__slice_u8 v_p = {0}; v_s = (18446744073709551615u ^ self->private_impl.f_state); { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 8; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 8) * 8)); while (v_p.ptr < i_end0_p) { v_s ^= ((((uint64_t)(v_p.ptr[0u])) << 0u) | (((uint64_t)(v_p.ptr[1u])) << 8u) | (((uint64_t)(v_p.ptr[2u])) << 16u) | (((uint64_t)(v_p.ptr[3u])) << 24u) | (((uint64_t)(v_p.ptr[4u])) << 32u) | (((uint64_t)(v_p.ptr[5u])) << 40u) | (((uint64_t)(v_p.ptr[6u])) << 48u) | (((uint64_t)(v_p.ptr[7u])) << 56u)); v_s = (WUFFS_CRC64__ECMA_TABLE[0u][(255u & (v_s >> 56u))] ^ WUFFS_CRC64__ECMA_TABLE[1u][(255u & (v_s >> 48u))] ^ WUFFS_CRC64__ECMA_TABLE[2u][(255u & (v_s >> 40u))] ^ WUFFS_CRC64__ECMA_TABLE[3u][(255u & (v_s >> 32u))] ^ WUFFS_CRC64__ECMA_TABLE[4u][(255u & (v_s >> 24u))] ^ WUFFS_CRC64__ECMA_TABLE[5u][(255u & (v_s >> 16u))] ^ WUFFS_CRC64__ECMA_TABLE[6u][(255u & (v_s >> 8u))] ^ WUFFS_CRC64__ECMA_TABLE[7u][(255u & (v_s >> 0u))]); v_p.ptr += 8; } v_p.len = 1; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end1_p) { v_s = (WUFFS_CRC64__ECMA_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ v_p.ptr[0u]))] ^ (v_s >> 8u)); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_state = (18446744073709551615u ^ v_s); return wuffs_base__make_empty_struct(); } // -------- func crc64.ecma_hasher.checksum_u64 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_crc64__ecma_hasher__checksum_u64( const wuffs_crc64__ecma_hasher* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_state; } // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func crc64.ecma_hasher.up_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_crc64__ecma_hasher__up_x86_sse42( wuffs_crc64__ecma_hasher* self, wuffs_base__slice_u8 a_x) { uint64_t v_s = 0; wuffs_base__slice_u8 v_p = {0}; uint8_t v_buf[48] = {0}; __m128i v_xa = {0}; __m128i v_xb = {0}; __m128i v_xc = {0}; __m128i v_xd = {0}; __m128i v_xe = {0}; __m128i v_xf = {0}; __m128i v_xg = {0}; __m128i v_xh = {0}; __m128i v_mu1 = {0}; __m128i v_mu2 = {0}; __m128i v_mu4 = {0}; __m128i v_mu8 = {0}; __m128i v_mupx = {0}; v_s = (18446744073709551615u ^ self->private_impl.f_state); while ((((uint64_t)(a_x.len)) > 0u) && ((15u & ((uint32_t)(0xFFFu & (uintptr_t)(a_x.ptr)))) != 0u)) { v_s = (WUFFS_CRC64__ECMA_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ a_x.ptr[0u]))] ^ (v_s >> 8u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } do { do { if (((uint64_t)(a_x.len)) >= 128u) { } else if (((uint64_t)(a_x.len)) >= 64u) { v_xa = _mm_xor_si128(_mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u)), _mm_cvtsi64_si128((int64_t)(v_s))); v_xb = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u)); v_xc = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u)); v_xd = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 64u); break; } else if (((uint64_t)(a_x.len)) >= 32u) { v_xa = _mm_xor_si128(_mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u)), _mm_cvtsi64_si128((int64_t)(v_s))); v_xb = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 32u); goto label__chain2__break; } else { { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 1; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end0_p) { v_s = (WUFFS_CRC64__ECMA_TABLE[0u][((uint8_t)(((uint8_t)(v_s)) ^ v_p.ptr[0u]))] ^ (v_s >> 8u)); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_state = (18446744073709551615u ^ v_s); return wuffs_base__make_empty_struct(); } v_xa = _mm_xor_si128(_mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u)), _mm_cvtsi64_si128((int64_t)(v_s))); v_xb = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u)); v_xc = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u)); v_xd = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u)); v_xe = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 64u)); v_xf = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 80u)); v_xg = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 96u)); v_xh = _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 112u)); a_x = wuffs_base__slice_u8__subslice_i(a_x, 128u); v_mu8 = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_FOLD8)); while (((uint64_t)(a_x.len)) >= 128u) { v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u))); v_xb = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u))); v_xc = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xc, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xc, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u))); v_xd = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xd, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xd, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u))); v_xe = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xe, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xe, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 64u))); v_xf = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xf, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xf, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 80u))); v_xg = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xg, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xg, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 96u))); v_xh = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xh, v_mu8, (int32_t)(0u)), _mm_clmulepi64_si128(v_xh, v_mu8, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 112u))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 128u); } v_mu4 = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_FOLD4)); v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu4, (int32_t)(17u))), v_xe); v_xb = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu4, (int32_t)(17u))), v_xf); v_xc = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xc, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xc, v_mu4, (int32_t)(17u))), v_xg); v_xd = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xd, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xd, v_mu4, (int32_t)(17u))), v_xh); if (((uint64_t)(a_x.len)) > 64u) { v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu4, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u))); v_xb = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu4, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u))); v_xc = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xc, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xc, v_mu4, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 32u))); v_xd = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xd, v_mu4, (int32_t)(0u)), _mm_clmulepi64_si128(v_xd, v_mu4, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 48u))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 64u); } } while (0); v_mu2 = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_FOLD2)); v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(17u))), v_xc); v_xb = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu2, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu2, (int32_t)(17u))), v_xd); if (((uint64_t)(a_x.len)) > 32u) { v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u))); v_xb = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu2, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu2, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 16u))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 32u); } } while (0); label__chain2__break:; v_mu1 = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_FOLD1)); v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu1, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu1, (int32_t)(17u))), v_xb); if (((uint64_t)(a_x.len)) > 24u) { v_xa = _mm_xor_si128(_mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu1, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu1, (int32_t)(17u))), _mm_lddqu_si128((const __m128i*)(const void*)(a_x.ptr + 0u))); a_x = wuffs_base__slice_u8__subslice_i(a_x, 16u); if (((uint64_t)(a_x.len)) > 24u) { return wuffs_base__make_empty_struct(); } } _mm_storeu_si128((__m128i*)(void*)(v_buf + (24u - ((uint64_t)(a_x.len)))), v_xa); wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(v_buf, ((24u - ((uint64_t)(a_x.len))) + 16u), 48), a_x); v_mu2 = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_FOLD2)); v_xa = _mm_lddqu_si128((const __m128i*)(const void*)(v_buf + 0u)); v_xb = _mm_lddqu_si128((const __m128i*)(const void*)(v_buf + 16u)); v_xc = _mm_lddqu_si128((const __m128i*)(const void*)(v_buf + 32u)); v_xd = _mm_xor_si128(_mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(0u)), _mm_clmulepi64_si128(v_xa, v_mu2, (int32_t)(17u))); v_xe = _mm_xor_si128(_mm_clmulepi64_si128(v_xb, v_mu1, (int32_t)(0u)), _mm_clmulepi64_si128(v_xb, v_mu1, (int32_t)(17u))); v_xa = _mm_xor_si128(v_xd, _mm_xor_si128(v_xe, v_xc)); v_mupx = _mm_lddqu_si128((const __m128i*)(const void*)(WUFFS_CRC64__ECMA_X86_SSE42_MUPX)); v_xb = _mm_clmulepi64_si128(v_xa, v_mupx, (int32_t)(0u)); v_xc = _mm_clmulepi64_si128(v_xb, v_mupx, (int32_t)(16u)); v_s = ((uint64_t)(_mm_extract_epi64(_mm_xor_si128(_mm_xor_si128(v_xc, _mm_slli_si128(v_xb, (int32_t)(8u))), v_xa), (int32_t)(1u)))); self->private_impl.f_state = (18446744073709551615u ^ v_s); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__CRC64) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__DEFLATE) // ---------------- Status Codes Implementations const char wuffs_deflate__error__bad_huffman_code_over_subscribed[] = "#deflate: bad Huffman code (over-subscribed)"; const char wuffs_deflate__error__bad_huffman_code_under_subscribed[] = "#deflate: bad Huffman code (under-subscribed)"; const char wuffs_deflate__error__bad_huffman_code_length_count[] = "#deflate: bad Huffman code length count"; const char wuffs_deflate__error__bad_huffman_code_length_repetition[] = "#deflate: bad Huffman code length repetition"; const char wuffs_deflate__error__bad_huffman_code[] = "#deflate: bad Huffman code"; const char wuffs_deflate__error__bad_huffman_minimum_code_length[] = "#deflate: bad Huffman minimum code length"; const char wuffs_deflate__error__bad_block[] = "#deflate: bad block"; const char wuffs_deflate__error__bad_distance[] = "#deflate: bad distance"; const char wuffs_deflate__error__bad_distance_code_count[] = "#deflate: bad distance code count"; const char wuffs_deflate__error__bad_literal_length_code_count[] = "#deflate: bad literal/length code count"; const char wuffs_deflate__error__inconsistent_stored_block_length[] = "#deflate: inconsistent stored block length"; const char wuffs_deflate__error__missing_end_of_block_code[] = "#deflate: missing end-of-block code"; const char wuffs_deflate__error__no_huffman_codes[] = "#deflate: no Huffman codes"; const char wuffs_deflate__error__truncated_input[] = "#deflate: truncated input"; const char wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state[] = "#deflate: internal error: inconsistent Huffman decoder state"; const char wuffs_deflate__error__internal_error_inconsistent_i_o[] = "#deflate: internal error: inconsistent I/O"; const char wuffs_deflate__error__internal_error_inconsistent_distance[] = "#deflate: internal error: inconsistent distance"; const char wuffs_deflate__error__internal_error_inconsistent_n_bits[] = "#deflate: internal error: inconsistent n_bits"; // ---------------- Private Consts static const uint8_t WUFFS_DEFLATE__CODE_ORDER[19] WUFFS_BASE__POTENTIALLY_UNUSED = { 16u, 17u, 18u, 0u, 8u, 7u, 9u, 6u, 10u, 5u, 11u, 4u, 12u, 3u, 13u, 2u, 14u, 1u, 15u, }; static const uint8_t WUFFS_DEFLATE__REVERSE8[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 128u, 64u, 192u, 32u, 160u, 96u, 224u, 16u, 144u, 80u, 208u, 48u, 176u, 112u, 240u, 8u, 136u, 72u, 200u, 40u, 168u, 104u, 232u, 24u, 152u, 88u, 216u, 56u, 184u, 120u, 248u, 4u, 132u, 68u, 196u, 36u, 164u, 100u, 228u, 20u, 148u, 84u, 212u, 52u, 180u, 116u, 244u, 12u, 140u, 76u, 204u, 44u, 172u, 108u, 236u, 28u, 156u, 92u, 220u, 60u, 188u, 124u, 252u, 2u, 130u, 66u, 194u, 34u, 162u, 98u, 226u, 18u, 146u, 82u, 210u, 50u, 178u, 114u, 242u, 10u, 138u, 74u, 202u, 42u, 170u, 106u, 234u, 26u, 154u, 90u, 218u, 58u, 186u, 122u, 250u, 6u, 134u, 70u, 198u, 38u, 166u, 102u, 230u, 22u, 150u, 86u, 214u, 54u, 182u, 118u, 246u, 14u, 142u, 78u, 206u, 46u, 174u, 110u, 238u, 30u, 158u, 94u, 222u, 62u, 190u, 126u, 254u, 1u, 129u, 65u, 193u, 33u, 161u, 97u, 225u, 17u, 145u, 81u, 209u, 49u, 177u, 113u, 241u, 9u, 137u, 73u, 201u, 41u, 169u, 105u, 233u, 25u, 153u, 89u, 217u, 57u, 185u, 121u, 249u, 5u, 133u, 69u, 197u, 37u, 165u, 101u, 229u, 21u, 149u, 85u, 213u, 53u, 181u, 117u, 245u, 13u, 141u, 77u, 205u, 45u, 173u, 109u, 237u, 29u, 157u, 93u, 221u, 61u, 189u, 125u, 253u, 3u, 131u, 67u, 195u, 35u, 163u, 99u, 227u, 19u, 147u, 83u, 211u, 51u, 179u, 115u, 243u, 11u, 139u, 75u, 203u, 43u, 171u, 107u, 235u, 27u, 155u, 91u, 219u, 59u, 187u, 123u, 251u, 7u, 135u, 71u, 199u, 39u, 167u, 103u, 231u, 23u, 151u, 87u, 215u, 55u, 183u, 119u, 247u, 15u, 143u, 79u, 207u, 47u, 175u, 111u, 239u, 31u, 159u, 95u, 223u, 63u, 191u, 127u, 255u, }; static const uint32_t WUFFS_DEFLATE__LCODE_MAGIC_NUMBERS[32] WUFFS_BASE__POTENTIALLY_UNUSED = { 1073741824u, 1073742080u, 1073742336u, 1073742592u, 1073742848u, 1073743104u, 1073743360u, 1073743616u, 1073743888u, 1073744400u, 1073744912u, 1073745424u, 1073745952u, 1073746976u, 1073748000u, 1073749024u, 1073750064u, 1073752112u, 1073754160u, 1073756208u, 1073758272u, 1073762368u, 1073766464u, 1073770560u, 1073774672u, 1073782864u, 1073791056u, 1073799248u, 1073807104u, 134217728u, 134217728u, 134217728u, }; static const uint32_t WUFFS_DEFLATE__DCODE_MAGIC_NUMBERS[32] WUFFS_BASE__POTENTIALLY_UNUSED = { 1073741824u, 1073742080u, 1073742336u, 1073742592u, 1073742864u, 1073743376u, 1073743904u, 1073744928u, 1073745968u, 1073748016u, 1073750080u, 1073754176u, 1073758288u, 1073766480u, 1073774688u, 1073791072u, 1073807472u, 1073840240u, 1073873024u, 1073938560u, 1074004112u, 1074135184u, 1074266272u, 1074528416u, 1074790576u, 1075314864u, 1075839168u, 1076887744u, 1077936336u, 1080033488u, 134217728u, 134217728u, }; #define WUFFS_DEFLATE__HUFFS_TABLE_SIZE 1024u #define WUFFS_DEFLATE__HUFFS_TABLE_MASK 1023u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__do_transform_io( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_blocks( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_uncompressed( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_fixed_huffman( wuffs_deflate__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_dynamic_huffman( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_huff( wuffs_deflate__decoder* self, uint32_t a_which, uint32_t a_n_codes0, uint32_t a_n_codes1, uint32_t a_base_symbol); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_bmi2( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast32( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast64( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast64__choosy_default( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_slow( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_deflate__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_deflate__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_deflate__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_deflate__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_deflate__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_deflate__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_deflate__decoder__initialize( wuffs_deflate__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_decode_huffman_fast64 = &wuffs_deflate__decoder__decode_huffman_fast64__choosy_default; self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_deflate__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_deflate__decoder* wuffs_deflate__decoder__alloc(void) { wuffs_deflate__decoder* x = (wuffs_deflate__decoder*)(calloc(1, sizeof(wuffs_deflate__decoder))); if (!x) { return NULL; } if (wuffs_deflate__decoder__initialize( x, sizeof(wuffs_deflate__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_deflate__decoder(void) { return sizeof(wuffs_deflate__decoder); } // ---------------- Function Implementations // -------- func deflate.decoder.add_history WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_deflate__decoder__add_history( wuffs_deflate__decoder* self, wuffs_base__slice_u8 a_hist) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } wuffs_base__slice_u8 v_s = {0}; uint64_t v_n_copied = 0; uint32_t v_already_full = 0; v_s = a_hist; if (((uint64_t)(v_s.len)) >= 32768u) { v_s = wuffs_private_impl__slice_u8__suffix(v_s, 32768u); wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8(self->private_data.f_history, 32768), v_s); self->private_impl.f_history_index = 32768u; } else { v_n_copied = wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(self->private_data.f_history, (self->private_impl.f_history_index & 32767u), 32768), v_s); if (v_n_copied < ((uint64_t)(v_s.len))) { v_s = wuffs_base__slice_u8__subslice_i(v_s, v_n_copied); v_n_copied = wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8(self->private_data.f_history, 32768), v_s); self->private_impl.f_history_index = (((uint32_t)((v_n_copied & 32767u))) + 32768u); } else { v_already_full = 0u; if (self->private_impl.f_history_index >= 32768u) { v_already_full = 32768u; } self->private_impl.f_history_index = ((self->private_impl.f_history_index & 32767u) + ((uint32_t)((v_n_copied & 32767u))) + v_already_full); } } wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8_ij(self->private_data.f_history, 32768, 33025), wuffs_base__make_slice_u8(self->private_data.f_history, 33025)); return wuffs_base__make_empty_struct(); } // -------- func deflate.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_deflate__decoder__get_quirk( const wuffs_deflate__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func deflate.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_deflate__decoder__set_quirk( wuffs_deflate__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func deflate.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_deflate__decoder__dst_history_retain_length( const wuffs_deflate__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func deflate.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_deflate__decoder__workbuf_len( const wuffs_deflate__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(1u, 1u); } // -------- func deflate.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_deflate__decoder__transform_io( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_deflate__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_deflate__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func deflate.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__do_transform_io( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_mark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.choosy_decode_huffman_fast64 = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) wuffs_base__cpu_arch__have_x86_bmi2() ? &wuffs_deflate__decoder__decode_huffman_bmi2 : #endif self->private_impl.choosy_decode_huffman_fast64); while (true) { v_mark = ((uint64_t)(iop_a_dst - io0_a_dst)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } wuffs_base__status t_0 = wuffs_deflate__decoder__decode_blocks(self, a_dst, a_src); v_status = t_0; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } } if ( ! wuffs_base__status__is_suspension(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_transformed_history_count, wuffs_private_impl__io__count_since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst)))); wuffs_deflate__decoder__add_history(self, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } return status; } // -------- func deflate.decoder.decode_blocks WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_blocks( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_final = 0; uint32_t v_b0 = 0; uint32_t v_type = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_blocks; if (coro_susp_point) { v_final = self->private_data.s_decode_blocks.v_final; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; label__outer__continue:; while (v_final == 0u) { while (self->private_impl.f_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_0 = *iop_a_src++; v_b0 = t_0; } self->private_impl.f_bits |= (v_b0 << (self->private_impl.f_n_bits & 3u)); self->private_impl.f_n_bits = ((self->private_impl.f_n_bits & 3u) + 8u); } v_final = (self->private_impl.f_bits & 1u); v_type = ((self->private_impl.f_bits >> 1u) & 3u); self->private_impl.f_bits >>= 3u; self->private_impl.f_n_bits -= 3u; if (v_type == 0u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_deflate__decoder__decode_uncompressed(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else if (v_type == 1u) { v_status = wuffs_deflate__decoder__init_fixed_huffman(self); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } } else if (v_type == 2u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_deflate__decoder__init_dynamic_huffman(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_deflate__error__bad_block); goto exit; } self->private_impl.f_end_of_block = false; while (true) { if (sizeof(void*) == 4u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_deflate__decoder__decode_huffman_fast32(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } else { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_status = wuffs_deflate__decoder__decode_huffman_fast64(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } if (self->private_impl.f_end_of_block) { goto label__outer__continue; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_deflate__decoder__decode_huffman_slow(self, a_dst, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_end_of_block) { goto label__outer__continue; } } } ok: self->private_impl.p_decode_blocks = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_blocks = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_blocks.v_final = v_final; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func deflate.decoder.decode_uncompressed WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_uncompressed( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_length = 0; uint32_t v_n_copied = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_uncompressed; if (coro_susp_point) { v_length = self->private_data.s_decode_uncompressed.v_length; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_n_bits = 0u; self->private_impl.f_bits = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_uncompressed.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_uncompressed.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_length = t_0; } if ((((v_length) & 0xFFFFu) + ((v_length) >> (32u - 16u))) != 65535u) { status = wuffs_base__make_status(wuffs_deflate__error__inconsistent_stored_block_length); goto exit; } v_length = ((v_length) & 0xFFFFu); while (true) { v_n_copied = wuffs_private_impl__io_writer__limited_copy_u32_from_reader( &iop_a_dst, io2_a_dst,v_length, &iop_a_src, io2_a_src); if (v_length <= v_n_copied) { status = wuffs_base__make_status(NULL); goto ok; } v_length -= v_n_copied; if (((uint64_t)(io2_a_dst - iop_a_dst)) == 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); } else { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); } } ok: self->private_impl.p_decode_uncompressed = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_uncompressed = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_uncompressed.v_length = v_length; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func deflate.decoder.init_fixed_huffman WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_fixed_huffman( wuffs_deflate__decoder* self) { uint32_t v_i = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); while (v_i < 144u) { self->private_data.f_code_lengths[v_i] = 8u; v_i += 1u; } while (v_i < 256u) { self->private_data.f_code_lengths[v_i] = 9u; v_i += 1u; } while (v_i < 280u) { self->private_data.f_code_lengths[v_i] = 7u; v_i += 1u; } while (v_i < 288u) { self->private_data.f_code_lengths[v_i] = 8u; v_i += 1u; } while (v_i < 320u) { self->private_data.f_code_lengths[v_i] = 5u; v_i += 1u; } v_status = wuffs_deflate__decoder__init_huff(self, 0u, 0u, 288u, 257u); if (wuffs_base__status__is_error(&v_status)) { return v_status; } v_status = wuffs_deflate__decoder__init_huff(self, 1u, 288u, 320u, 0u); if (wuffs_base__status__is_error(&v_status)) { return v_status; } return wuffs_base__make_status(NULL); } // -------- func deflate.decoder.init_dynamic_huffman WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_dynamic_huffman( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_b0 = 0; uint32_t v_n_lit = 0; uint32_t v_n_dist = 0; uint32_t v_n_clen = 0; uint32_t v_i = 0; uint32_t v_b1 = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_mask = 0; uint32_t v_table_entry = 0; uint32_t v_table_entry_n_bits = 0; uint32_t v_b2 = 0; uint32_t v_n_extra_bits = 0; uint8_t v_rep_symbol = 0; uint32_t v_rep_count = 0; uint32_t v_b3 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_init_dynamic_huffman; if (coro_susp_point) { v_bits = self->private_data.s_init_dynamic_huffman.v_bits; v_n_bits = self->private_data.s_init_dynamic_huffman.v_n_bits; v_n_lit = self->private_data.s_init_dynamic_huffman.v_n_lit; v_n_dist = self->private_data.s_init_dynamic_huffman.v_n_dist; v_n_clen = self->private_data.s_init_dynamic_huffman.v_n_clen; v_i = self->private_data.s_init_dynamic_huffman.v_i; v_mask = self->private_data.s_init_dynamic_huffman.v_mask; v_n_extra_bits = self->private_data.s_init_dynamic_huffman.v_n_extra_bits; v_rep_symbol = self->private_data.s_init_dynamic_huffman.v_rep_symbol; v_rep_count = self->private_data.s_init_dynamic_huffman.v_rep_count; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_bits = self->private_impl.f_bits; v_n_bits = self->private_impl.f_n_bits; while (v_n_bits < 14u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_0 = *iop_a_src++; v_b0 = t_0; } v_bits |= (v_b0 << v_n_bits); v_n_bits += 8u; } v_n_lit = (((v_bits) & 0x1Fu) + 257u); if (v_n_lit > 286u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_literal_length_code_count); goto exit; } v_bits >>= 5u; v_n_dist = (((v_bits) & 0x1Fu) + 1u); if (v_n_dist > 30u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_distance_code_count); goto exit; } v_bits >>= 5u; v_n_clen = (((v_bits) & 0xFu) + 4u); v_bits >>= 4u; v_n_bits -= 14u; v_i = 0u; while (v_i < v_n_clen) { while (v_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_1 = *iop_a_src++; v_b1 = t_1; } v_bits |= (v_b1 << v_n_bits); v_n_bits += 8u; } self->private_data.f_code_lengths[WUFFS_DEFLATE__CODE_ORDER[v_i]] = ((uint8_t)((v_bits & 7u))); v_bits >>= 3u; v_n_bits -= 3u; v_i += 1u; } while (v_i < 19u) { self->private_data.f_code_lengths[WUFFS_DEFLATE__CODE_ORDER[v_i]] = 0u; v_i += 1u; } v_status = wuffs_deflate__decoder__init_huff(self, 0u, 0u, 19u, 4095u); if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } v_mask = ((((uint32_t)(1u)) << self->private_impl.f_n_huffs_bits[0u]) - 1u); v_i = 0u; while (v_i < (v_n_lit + v_n_dist)) { while (true) { v_table_entry = self->private_data.f_huffs[0u][(v_bits & v_mask)]; v_table_entry_n_bits = (v_table_entry & 15u); if (v_n_bits >= v_table_entry_n_bits) { v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_2 = *iop_a_src++; v_b2 = t_2; } v_bits |= (v_b2 << v_n_bits); v_n_bits += 8u; } if ((v_table_entry >> 24u) != 128u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_table_entry = ((v_table_entry >> 8u) & 255u); if (v_table_entry < 16u) { self->private_data.f_code_lengths[v_i] = ((uint8_t)(v_table_entry)); v_i += 1u; continue; } v_n_extra_bits = 0u; v_rep_symbol = 0u; v_rep_count = 0u; if (v_table_entry == 16u) { v_n_extra_bits = 2u; if (v_i <= 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code_length_repetition); goto exit; } v_rep_symbol = ((uint8_t)(self->private_data.f_code_lengths[(v_i - 1u)] & 15u)); v_rep_count = 3u; } else if (v_table_entry == 17u) { v_n_extra_bits = 3u; v_rep_symbol = 0u; v_rep_count = 3u; } else if (v_table_entry == 18u) { v_n_extra_bits = 7u; v_rep_symbol = 0u; v_rep_count = 11u; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } while (v_n_bits < v_n_extra_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_3 = *iop_a_src++; v_b3 = t_3; } v_bits |= (v_b3 << v_n_bits); v_n_bits += 8u; } v_rep_count += ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_n_extra_bits)); v_bits >>= v_n_extra_bits; v_n_bits -= v_n_extra_bits; while (v_rep_count > 0u) { if (v_i >= (v_n_lit + v_n_dist)) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code_length_count); goto exit; } self->private_data.f_code_lengths[v_i] = v_rep_symbol; v_i += 1u; v_rep_count -= 1u; } } if (v_i != (v_n_lit + v_n_dist)) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code_length_count); goto exit; } if (self->private_data.f_code_lengths[256u] == 0u) { status = wuffs_base__make_status(wuffs_deflate__error__missing_end_of_block_code); goto exit; } v_status = wuffs_deflate__decoder__init_huff(self, 0u, 0u, v_n_lit, 257u); if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } v_status = wuffs_deflate__decoder__init_huff(self, 1u, v_n_lit, (v_n_lit + v_n_dist), 0u); if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } self->private_impl.f_bits = v_bits; self->private_impl.f_n_bits = v_n_bits; goto ok; ok: self->private_impl.p_init_dynamic_huffman = 0; goto exit; } goto suspend; suspend: self->private_impl.p_init_dynamic_huffman = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_init_dynamic_huffman.v_bits = v_bits; self->private_data.s_init_dynamic_huffman.v_n_bits = v_n_bits; self->private_data.s_init_dynamic_huffman.v_n_lit = v_n_lit; self->private_data.s_init_dynamic_huffman.v_n_dist = v_n_dist; self->private_data.s_init_dynamic_huffman.v_n_clen = v_n_clen; self->private_data.s_init_dynamic_huffman.v_i = v_i; self->private_data.s_init_dynamic_huffman.v_mask = v_mask; self->private_data.s_init_dynamic_huffman.v_n_extra_bits = v_n_extra_bits; self->private_data.s_init_dynamic_huffman.v_rep_symbol = v_rep_symbol; self->private_data.s_init_dynamic_huffman.v_rep_count = v_rep_count; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func deflate.decoder.init_huff WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__init_huff( wuffs_deflate__decoder* self, uint32_t a_which, uint32_t a_n_codes0, uint32_t a_n_codes1, uint32_t a_base_symbol) { uint16_t v_counts[16] = {0}; uint32_t v_i = 0; uint32_t v_remaining = 0; uint16_t v_offsets[16] = {0}; uint32_t v_n_symbols = 0; uint32_t v_count = 0; uint16_t v_symbols[320] = {0}; uint32_t v_min_cl = 0; uint32_t v_max_cl = 0; uint32_t v_initial_high_bits = 0; uint32_t v_prev_cl = 0; uint32_t v_prev_redirect_key = 0; uint32_t v_top = 0; uint32_t v_next_top = 0; uint32_t v_code = 0; uint32_t v_key = 0; uint32_t v_value = 0; uint32_t v_cl = 0; uint32_t v_redirect_key = 0; uint32_t v_j = 0; uint32_t v_reversed_key = 0; uint32_t v_symbol = 0; uint32_t v_high_bits = 0; uint32_t v_delta = 0; v_i = a_n_codes0; while (v_i < a_n_codes1) { if (v_counts[((uint8_t)(self->private_data.f_code_lengths[v_i] & 15u))] >= 320u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_counts[((uint8_t)(self->private_data.f_code_lengths[v_i] & 15u))] += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_i += 1u; } if ((((uint32_t)(v_counts[0u])) + a_n_codes0) == a_n_codes1) { return wuffs_base__make_status(wuffs_deflate__error__no_huffman_codes); } v_remaining = 1u; v_i = 1u; while (v_i <= 15u) { if (v_remaining > 1073741824u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_remaining <<= 1u; if (v_remaining < ((uint32_t)(v_counts[v_i]))) { return wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code_over_subscribed); } v_remaining -= ((uint32_t)(v_counts[v_i])); v_i += 1u; } if (v_remaining != 0u) { if ((a_which == 1u) && (v_counts[1u] == 1u) && ((((uint32_t)(v_counts[0u])) + a_n_codes0 + 1u) == a_n_codes1)) { v_i = 0u; while (v_i <= 29u) { if (self->private_data.f_code_lengths[(a_n_codes0 + v_i)] == 1u) { self->private_impl.f_n_huffs_bits[1u] = 1u; self->private_data.f_huffs[1u][0u] = (WUFFS_DEFLATE__DCODE_MAGIC_NUMBERS[v_i] | 1u); self->private_data.f_huffs[1u][1u] = (WUFFS_DEFLATE__DCODE_MAGIC_NUMBERS[31u] | 1u); return wuffs_base__make_status(NULL); } v_i += 1u; } } return wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code_under_subscribed); } v_i = 1u; while (v_i <= 15u) { v_offsets[v_i] = ((uint16_t)(v_n_symbols)); v_count = ((uint32_t)(v_counts[v_i])); if (v_n_symbols > (320u - v_count)) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_n_symbols = (v_n_symbols + v_count); v_i += 1u; } if (v_n_symbols > 288u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_i = a_n_codes0; while (v_i < a_n_codes1) { if (v_i < a_n_codes0) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } if (self->private_data.f_code_lengths[v_i] != 0u) { if (v_offsets[((uint8_t)(self->private_data.f_code_lengths[v_i] & 15u))] >= 320u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_symbols[v_offsets[((uint8_t)(self->private_data.f_code_lengths[v_i] & 15u))]] = ((uint16_t)((v_i - a_n_codes0))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_offsets[((uint8_t)(self->private_data.f_code_lengths[v_i] & 15u))] += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } v_i += 1u; } v_min_cl = 1u; while (true) { if (v_counts[v_min_cl] != 0u) { break; } if (v_min_cl >= 9u) { return wuffs_base__make_status(wuffs_deflate__error__bad_huffman_minimum_code_length); } v_min_cl += 1u; } v_max_cl = 15u; while (true) { if (v_counts[v_max_cl] != 0u) { break; } if (v_max_cl <= 1u) { return wuffs_base__make_status(wuffs_deflate__error__no_huffman_codes); } v_max_cl -= 1u; } if (v_max_cl <= 9u) { self->private_impl.f_n_huffs_bits[a_which] = v_max_cl; } else { self->private_impl.f_n_huffs_bits[a_which] = 9u; } v_i = 0u; if ((v_n_symbols != ((uint32_t)(v_offsets[v_max_cl]))) || (v_n_symbols != ((uint32_t)(v_offsets[15u])))) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } if ((a_n_codes0 + ((uint32_t)(v_symbols[0u]))) >= 320u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_initial_high_bits = 512u; if (v_max_cl < 9u) { v_initial_high_bits = (((uint32_t)(1u)) << v_max_cl); } v_prev_cl = ((uint32_t)(((uint8_t)(self->private_data.f_code_lengths[(a_n_codes0 + ((uint32_t)(v_symbols[0u])))] & 15u)))); v_prev_redirect_key = 4294967295u; v_top = 0u; v_next_top = 512u; v_code = 0u; v_key = 0u; v_value = 0u; while (true) { if ((a_n_codes0 + ((uint32_t)(v_symbols[v_i]))) >= 320u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_cl = ((uint32_t)(((uint8_t)(self->private_data.f_code_lengths[(a_n_codes0 + ((uint32_t)(v_symbols[v_i])))] & 15u)))); if (v_cl > v_prev_cl) { v_code <<= (v_cl - v_prev_cl); if (v_code >= 32768u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } } v_prev_cl = v_cl; v_key = v_code; if (v_cl > 9u) { v_cl -= 9u; v_redirect_key = ((v_key >> v_cl) & 511u); v_key = ((v_key) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_cl)); if (v_prev_redirect_key != v_redirect_key) { v_prev_redirect_key = v_redirect_key; v_remaining = (((uint32_t)(1u)) << v_cl); v_j = v_prev_cl; while (v_j <= 15u) { if (v_remaining <= ((uint32_t)(v_counts[v_j]))) { break; } v_remaining -= ((uint32_t)(v_counts[v_j])); if (v_remaining > 1073741824u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_remaining <<= 1u; v_j += 1u; } if ((v_j <= 9u) || (15u < v_j)) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_j -= 9u; v_initial_high_bits = (((uint32_t)(1u)) << v_j); v_top = v_next_top; if ((v_top + (((uint32_t)(1u)) << v_j)) > 1024u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_next_top = (v_top + (((uint32_t)(1u)) << v_j)); v_redirect_key = (((uint32_t)(WUFFS_DEFLATE__REVERSE8[(v_redirect_key >> 1u)])) | ((v_redirect_key & 1u) << 8u)); self->private_data.f_huffs[a_which][v_redirect_key] = (268435465u | (v_top << 8u) | (v_j << 4u)); } } if ((v_key >= 512u) || (v_counts[v_prev_cl] <= 0u)) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_counts[v_prev_cl] -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_reversed_key = (((uint32_t)(WUFFS_DEFLATE__REVERSE8[(v_key >> 1u)])) | ((v_key & 1u) << 8u)); v_reversed_key >>= (9u - v_cl); v_symbol = ((uint32_t)(v_symbols[v_i])); if (v_symbol == 256u) { v_value = (536870912u | v_cl); } else if ((v_symbol < 256u) && (a_which == 0u)) { v_value = (2147483648u | (v_symbol << 8u) | v_cl); } else if (v_symbol >= a_base_symbol) { v_symbol -= a_base_symbol; if (a_which == 0u) { v_value = (WUFFS_DEFLATE__LCODE_MAGIC_NUMBERS[(v_symbol & 31u)] | v_cl); } else { v_value = (WUFFS_DEFLATE__DCODE_MAGIC_NUMBERS[(v_symbol & 31u)] | v_cl); } } else { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } v_high_bits = v_initial_high_bits; v_delta = (((uint32_t)(1u)) << v_cl); while (v_high_bits >= v_delta) { v_high_bits -= v_delta; if ((v_top + ((v_high_bits | v_reversed_key) & 511u)) >= 1024u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } self->private_data.f_huffs[a_which][(v_top + ((v_high_bits | v_reversed_key) & 511u))] = v_value; } v_i += 1u; if (v_i >= v_n_symbols) { break; } v_code += 1u; if (v_code >= 32768u) { return wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); } } return wuffs_base__make_status(NULL); } // ‼ WUFFS MULTI-FILE SECTION +x86_bmi2 // -------- func deflate.decoder.decode_huffman_bmi2 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("bmi2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_bmi2( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_table_entry = 0; uint32_t v_table_entry_n_bits = 0; uint64_t v_lmask = 0; uint64_t v_dmask = 0; uint32_t v_redir_top = 0; uint32_t v_redir_mask = 0; uint32_t v_length = 0; uint32_t v_dist_minus_1 = 0; uint32_t v_hlen = 0; uint32_t v_hdist = 0; uint32_t v_hdist_adjustment = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } v_bits = ((uint64_t)(self->private_impl.f_bits)); v_n_bits = self->private_impl.f_n_bits; v_lmask = ((((uint64_t)(1u)) << self->private_impl.f_n_huffs_bits[0u]) - 1u); v_dmask = ((((uint64_t)(1u)) << self->private_impl.f_n_huffs_bits[1u]) - 1u); if (self->private_impl.f_transformed_history_count < (a_dst ? a_dst->meta.pos : 0u)) { status = wuffs_base__make_status(wuffs_base__error__bad_i_o_position); goto exit; } v_hdist_adjustment = ((uint32_t)((self->private_impl.f_transformed_history_count - (a_dst ? a_dst->meta.pos : 0u)))); label__loop__continue:; while ((((uint64_t)(io2_a_dst - iop_a_dst)) >= 266u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 8u)) { v_bits |= ((uint64_t)(wuffs_base__peek_u64le__no_bounds_check(iop_a_src) << (v_n_bits & 63u))); iop_a_src += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_table_entry = self->private_data.f_huffs[0u][(v_bits & v_lmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[0u][((v_redir_top + (((uint32_t)(v_bits)) & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_length = (((v_table_entry >> 8u) & 255u) + 3u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_table_entry_n_bits > 0u) { v_length = (((v_length + 253u + ((uint32_t)(((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64(v_table_entry_n_bits))))) & 255u) + 3u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } v_table_entry = self->private_data.f_huffs[1u][(v_bits & v_dmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 28u) == 1u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[1u][((v_redir_top + (((uint32_t)(v_bits)) & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } if ((v_table_entry >> 24u) != 64u) { if ((v_table_entry >> 24u) == 8u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_dist_minus_1 = ((v_table_entry >> 8u) & 32767u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); v_dist_minus_1 = ((v_dist_minus_1 + ((uint32_t)(((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64(v_table_entry_n_bits))))) & 32767u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; do { if (((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_hlen = 0u; v_hdist = ((uint32_t)((((uint64_t)((v_dist_minus_1 + 1u))) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_length > v_hdist) { v_length -= v_hdist; v_hlen = v_hdist; } else { v_hlen = v_length; v_length = 0u; } v_hdist += v_hdist_adjustment; if (self->private_impl.f_history_index < v_hdist) { status = wuffs_base__make_status(wuffs_deflate__error__bad_distance); goto exit; } wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_hlen, wuffs_base__make_slice_u8_ij(self->private_data.f_history, ((self->private_impl.f_history_index - v_hdist) & 32767u), 33025)); if (v_length == 0u) { goto label__loop__continue; } if ((((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) || (((uint64_t)(v_length)) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)((v_length + 8u))) > ((uint64_t)(io2_a_dst - iop_a_dst)))) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_distance); goto exit; } } if ((v_dist_minus_1 + 1u) >= 8u) { wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } else if ((v_dist_minus_1 + 1u) == 1u) { wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } else { wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } } while (0); } if (v_n_bits > 63u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } while (v_n_bits >= 8u) { v_n_bits -= 8u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_i_o); goto exit; } } self->private_impl.f_bits = ((uint32_t)((v_bits & ((((uint64_t)(1u)) << v_n_bits) - 1u)))); self->private_impl.f_n_bits = v_n_bits; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> self->private_impl.f_n_bits) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) // ‼ WUFFS MULTI-FILE SECTION -x86_bmi2 // -------- func deflate.decoder.decode_huffman_fast32 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast32( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_table_entry = 0; uint32_t v_table_entry_n_bits = 0; uint32_t v_lmask = 0; uint32_t v_dmask = 0; uint32_t v_redir_top = 0; uint32_t v_redir_mask = 0; uint32_t v_length = 0; uint32_t v_dist_minus_1 = 0; uint32_t v_hlen = 0; uint32_t v_hdist = 0; uint32_t v_hdist_adjustment = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } v_bits = self->private_impl.f_bits; v_n_bits = self->private_impl.f_n_bits; v_lmask = ((((uint32_t)(1u)) << self->private_impl.f_n_huffs_bits[0u]) - 1u); v_dmask = ((((uint32_t)(1u)) << self->private_impl.f_n_huffs_bits[1u]) - 1u); if (self->private_impl.f_transformed_history_count < (a_dst ? a_dst->meta.pos : 0u)) { status = wuffs_base__make_status(wuffs_base__error__bad_i_o_position); goto exit; } v_hdist_adjustment = ((uint32_t)((self->private_impl.f_transformed_history_count - (a_dst ? a_dst->meta.pos : 0u)))); label__loop__continue:; while ((((uint64_t)(io2_a_dst - iop_a_dst)) >= 266u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 12u)) { if (v_n_bits < 15u) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } else { } v_table_entry = self->private_data.f_huffs[0u][(v_bits & v_lmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { if (v_n_bits < 15u) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } else { } v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[0u][((v_redir_top + (v_bits & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_length = (((v_table_entry >> 8u) & 255u) + 3u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_table_entry_n_bits > 0u) { if (v_n_bits < 15u) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } else { } v_length = (((v_length + 253u + ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_table_entry_n_bits))) & 255u) + 3u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } else { } if (v_n_bits < 15u) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } else { } v_table_entry = self->private_data.f_huffs[1u][(v_bits & v_dmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 28u) == 1u) { if (v_n_bits < 15u) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } else { } v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[1u][((v_redir_top + (v_bits & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } else { } if ((v_table_entry >> 24u) != 64u) { if ((v_table_entry >> 24u) == 8u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_dist_minus_1 = ((v_table_entry >> 8u) & 32767u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_n_bits < v_table_entry_n_bits) { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; } v_dist_minus_1 = ((v_dist_minus_1 + ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_table_entry_n_bits))) & 32767u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; do { if (((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_hlen = 0u; v_hdist = ((uint32_t)((((uint64_t)((v_dist_minus_1 + 1u))) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_length > v_hdist) { v_length -= v_hdist; v_hlen = v_hdist; } else { v_hlen = v_length; v_length = 0u; } v_hdist += v_hdist_adjustment; if (self->private_impl.f_history_index < v_hdist) { status = wuffs_base__make_status(wuffs_deflate__error__bad_distance); goto exit; } wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_hlen, wuffs_base__make_slice_u8_ij(self->private_data.f_history, ((self->private_impl.f_history_index - v_hdist) & 32767u), 33025)); if (v_length == 0u) { goto label__loop__continue; } if ((((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) || (((uint64_t)(v_length)) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)((v_length + 8u))) > ((uint64_t)(io2_a_dst - iop_a_dst)))) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_distance); goto exit; } } if ((v_dist_minus_1 + 1u) >= 8u) { wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } else { wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } } while (0); } while (v_n_bits >= 8u) { v_n_bits -= 8u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_i_o); goto exit; } } self->private_impl.f_bits = (v_bits & ((((uint32_t)(1u)) << v_n_bits) - 1u)); self->private_impl.f_n_bits = v_n_bits; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> self->private_impl.f_n_bits) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func deflate.decoder.decode_huffman_fast64 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast64( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { return (*self->private_impl.choosy_decode_huffman_fast64)(self, a_dst, a_src); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_fast64__choosy_default( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_table_entry = 0; uint32_t v_table_entry_n_bits = 0; uint64_t v_lmask = 0; uint64_t v_dmask = 0; uint32_t v_redir_top = 0; uint32_t v_redir_mask = 0; uint32_t v_length = 0; uint32_t v_dist_minus_1 = 0; uint32_t v_hlen = 0; uint32_t v_hdist = 0; uint32_t v_hdist_adjustment = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } v_bits = ((uint64_t)(self->private_impl.f_bits)); v_n_bits = self->private_impl.f_n_bits; v_lmask = ((((uint64_t)(1u)) << self->private_impl.f_n_huffs_bits[0u]) - 1u); v_dmask = ((((uint64_t)(1u)) << self->private_impl.f_n_huffs_bits[1u]) - 1u); if (self->private_impl.f_transformed_history_count < (a_dst ? a_dst->meta.pos : 0u)) { status = wuffs_base__make_status(wuffs_base__error__bad_i_o_position); goto exit; } v_hdist_adjustment = ((uint32_t)((self->private_impl.f_transformed_history_count - (a_dst ? a_dst->meta.pos : 0u)))); label__loop__continue:; while ((((uint64_t)(io2_a_dst - iop_a_dst)) >= 266u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 8u)) { v_bits |= ((uint64_t)(wuffs_base__peek_u64le__no_bounds_check(iop_a_src) << (v_n_bits & 63u))); iop_a_src += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_table_entry = self->private_data.f_huffs[0u][(v_bits & v_lmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[0u][((v_redir_top + (((uint32_t)(v_bits)) & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 31u) != 0u) { (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)((v_table_entry >> 8u)))), iop_a_dst += 1); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_length = (((v_table_entry >> 8u) & 255u) + 3u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_table_entry_n_bits > 0u) { v_length = (((v_length + 253u + ((uint32_t)(((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64(v_table_entry_n_bits))))) & 255u) + 3u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } v_table_entry = self->private_data.f_huffs[1u][(v_bits & v_dmask)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; if ((v_table_entry >> 28u) == 1u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); v_table_entry = self->private_data.f_huffs[1u][((v_redir_top + (((uint32_t)(v_bits)) & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } if ((v_table_entry >> 24u) != 64u) { if ((v_table_entry >> 24u) == 8u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_dist_minus_1 = ((v_table_entry >> 8u) & 32767u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); v_dist_minus_1 = ((v_dist_minus_1 + ((uint32_t)(((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U64(v_table_entry_n_bits))))) & 32767u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; do { if (((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_hlen = 0u; v_hdist = ((uint32_t)((((uint64_t)((v_dist_minus_1 + 1u))) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_length > v_hdist) { v_length -= v_hdist; v_hlen = v_hdist; } else { v_hlen = v_length; v_length = 0u; } v_hdist += v_hdist_adjustment; if (self->private_impl.f_history_index < v_hdist) { status = wuffs_base__make_status(wuffs_deflate__error__bad_distance); goto exit; } wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_hlen, wuffs_base__make_slice_u8_ij(self->private_data.f_history, ((self->private_impl.f_history_index - v_hdist) & 32767u), 33025)); if (v_length == 0u) { goto label__loop__continue; } if ((((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) || (((uint64_t)(v_length)) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)((v_length + 8u))) > ((uint64_t)(io2_a_dst - iop_a_dst)))) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_distance); goto exit; } } if ((v_dist_minus_1 + 1u) >= 8u) { wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } else if ((v_dist_minus_1 + 1u) == 1u) { wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_distance_1_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } else { wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); } } while (0); } if (v_n_bits > 63u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } while (v_n_bits >= 8u) { v_n_bits -= 8u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_i_o); goto exit; } } self->private_impl.f_bits = ((uint32_t)((v_bits & ((((uint64_t)(1u)) << v_n_bits) - 1u)))); self->private_impl.f_n_bits = v_n_bits; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> self->private_impl.f_n_bits) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func deflate.decoder.decode_huffman_slow WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_deflate__decoder__decode_huffman_slow( wuffs_deflate__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_table_entry = 0; uint32_t v_table_entry_n_bits = 0; uint32_t v_lmask = 0; uint32_t v_dmask = 0; uint32_t v_b0 = 0; uint32_t v_redir_top = 0; uint32_t v_redir_mask = 0; uint32_t v_b1 = 0; uint32_t v_length = 0; uint32_t v_b2 = 0; uint32_t v_b3 = 0; uint32_t v_b4 = 0; uint32_t v_dist_minus_1 = 0; uint32_t v_b5 = 0; uint32_t v_n_copied = 0; uint32_t v_hlen = 0; uint32_t v_hdist = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_huffman_slow; if (coro_susp_point) { v_bits = self->private_data.s_decode_huffman_slow.v_bits; v_n_bits = self->private_data.s_decode_huffman_slow.v_n_bits; v_table_entry_n_bits = self->private_data.s_decode_huffman_slow.v_table_entry_n_bits; v_lmask = self->private_data.s_decode_huffman_slow.v_lmask; v_dmask = self->private_data.s_decode_huffman_slow.v_dmask; v_redir_top = self->private_data.s_decode_huffman_slow.v_redir_top; v_redir_mask = self->private_data.s_decode_huffman_slow.v_redir_mask; v_length = self->private_data.s_decode_huffman_slow.v_length; v_dist_minus_1 = self->private_data.s_decode_huffman_slow.v_dist_minus_1; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } v_bits = self->private_impl.f_bits; v_n_bits = self->private_impl.f_n_bits; v_lmask = ((((uint32_t)(1u)) << self->private_impl.f_n_huffs_bits[0u]) - 1u); v_dmask = ((((uint32_t)(1u)) << self->private_impl.f_n_huffs_bits[1u]) - 1u); label__loop__continue:; while ( ! (self->private_impl.p_decode_huffman_slow != 0)) { while (true) { v_table_entry = self->private_data.f_huffs[0u][(v_bits & v_lmask)]; v_table_entry_n_bits = (v_table_entry & 15u); if (v_n_bits >= v_table_entry_n_bits) { v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_0 = *iop_a_src++; v_b0 = t_0; } v_bits |= (v_b0 << v_n_bits); v_n_bits += 8u; } if ((v_table_entry >> 31u) != 0u) { self->private_data.s_decode_huffman_slow.scratch = ((uint8_t)((v_table_entry >> 8u))); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (iop_a_dst == io2_a_dst) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); goto suspend; } *iop_a_dst++ = ((uint8_t)(self->private_data.s_decode_huffman_slow.scratch)); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); while (true) { v_table_entry = self->private_data.f_huffs[0u][((v_redir_top + (v_bits & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); if (v_n_bits >= v_table_entry_n_bits) { v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_1 = *iop_a_src++; v_b1 = t_1; } v_bits |= (v_b1 << v_n_bits); v_n_bits += 8u; } if ((v_table_entry >> 31u) != 0u) { self->private_data.s_decode_huffman_slow.scratch = ((uint8_t)((v_table_entry >> 8u))); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (iop_a_dst == io2_a_dst) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); goto suspend; } *iop_a_dst++ = ((uint8_t)(self->private_data.s_decode_huffman_slow.scratch)); continue; } else if ((v_table_entry >> 30u) != 0u) { } else if ((v_table_entry >> 29u) != 0u) { self->private_impl.f_end_of_block = true; break; } else if ((v_table_entry >> 28u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } } else if ((v_table_entry >> 27u) != 0u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } else { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_length = (((v_table_entry >> 8u) & 255u) + 3u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_table_entry_n_bits > 0u) { while (v_n_bits < v_table_entry_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_2 = *iop_a_src++; v_b2 = t_2; } v_bits |= (v_b2 << v_n_bits); v_n_bits += 8u; } v_length = (((v_length + 253u + ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_table_entry_n_bits))) & 255u) + 3u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } while (true) { v_table_entry = self->private_data.f_huffs[1u][(v_bits & v_dmask)]; v_table_entry_n_bits = (v_table_entry & 15u); if (v_n_bits >= v_table_entry_n_bits) { v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_3 = *iop_a_src++; v_b3 = t_3; } v_bits |= (v_b3 << v_n_bits); v_n_bits += 8u; } if ((v_table_entry >> 28u) == 1u) { v_redir_top = ((v_table_entry >> 8u) & 65535u); v_redir_mask = ((((uint32_t)(1u)) << ((v_table_entry >> 4u) & 15u)) - 1u); while (true) { v_table_entry = self->private_data.f_huffs[1u][((v_redir_top + (v_bits & v_redir_mask)) & 1023u)]; v_table_entry_n_bits = (v_table_entry & 15u); if (v_n_bits >= v_table_entry_n_bits) { v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_4 = *iop_a_src++; v_b4 = t_4; } v_bits |= (v_b4 << v_n_bits); v_n_bits += 8u; } } if ((v_table_entry >> 24u) != 64u) { if ((v_table_entry >> 24u) == 8u) { status = wuffs_base__make_status(wuffs_deflate__error__bad_huffman_code); goto exit; } status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_huffman_decoder_state); goto exit; } v_dist_minus_1 = ((v_table_entry >> 8u) & 32767u); v_table_entry_n_bits = ((v_table_entry >> 4u) & 15u); if (v_table_entry_n_bits > 0u) { while (v_n_bits < v_table_entry_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_5 = *iop_a_src++; v_b5 = t_5; } v_bits |= (v_b5 << v_n_bits); v_n_bits += 8u; } v_dist_minus_1 = ((v_dist_minus_1 + ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_table_entry_n_bits))) & 32767u); v_bits >>= v_table_entry_n_bits; v_n_bits -= v_table_entry_n_bits; } while (true) { if (((uint64_t)((v_dist_minus_1 + 1u))) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_hdist = ((uint32_t)((((uint64_t)((v_dist_minus_1 + 1u))) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_hdist < v_length) { v_hlen = v_hdist; } else { v_hlen = v_length; } v_hdist += ((uint32_t)(((uint64_t)(self->private_impl.f_transformed_history_count - (a_dst ? a_dst->meta.pos : 0u))))); if (self->private_impl.f_history_index < v_hdist) { status = wuffs_base__make_status(wuffs_deflate__error__bad_distance); goto exit; } v_n_copied = wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_hlen, wuffs_base__make_slice_u8_ij(self->private_data.f_history, ((self->private_impl.f_history_index - v_hdist) & 32767u), 33025)); if (v_n_copied < v_hlen) { v_length -= v_n_copied; status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); continue; } v_length -= v_hlen; if (v_length == 0u) { goto label__loop__continue; } } v_n_copied = wuffs_private_impl__io_writer__limited_copy_u32_from_history( &iop_a_dst, io0_a_dst, io2_a_dst, v_length, (v_dist_minus_1 + 1u)); if (v_length <= v_n_copied) { goto label__loop__continue; } v_length -= v_n_copied; status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); } } self->private_impl.f_bits = v_bits; self->private_impl.f_n_bits = v_n_bits; if ((self->private_impl.f_n_bits >= 8u) || ((self->private_impl.f_bits >> (self->private_impl.f_n_bits & 7u)) != 0u)) { status = wuffs_base__make_status(wuffs_deflate__error__internal_error_inconsistent_n_bits); goto exit; } ok: self->private_impl.p_decode_huffman_slow = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_huffman_slow = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_huffman_slow.v_bits = v_bits; self->private_data.s_decode_huffman_slow.v_n_bits = v_n_bits; self->private_data.s_decode_huffman_slow.v_table_entry_n_bits = v_table_entry_n_bits; self->private_data.s_decode_huffman_slow.v_lmask = v_lmask; self->private_data.s_decode_huffman_slow.v_dmask = v_dmask; self->private_data.s_decode_huffman_slow.v_redir_top = v_redir_top; self->private_data.s_decode_huffman_slow.v_redir_mask = v_redir_mask; self->private_data.s_decode_huffman_slow.v_length = v_length; self->private_data.s_decode_huffman_slow.v_dist_minus_1 = v_dist_minus_1; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__DEFLATE) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GIF) // ---------------- Status Codes Implementations const char wuffs_gif__error__bad_lzw_code[] = "#gif: bad LZW code"; const char wuffs_gif__error__bad_extension_label[] = "#gif: bad extension label"; const char wuffs_gif__error__bad_frame_size[] = "#gif: bad frame size"; const char wuffs_gif__error__bad_graphic_control[] = "#gif: bad graphic control"; const char wuffs_gif__error__bad_header[] = "#gif: bad header"; const char wuffs_gif__error__bad_literal_width[] = "#gif: bad literal width"; const char wuffs_gif__error__bad_palette[] = "#gif: bad palette"; const char wuffs_gif__error__truncated_input[] = "#gif: truncated input"; const char wuffs_gif__error__internal_error_inconsistent_i_o[] = "#gif: internal error: inconsistent I/O"; // ---------------- Private Consts static const uint32_t WUFFS_GIF__INTERLACE_START[5] WUFFS_BASE__POTENTIALLY_UNUSED = { 4294967295u, 1u, 2u, 4u, 0u, }; static const uint8_t WUFFS_GIF__INTERLACE_DELTA[5] WUFFS_BASE__POTENTIALLY_UNUSED = { 1u, 2u, 4u, 8u, 8u, }; static const uint8_t WUFFS_GIF__INTERLACE_COUNT[5] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 1u, 2u, 4u, 8u, }; static const uint8_t WUFFS_GIF__ANIMEXTS1DOT0[11] WUFFS_BASE__POTENTIALLY_UNUSED = { 65u, 78u, 73u, 77u, 69u, 88u, 84u, 83u, 49u, 46u, 48u, }; static const uint8_t WUFFS_GIF__NETSCAPE2DOT0[11] WUFFS_BASE__POTENTIALLY_UNUSED = { 78u, 69u, 84u, 83u, 67u, 65u, 80u, 69u, 50u, 46u, 48u, }; static const uint8_t WUFFS_GIF__ICCRGBG1012[11] WUFFS_BASE__POTENTIALLY_UNUSED = { 73u, 67u, 67u, 82u, 71u, 66u, 71u, 49u, 48u, 49u, 50u, }; static const uint8_t WUFFS_GIF__XMPDATAXMP[11] WUFFS_BASE__POTENTIALLY_UNUSED = { 88u, 77u, 80u, 32u, 68u, 97u, 116u, 97u, 88u, 77u, 80u, }; #define WUFFS_GIF__QUIRKS_BASE 1041635328u #define WUFFS_GIF__QUIRKS_COUNT 7u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_image_config( wuffs_gif__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_tell_me_more( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_frame_config( wuffs_gif__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__skip_frame( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_frame( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__reset_gc( wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_up_to_id_part1( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_header( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_lsd( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_extension( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__skip_blocks( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_ae( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_gc( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part0( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part1( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part2( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__copy_to_image_buffer( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_pb, wuffs_base__slice_u8 a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__lzw_init( wuffs_gif__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__lzw_read_from( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_gif__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_gif__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_gif__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_gif__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_gif__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_gif__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_gif__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_gif__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_gif__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_gif__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_gif__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_gif__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_gif__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_gif__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_gif__decoder__initialize( wuffs_gif__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_gif__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_gif__decoder* wuffs_gif__decoder__alloc(void) { wuffs_gif__decoder* x = (wuffs_gif__decoder*)(calloc(1, sizeof(wuffs_gif__decoder))); if (!x) { return NULL; } if (wuffs_gif__decoder__initialize( x, sizeof(wuffs_gif__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_gif__decoder(void) { return sizeof(wuffs_gif__decoder); } // ---------------- Function Implementations // -------- func gif.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__get_quirk( const wuffs_gif__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } uint32_t v_key = 0; if (a_key >= 1041635328u) { v_key = (a_key - 1041635328u); if (v_key < 7u) { if (self->private_impl.f_quirks[v_key]) { return 1u; } } } return 0u; } // -------- func gif.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__set_quirk( wuffs_gif__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if ((self->private_impl.f_call_sequence == 0u) && (a_key >= 1041635328u)) { a_key -= 1041635328u; if (a_key < 7u) { self->private_impl.f_quirks[a_key] = (a_value > 0u); return wuffs_base__make_status(NULL); } } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func gif.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_image_config( wuffs_gif__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_gif__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_gif__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func gif.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_image_config( wuffs_gif__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); bool v_ffio = false; uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if ( ! self->private_impl.f_seen_header) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_gif__decoder__decode_header(self, a_src); if (status.repr) { goto suspend; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_gif__decoder__decode_lsd(self, a_src); if (status.repr) { goto suspend; } self->private_impl.f_seen_header = true; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_gif__decoder__decode_up_to_id_part1(self, a_src); if (status.repr) { goto suspend; } v_ffio = ! self->private_impl.f_gc_has_transparent_index; if ( ! self->private_impl.f_quirks[2u]) { v_ffio = (v_ffio && (self->private_impl.f_frame_rect_x0 == 0u) && (self->private_impl.f_frame_rect_y0 == 0u) && (self->private_impl.f_frame_rect_x1 == self->private_impl.f_width) && (self->private_impl.f_frame_rect_y1 == self->private_impl.f_height)); } else if (v_ffio) { self->private_impl.f_black_color_u32_argb_premul = 4278190080u; } if (self->private_impl.f_background_color_u32_argb_premul == 77u) { self->private_impl.f_background_color_u32_argb_premul = self->private_impl.f_black_color_u32_argb_premul; } if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, 2198077448u, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, v_ffio); } if (self->private_impl.f_call_sequence == 0u) { self->private_impl.f_call_sequence = 32u; } goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func gif.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_gif__decoder__set_report_metadata( wuffs_gif__decoder* self, uint32_t a_fourcc, bool a_report) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if (a_fourcc == 1229144912u) { self->private_impl.f_report_metadata_iccp = a_report; } else if (a_fourcc == 1481461792u) { self->private_impl.f_report_metadata_xmp = a_report; } return wuffs_base__make_empty_struct(); } // -------- func gif.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__tell_me_more( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_tell_me_more; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_gif__decoder__do_tell_me_more(self, a_dst, a_minfo, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_gif__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_tell_me_more = 0; goto exit; } goto suspend; suspend: self->private_impl.p_tell_me_more = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func gif.decoder.do_tell_me_more WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_tell_me_more( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_chunk_length = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_tell_me_more; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (((uint8_t)(self->private_impl.f_call_sequence & 16u)) == 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } if (self->private_impl.f_metadata_fourcc == 0u) { status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; } while (true) { while (true) { if (wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))) != self->private_impl.f_metadata_io_position) { if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, 2u, 0u, self->private_impl.f_metadata_io_position, 0u, 0u); } status = wuffs_base__make_status(wuffs_base__suspension__mispositioned_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, 0u, 0u, 0u, 0u, 0u); } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); continue; } break; } v_chunk_length = ((uint64_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))); if (v_chunk_length <= 0u) { iop_a_src += 1u; break; } if (self->private_impl.f_metadata_fourcc == 1481461792u) { v_chunk_length += 1u; } else { iop_a_src += 1u; } self->private_impl.f_metadata_io_position = wuffs_base__u64__sat_add(wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))), v_chunk_length); if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, 3u, self->private_impl.f_metadata_fourcc, 0u, wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))), self->private_impl.f_metadata_io_position); } status = wuffs_base__make_status(wuffs_base__suspension__even_more_information); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); } if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, 3u, self->private_impl.f_metadata_fourcc, 0u, self->private_impl.f_metadata_io_position, self->private_impl.f_metadata_io_position); } self->private_impl.f_call_sequence &= 239u; self->private_impl.f_metadata_fourcc = 0u; self->private_impl.f_metadata_io_position = 0u; status = wuffs_base__make_status(NULL); goto ok; ok: self->private_impl.p_do_tell_me_more = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_tell_me_more = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_gif__decoder__num_animation_loops( const wuffs_gif__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_seen_num_animation_loops_value) { return self->private_impl.f_num_animation_loops_value; } if (self->private_impl.f_num_decoded_frame_configs_value > 1u) { return 1u; } return 0u; } // -------- func gif.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__num_decoded_frame_configs( const wuffs_gif__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_num_decoded_frame_configs_value; } // -------- func gif.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gif__decoder__num_decoded_frames( const wuffs_gif__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_num_decoded_frames_value; } // -------- func gif.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_gif__decoder__frame_dirty_rect( const wuffs_gif__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( wuffs_base__u32__min(self->private_impl.f_frame_rect_x0, self->private_impl.f_width), wuffs_base__u32__min(self->private_impl.f_frame_rect_y0, self->private_impl.f_height), wuffs_base__u32__min(self->private_impl.f_frame_rect_x1, self->private_impl.f_width), wuffs_base__u32__min(self->private_impl.f_dirty_max_excl_y, self->private_impl.f_height)); } // -------- func gif.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_gif__decoder__workbuf_len( const wuffs_gif__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } // -------- func gif.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__restart_frame( wuffs_gif__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } else if (a_io_position == 0u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_delayed_num_decoded_frames = false; self->private_impl.f_frame_config_io_position = a_io_position; self->private_impl.f_num_decoded_frame_configs_value = a_index; self->private_impl.f_num_decoded_frames_value = a_index; wuffs_gif__decoder__reset_gc(self); self->private_impl.f_call_sequence = 40u; return wuffs_base__make_status(NULL); } // -------- func gif.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_frame_config( wuffs_gif__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_gif__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_gif__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func gif.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_frame_config( wuffs_gif__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_background_color = 0; uint8_t v_flags = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; if (coro_susp_point) { v_background_color = self->private_data.s_do_decode_frame_config.v_background_color; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_dirty_max_excl_y = 0u; if (((uint8_t)(self->private_impl.f_call_sequence & 16u)) != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_gif__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_gif__decoder__skip_frame(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_call_sequence >= 96u) { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if ((self->private_impl.f_num_decoded_frame_configs_value > 0u) || (self->private_impl.f_call_sequence == 40u)) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_gif__decoder__decode_up_to_id_part1(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_call_sequence >= 96u) { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } } v_background_color = self->private_impl.f_black_color_u32_argb_premul; if ( ! self->private_impl.f_gc_has_transparent_index) { v_background_color = self->private_impl.f_background_color_u32_argb_premul; if (self->private_impl.f_quirks[1u] && (self->private_impl.f_num_decoded_frame_configs_value == 0u)) { while (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); } v_flags = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (((uint8_t)(v_flags & 128u)) != 0u) { v_background_color = self->private_impl.f_black_color_u32_argb_premul; } } } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( wuffs_base__u32__min(self->private_impl.f_frame_rect_x0, self->private_impl.f_width), wuffs_base__u32__min(self->private_impl.f_frame_rect_y0, self->private_impl.f_height), wuffs_base__u32__min(self->private_impl.f_frame_rect_x1, self->private_impl.f_width), wuffs_base__u32__min(self->private_impl.f_frame_rect_y1, self->private_impl.f_height)), ((wuffs_base__flicks)(self->private_impl.f_gc_duration)), self->private_impl.f_num_decoded_frame_configs_value, self->private_impl.f_frame_config_io_position, self->private_impl.f_gc_disposal, ! self->private_impl.f_gc_has_transparent_index, false, v_background_color); } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_num_decoded_frame_configs_value, 1u); self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_frame_config.v_background_color = v_background_color; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.skip_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__skip_frame( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_flags = 0; uint8_t v_lw = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_skip_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_flags = t_0; } if (((uint8_t)(v_flags & 128u)) != 0u) { self->private_data.s_skip_frame.scratch = (((uint32_t)(3u)) << ((uint8_t)(1u + ((uint8_t)(v_flags & 7u))))); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (self->private_data.s_skip_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_skip_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_skip_frame.scratch; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_lw = t_1; } if (v_lw > 8u) { status = wuffs_base__make_status(wuffs_gif__error__bad_literal_width); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_gif__decoder__skip_blocks(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_quirks[0u]) { self->private_impl.f_delayed_num_decoded_frames = true; } else { wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); } wuffs_gif__decoder__reset_gc(self); self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_skip_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_skip_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gif__decoder__decode_frame( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_gif__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_gif__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 4 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func gif.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__do_decode_frame( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_gif__decoder__do_decode_frame_config(self, NULL, a_src); if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (self->private_impl.f_quirks[5u] && ((self->private_impl.f_frame_rect_x0 == self->private_impl.f_frame_rect_x1) || (self->private_impl.f_frame_rect_y0 == self->private_impl.f_frame_rect_y1))) { status = wuffs_base__make_status(wuffs_gif__error__bad_frame_size); goto exit; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_gif__decoder__decode_id_part1(self, a_dst, a_src, a_blend); if (status.repr) { goto suspend; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_gif__decoder__decode_id_part2(self, a_dst, a_src, a_workbuf); if (status.repr) { goto suspend; } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); wuffs_gif__decoder__reset_gc(self); self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func gif.decoder.reset_gc WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__reset_gc( wuffs_gif__decoder* self) { self->private_impl.f_gc_has_transparent_index = false; self->private_impl.f_gc_transparent_index = 0u; self->private_impl.f_gc_disposal = 0u; self->private_impl.f_gc_duration = 0u; return wuffs_base__make_empty_struct(); } // -------- func gif.decoder.decode_up_to_id_part1 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_up_to_id_part1( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_block_type = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_up_to_id_part1; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_frame_config_io_position == 0u) || (self->private_impl.f_num_decoded_frame_configs_value > 0u)) { self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_block_type = t_0; } if (v_block_type == 33u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_gif__decoder__decode_extension(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (v_block_type == 44u) { if (self->private_impl.f_delayed_num_decoded_frames) { self->private_impl.f_delayed_num_decoded_frames = false; wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_gif__decoder__decode_id_part0(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } break; } else { if (self->private_impl.f_delayed_num_decoded_frames) { self->private_impl.f_delayed_num_decoded_frames = false; wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); } self->private_impl.f_call_sequence = 96u; break; } } goto ok; ok: self->private_impl.p_decode_up_to_id_part1 = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_up_to_id_part1 = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_header WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_header( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_c48 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_header; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 6)) { t_0 = ((uint64_t)(wuffs_base__peek_u48le__no_bounds_check(iop_a_src))); iop_a_src += 6; } else { self->private_data.s_decode_header.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_header.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 40) { t_0 = ((uint64_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c48 = t_0; } if ((v_c48 != 106889795225927u) && (v_c48 != 106898385160519u)) { status = wuffs_base__make_status(wuffs_gif__error__bad_header); goto exit; } goto ok; ok: self->private_impl.p_decode_header = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_header = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_lsd WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_lsd( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_flags = 0; uint8_t v_background_color_index = 0; uint32_t v_num_palette_entries = 0; uint32_t v_i = 0; uint32_t v_j = 0; uint32_t v_argb = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_lsd; if (coro_susp_point) { v_flags = self->private_data.s_decode_lsd.v_flags; v_background_color_index = self->private_data.s_decode_lsd.v_background_color_index; v_num_palette_entries = self->private_data.s_decode_lsd.v_num_palette_entries; v_i = self->private_data.s_decode_lsd.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_lsd.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_lsd.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 8) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } self->private_impl.f_width = t_0; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_1 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_lsd.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_lsd.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 8) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } self->private_impl.f_height = t_1; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_flags = t_2; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_background_color_index = t_3; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src++; v_i = 0u; self->private_impl.f_has_global_palette = (((uint8_t)(v_flags & 128u)) != 0u); if (self->private_impl.f_has_global_palette) { v_num_palette_entries = (((uint32_t)(1u)) << ((uint8_t)(1u + ((uint8_t)(v_flags & 7u))))); while (v_i < v_num_palette_entries) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 3)) { t_4 = ((uint32_t)(wuffs_base__peek_u24be__no_bounds_check(iop_a_src))); iop_a_src += 3; } else { self->private_data.s_decode_lsd.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_lsd.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_4); if (num_bits_4 == 16) { t_4 = ((uint32_t)(*scratch >> 40)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)); } } v_argb = t_4; } v_argb |= 4278190080u; self->private_data.f_palettes[0u][((4u * v_i) + 0u)] = ((uint8_t)((v_argb >> 0u))); self->private_data.f_palettes[0u][((4u * v_i) + 1u)] = ((uint8_t)((v_argb >> 8u))); self->private_data.f_palettes[0u][((4u * v_i) + 2u)] = ((uint8_t)((v_argb >> 16u))); self->private_data.f_palettes[0u][((4u * v_i) + 3u)] = ((uint8_t)((v_argb >> 24u))); v_i += 1u; } if (self->private_impl.f_quirks[2u]) { if ((v_background_color_index != 0u) && (((uint32_t)(v_background_color_index)) < v_num_palette_entries)) { v_j = (4u * ((uint32_t)(v_background_color_index))); self->private_impl.f_background_color_u32_argb_premul = ((((uint32_t)(self->private_data.f_palettes[0u][(v_j + 0u)])) << 0u) | (((uint32_t)(self->private_data.f_palettes[0u][(v_j + 1u)])) << 8u) | (((uint32_t)(self->private_data.f_palettes[0u][(v_j + 2u)])) << 16u) | (((uint32_t)(self->private_data.f_palettes[0u][(v_j + 3u)])) << 24u)); } else { self->private_impl.f_background_color_u32_argb_premul = 77u; } } } while (v_i < 256u) { self->private_data.f_palettes[0u][((4u * v_i) + 0u)] = 0u; self->private_data.f_palettes[0u][((4u * v_i) + 1u)] = 0u; self->private_data.f_palettes[0u][((4u * v_i) + 2u)] = 0u; self->private_data.f_palettes[0u][((4u * v_i) + 3u)] = 255u; v_i += 1u; } goto ok; ok: self->private_impl.p_decode_lsd = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_lsd = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_lsd.v_flags = v_flags; self->private_data.s_decode_lsd.v_background_color_index = v_background_color_index; self->private_data.s_decode_lsd.v_num_palette_entries = v_num_palette_entries; self->private_data.s_decode_lsd.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_extension WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_extension( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_label = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_extension; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_label = t_0; } if (v_label == 249u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_gif__decoder__decode_gc(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } status = wuffs_base__make_status(NULL); goto ok; } else if (v_label == 255u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_gif__decoder__decode_ae(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } status = wuffs_base__make_status(NULL); goto ok; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_gif__decoder__skip_blocks(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } ok: self->private_impl.p_decode_extension = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_extension = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.skip_blocks WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__skip_blocks( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_block_size = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_skip_blocks; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_block_size = t_0; } if (v_block_size == 0u) { status = wuffs_base__make_status(NULL); goto ok; } self->private_data.s_skip_blocks.scratch = ((uint32_t)(v_block_size)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (self->private_data.s_skip_blocks.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_skip_blocks.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_skip_blocks.scratch; } ok: self->private_impl.p_skip_blocks = 0; goto exit; } goto suspend; suspend: self->private_impl.p_skip_blocks = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_ae WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_ae( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_block_size = 0; bool v_is_animexts = false; bool v_is_netscape = false; bool v_is_iccp = false; bool v_is_xmp = false; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_ae; if (coro_susp_point) { v_block_size = self->private_data.s_decode_ae.v_block_size; v_is_animexts = self->private_data.s_decode_ae.v_is_animexts; v_is_netscape = self->private_data.s_decode_ae.v_is_netscape; v_is_iccp = self->private_data.s_decode_ae.v_is_iccp; v_is_xmp = self->private_data.s_decode_ae.v_is_xmp; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; do { if (self->private_impl.f_metadata_fourcc != 0u) { status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_block_size = t_0; } if (v_block_size == 0u) { status = wuffs_base__make_status(NULL); goto ok; } if (v_block_size != 11u) { self->private_data.s_decode_ae.scratch = ((uint32_t)(v_block_size)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (self->private_data.s_decode_ae.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_ae.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_ae.scratch; break; } v_is_animexts = true; v_is_netscape = true; v_is_iccp = true; v_is_xmp = true; v_block_size = 0u; while (v_block_size < 11u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } v_is_animexts = (v_is_animexts && (v_c8 == WUFFS_GIF__ANIMEXTS1DOT0[v_block_size])); v_is_netscape = (v_is_netscape && (v_c8 == WUFFS_GIF__NETSCAPE2DOT0[v_block_size])); v_is_iccp = (v_is_iccp && (v_c8 == WUFFS_GIF__ICCRGBG1012[v_block_size])); v_is_xmp = (v_is_xmp && (v_c8 == WUFFS_GIF__XMPDATAXMP[v_block_size])); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_block_size += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } if (v_is_animexts || v_is_netscape) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_block_size = t_2; } if (v_block_size != 3u) { self->private_data.s_decode_ae.scratch = ((uint32_t)(v_block_size)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (self->private_data.s_decode_ae.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_ae.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_ae.scratch; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (v_c8 != 1u) { self->private_data.s_decode_ae.scratch = 2u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (self->private_data.s_decode_ae.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_ae.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_ae.scratch; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_ae.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_ae.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 8) { t_4 = ((uint32_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } self->private_impl.f_num_animation_loops_value = t_4; } self->private_impl.f_seen_num_animation_loops_value = true; if ((0u < self->private_impl.f_num_animation_loops_value) && (self->private_impl.f_num_animation_loops_value <= 65535u)) { self->private_impl.f_num_animation_loops_value += 1u; } } else if (self->private_impl.f_call_sequence >= 32u) { } else if (v_is_iccp && self->private_impl.f_report_metadata_iccp) { self->private_impl.f_metadata_fourcc = 1229144912u; self->private_impl.f_metadata_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); self->private_impl.f_call_sequence = 16u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } else if (v_is_xmp && self->private_impl.f_report_metadata_xmp) { self->private_impl.f_metadata_fourcc = 1481461792u; self->private_impl.f_metadata_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); self->private_impl.f_call_sequence = 16u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } } while (0); if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); status = wuffs_gif__decoder__skip_blocks(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } ok: self->private_impl.p_decode_ae = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_ae = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_ae.v_block_size = v_block_size; self->private_data.s_decode_ae.v_is_animexts = v_is_animexts; self->private_data.s_decode_ae.v_is_netscape = v_is_netscape; self->private_data.s_decode_ae.v_is_iccp = v_is_iccp; self->private_data.s_decode_ae.v_is_xmp = v_is_xmp; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_gc WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_gc( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_flags = 0; uint16_t v_gc_duration_centiseconds = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_gc; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 4u) { status = wuffs_base__make_status(wuffs_gif__error__bad_graphic_control); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_flags = t_1; } self->private_impl.f_gc_has_transparent_index = (((uint8_t)(v_flags & 1u)) != 0u); v_flags = ((uint8_t)(((uint8_t)(v_flags >> 2u)) & 7u)); if (v_flags == 2u) { self->private_impl.f_gc_disposal = 1u; } else if ((v_flags == 3u) || (v_flags == 4u)) { self->private_impl.f_gc_disposal = 2u; } else { self->private_impl.f_gc_disposal = 0u; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint16_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_2 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_decode_gc.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_gc.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 8) { t_2 = ((uint16_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } v_gc_duration_centiseconds = t_2; } self->private_impl.f_gc_duration = (((uint64_t)(v_gc_duration_centiseconds)) * 7056000u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; self->private_impl.f_gc_transparent_index = t_3; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_gif__error__bad_graphic_control); goto exit; } goto ok; ok: self->private_impl.p_decode_gc = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_gc = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_id_part0 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part0( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_id_part0; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_id_part0.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_id_part0.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 8) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } self->private_impl.f_frame_rect_x0 = t_0; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_1 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_id_part0.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_id_part0.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 8) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } self->private_impl.f_frame_rect_y0 = t_1; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_2 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_id_part0.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_id_part0.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 8) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } self->private_impl.f_frame_rect_x1 = t_2; } self->private_impl.f_frame_rect_x1 += self->private_impl.f_frame_rect_x0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_3 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_id_part0.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_id_part0.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 8) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } self->private_impl.f_frame_rect_y1 = t_3; } self->private_impl.f_frame_rect_y1 += self->private_impl.f_frame_rect_y0; self->private_impl.f_dst_x = self->private_impl.f_frame_rect_x0; self->private_impl.f_dst_y = self->private_impl.f_frame_rect_y0; if ((self->private_impl.f_num_decoded_frame_configs_value == 0u) && ! self->private_impl.f_quirks[4u]) { self->private_impl.f_width = wuffs_base__u32__max(self->private_impl.f_width, self->private_impl.f_frame_rect_x1); self->private_impl.f_height = wuffs_base__u32__max(self->private_impl.f_height, self->private_impl.f_frame_rect_y1); } goto ok; ok: self->private_impl.p_decode_id_part0 = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_id_part0 = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_id_part1 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part1( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_flags = 0; uint8_t v_which_palette = 0; uint32_t v_num_palette_entries = 0; uint32_t v_i = 0; uint32_t v_argb = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t v_lw = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_id_part1; if (coro_susp_point) { v_which_palette = self->private_data.s_decode_id_part1.v_which_palette; v_num_palette_entries = self->private_data.s_decode_id_part1.v_num_palette_entries; v_i = self->private_data.s_decode_id_part1.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_flags = t_0; } if (((uint8_t)(v_flags & 64u)) != 0u) { self->private_impl.f_interlace = 4u; } else { self->private_impl.f_interlace = 0u; } v_which_palette = 1u; if (((uint8_t)(v_flags & 128u)) != 0u) { v_num_palette_entries = (((uint32_t)(1u)) << ((uint8_t)(1u + ((uint8_t)(v_flags & 7u))))); v_i = 0u; while (v_i < v_num_palette_entries) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 3)) { t_1 = ((uint32_t)(wuffs_base__peek_u24be__no_bounds_check(iop_a_src))); iop_a_src += 3; } else { self->private_data.s_decode_id_part1.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_id_part1.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 16) { t_1 = ((uint32_t)(*scratch >> 40)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_argb = t_1; } v_argb |= 4278190080u; self->private_data.f_palettes[1u][((4u * v_i) + 0u)] = ((uint8_t)((v_argb >> 0u))); self->private_data.f_palettes[1u][((4u * v_i) + 1u)] = ((uint8_t)((v_argb >> 8u))); self->private_data.f_palettes[1u][((4u * v_i) + 2u)] = ((uint8_t)((v_argb >> 16u))); self->private_data.f_palettes[1u][((4u * v_i) + 3u)] = ((uint8_t)((v_argb >> 24u))); v_i += 1u; } while (v_i < 256u) { self->private_data.f_palettes[1u][((4u * v_i) + 0u)] = 0u; self->private_data.f_palettes[1u][((4u * v_i) + 1u)] = 0u; self->private_data.f_palettes[1u][((4u * v_i) + 2u)] = 0u; self->private_data.f_palettes[1u][((4u * v_i) + 3u)] = 255u; v_i += 1u; } } else if (self->private_impl.f_quirks[6u] && ! self->private_impl.f_has_global_palette) { status = wuffs_base__make_status(wuffs_gif__error__bad_palette); goto exit; } else if (self->private_impl.f_gc_has_transparent_index) { wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8(self->private_data.f_palettes[1u], 1024), wuffs_base__make_slice_u8(self->private_data.f_palettes[0u], 1024)); } else { v_which_palette = 0u; } if (self->private_impl.f_gc_has_transparent_index) { self->private_data.f_palettes[1u][((4u * ((uint32_t)(self->private_impl.f_gc_transparent_index))) + 0u)] = 0u; self->private_data.f_palettes[1u][((4u * ((uint32_t)(self->private_impl.f_gc_transparent_index))) + 1u)] = 0u; self->private_data.f_palettes[1u][((4u * ((uint32_t)(self->private_impl.f_gc_transparent_index))) + 2u)] = 0u; self->private_data.f_palettes[1u][((4u * ((uint32_t)(self->private_impl.f_gc_transparent_index))) + 3u)] = 0u; } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), wuffs_base__utility__make_pixel_format(2198077448u), wuffs_base__make_slice_u8(self->private_data.f_palettes[v_which_palette], 1024), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } if (self->private_impl.f_ignored_but_affects_benchmarks) { } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_lw = t_2; } if (v_lw > 8u) { status = wuffs_base__make_status(wuffs_gif__error__bad_literal_width); goto exit; } self->private_impl.f_lzw_pending_literal_width_plus_one = ((uint32_t)(((uint8_t)(1u + v_lw)))); self->private_impl.f_ignored_but_affects_benchmarks = true; ok: self->private_impl.p_decode_id_part1 = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_id_part1 = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_id_part1.v_which_palette = v_which_palette; self->private_data.s_decode_id_part1.v_num_palette_entries = v_num_palette_entries; self->private_data.s_decode_id_part1.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.decode_id_part2 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__decode_id_part2( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_block_size = 0; bool v_need_block_size = false; uint32_t v_n_copied = 0; uint64_t v_n_compressed = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint64_t v_mark = 0; wuffs_base__status v_copy_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_id_part2; if (coro_susp_point) { v_block_size = self->private_data.s_decode_id_part2.v_block_size; v_need_block_size = self->private_data.s_decode_id_part2.v_need_block_size; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; wuffs_gif__decoder__lzw_init(self); v_need_block_size = true; label__outer__continue:; while (true) { if (v_need_block_size) { v_need_block_size = false; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t t_0 = *iop_a_src++; v_block_size = t_0; } } if (v_block_size == 0u) { break; } while (((uint64_t)(io2_a_src - iop_a_src)) == 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } if (self->private_impl.f_compressed_ri == self->private_impl.f_compressed_wi) { self->private_impl.f_compressed_ri = 0u; self->private_impl.f_compressed_wi = 0u; } while (self->private_impl.f_compressed_wi <= 3841u) { v_n_compressed = wuffs_base__u64__min(v_block_size, ((uint64_t)(io2_a_src - iop_a_src))); if (v_n_compressed <= 0u) { break; } v_n_copied = wuffs_private_impl__io_reader__limited_copy_u32_to_slice( &iop_a_src, io2_a_src,((uint32_t)(v_n_compressed)), wuffs_base__make_slice_u8_ij(self->private_data.f_compressed, self->private_impl.f_compressed_wi, 4096)); wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_compressed_wi, ((uint64_t)(v_n_copied))); wuffs_private_impl__u64__sat_sub_indirect(&v_block_size, ((uint64_t)(v_n_copied))); if (v_block_size > 0u) { break; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { v_need_block_size = true; break; } v_block_size = ((uint64_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))); iop_a_src += 1u; } while (true) { if ((self->private_impl.f_compressed_ri > self->private_impl.f_compressed_wi) || (self->private_impl.f_compressed_wi > 4096u)) { status = wuffs_base__make_status(wuffs_gif__error__internal_error_inconsistent_i_o); goto exit; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_compressed, self->private_impl.f_compressed_ri, self->private_impl.f_compressed_wi), 0u); v_mark = ((uint64_t)(iop_v_r - io0_v_r)); u_r.meta.ri = ((size_t)(iop_v_r - u_r.data.ptr)); wuffs_gif__decoder__lzw_read_from(self, v_r); iop_v_r = u_r.data.ptr + u_r.meta.ri; wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_compressed_ri, wuffs_private_impl__io__count_since(v_mark, ((uint64_t)(iop_v_r - io0_v_r)))); v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } if (self->private_impl.f_lzw_output_ri < self->private_impl.f_lzw_output_wi) { v_copy_status = wuffs_gif__decoder__copy_to_image_buffer(self, a_dst, wuffs_base__make_slice_u8_ij(self->private_data.f_lzw_output, self->private_impl.f_lzw_output_ri, self->private_impl.f_lzw_output_wi)); if (wuffs_base__status__is_error(&v_copy_status)) { status = v_copy_status; goto exit; } self->private_impl.f_lzw_output_ri = 0u; self->private_impl.f_lzw_output_wi = 0u; } if (self->private_impl.f_lzw_read_from_return_value == 0u) { self->private_impl.f_ignored_but_affects_benchmarks = false; if (v_need_block_size || (v_block_size > 0u)) { self->private_data.s_decode_id_part2.scratch = ((uint32_t)(v_block_size)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (self->private_data.s_decode_id_part2.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_id_part2.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_id_part2.scratch; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_gif__decoder__skip_blocks(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } goto label__outer__break; } else if (self->private_impl.f_lzw_read_from_return_value == 1u) { continue; } else if (self->private_impl.f_lzw_read_from_return_value == 2u) { goto label__outer__continue; } else if (self->private_impl.f_quirks[3u] && (self->private_impl.f_dst_y >= self->private_impl.f_frame_rect_y1) && (self->private_impl.f_interlace == 0u)) { if (v_need_block_size || (v_block_size > 0u)) { self->private_data.s_decode_id_part2.scratch = ((uint32_t)(v_block_size)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (self->private_data.s_decode_id_part2.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_id_part2.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_id_part2.scratch; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); status = wuffs_gif__decoder__skip_blocks(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } goto label__outer__break; } else if (self->private_impl.f_lzw_read_from_return_value == 3u) { status = wuffs_base__make_status(wuffs_gif__error__truncated_input); goto exit; } else if (self->private_impl.f_lzw_read_from_return_value == 4u) { status = wuffs_base__make_status(wuffs_gif__error__bad_lzw_code); goto exit; } status = wuffs_base__make_status(wuffs_gif__error__internal_error_inconsistent_i_o); goto exit; } } label__outer__break:; self->private_impl.f_compressed_ri = 0u; self->private_impl.f_compressed_wi = 0u; if ((self->private_impl.f_dst_y < self->private_impl.f_frame_rect_y1) && (self->private_impl.f_frame_rect_x0 != self->private_impl.f_frame_rect_x1) && (self->private_impl.f_frame_rect_y0 != self->private_impl.f_frame_rect_y1)) { status = wuffs_base__make_status(wuffs_base__error__not_enough_data); goto exit; } ok: self->private_impl.p_decode_id_part2 = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_id_part2 = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_id_part2.v_block_size = v_block_size; self->private_data.s_decode_id_part2.v_need_block_size = v_need_block_size; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func gif.decoder.copy_to_image_buffer WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gif__decoder__copy_to_image_buffer( wuffs_gif__decoder* self, wuffs_base__pixel_buffer* a_pb, wuffs_base__slice_u8 a_src) { wuffs_base__slice_u8 v_dst = {0}; wuffs_base__slice_u8 v_src = {0}; uint64_t v_width_in_bytes = 0; uint64_t v_n = 0; uint64_t v_src_ri = 0; wuffs_base__pixel_format v_pixfmt = {0}; uint32_t v_bytes_per_pixel = 0; uint32_t v_bits_per_pixel = 0; wuffs_base__table_u8 v_tab = {0}; uint64_t v_i = 0; uint64_t v_j = 0; uint32_t v_replicate_y0 = 0; uint32_t v_replicate_y1 = 0; wuffs_base__slice_u8 v_replicate_dst = {0}; wuffs_base__slice_u8 v_replicate_src = {0}; v_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_pb); v_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_pixfmt); if ((v_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_bytes_per_pixel = (v_bits_per_pixel >> 3u); v_width_in_bytes = ((uint64_t)((self->private_impl.f_width * v_bytes_per_pixel))); v_tab = wuffs_base__pixel_buffer__plane(a_pb, 0u); while (v_src_ri < ((uint64_t)(a_src.len))) { v_src = wuffs_base__slice_u8__subslice_i(a_src, v_src_ri); if (self->private_impl.f_dst_y >= self->private_impl.f_frame_rect_y1) { if (self->private_impl.f_quirks[3u]) { return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__too_much_data); } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (self->private_impl.f_dst_y >= self->private_impl.f_height) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, 0u); } else if (v_width_in_bytes < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_width_in_bytes); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_bytes_per_pixel))); if (v_i < ((uint64_t)(v_dst.len))) { v_j = (((uint64_t)(self->private_impl.f_frame_rect_x1)) * ((uint64_t)(v_bytes_per_pixel))); if ((v_i <= v_j) && (v_j <= ((uint64_t)(v_dst.len)))) { v_dst = wuffs_base__slice_u8__subslice_ij(v_dst, v_i, v_j); } else { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_i); } v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024), v_src); wuffs_private_impl__u64__sat_add_indirect(&v_src_ri, v_n); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); self->private_impl.f_dirty_max_excl_y = wuffs_base__u32__max(self->private_impl.f_dirty_max_excl_y, wuffs_base__u32__sat_add(self->private_impl.f_dst_y, 1u)); } if (self->private_impl.f_frame_rect_x1 <= self->private_impl.f_dst_x) { self->private_impl.f_dst_x = self->private_impl.f_frame_rect_x0; if (self->private_impl.f_interlace == 0u) { wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_y, 1u); continue; } if ((self->private_impl.f_num_decoded_frames_value == 0u) && ! self->private_impl.f_gc_has_transparent_index && (self->private_impl.f_interlace > 1u)) { v_replicate_src = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); v_replicate_y0 = wuffs_base__u32__sat_add(self->private_impl.f_dst_y, 1u); v_replicate_y1 = wuffs_base__u32__sat_add(self->private_impl.f_dst_y, ((uint32_t)(WUFFS_GIF__INTERLACE_COUNT[self->private_impl.f_interlace]))); v_replicate_y1 = wuffs_base__u32__min(v_replicate_y1, self->private_impl.f_frame_rect_y1); while (v_replicate_y0 < v_replicate_y1) { v_replicate_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_replicate_y0); wuffs_private_impl__slice_u8__copy_from_slice(v_replicate_dst, v_replicate_src); v_replicate_y0 += 1u; } self->private_impl.f_dirty_max_excl_y = wuffs_base__u32__max(self->private_impl.f_dirty_max_excl_y, v_replicate_y1); } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_y, ((uint32_t)(WUFFS_GIF__INTERLACE_DELTA[self->private_impl.f_interlace]))); while ((self->private_impl.f_interlace > 0u) && (self->private_impl.f_dst_y >= self->private_impl.f_frame_rect_y1)) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_interlace -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_impl.f_dst_y = wuffs_base__u32__sat_add(self->private_impl.f_frame_rect_y0, WUFFS_GIF__INTERLACE_START[self->private_impl.f_interlace]); } continue; } if (((uint64_t)(a_src.len)) == v_src_ri) { break; } else if (((uint64_t)(a_src.len)) < v_src_ri) { return wuffs_base__make_status(wuffs_gif__error__internal_error_inconsistent_i_o); } v_n = ((uint64_t)((self->private_impl.f_frame_rect_x1 - self->private_impl.f_dst_x))); v_n = wuffs_base__u64__min(v_n, (((uint64_t)(a_src.len)) - v_src_ri)); wuffs_private_impl__u64__sat_add_indirect(&v_src_ri, v_n); wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); if (self->private_impl.f_frame_rect_x1 <= self->private_impl.f_dst_x) { self->private_impl.f_dst_x = self->private_impl.f_frame_rect_x0; wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_y, ((uint32_t)(WUFFS_GIF__INTERLACE_DELTA[self->private_impl.f_interlace]))); while ((self->private_impl.f_interlace > 0u) && (self->private_impl.f_dst_y >= self->private_impl.f_frame_rect_y1)) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_interlace -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_impl.f_dst_y = wuffs_base__u32__sat_add(self->private_impl.f_frame_rect_y0, WUFFS_GIF__INTERLACE_START[self->private_impl.f_interlace]); } continue; } if (v_src_ri != ((uint64_t)(a_src.len))) { return wuffs_base__make_status(wuffs_gif__error__internal_error_inconsistent_i_o); } break; } return wuffs_base__make_status(NULL); } // -------- func gif.decoder.lzw_init WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__lzw_init( wuffs_gif__decoder* self) { uint32_t v_i = 0; self->private_impl.f_lzw_literal_width = 8u; if (self->private_impl.f_lzw_pending_literal_width_plus_one > 0u) { self->private_impl.f_lzw_literal_width = (self->private_impl.f_lzw_pending_literal_width_plus_one - 1u); } self->private_impl.f_lzw_clear_code = (((uint32_t)(1u)) << self->private_impl.f_lzw_literal_width); self->private_impl.f_lzw_end_code = (self->private_impl.f_lzw_clear_code + 1u); self->private_impl.f_lzw_save_code = self->private_impl.f_lzw_end_code; self->private_impl.f_lzw_prev_code = self->private_impl.f_lzw_end_code; self->private_impl.f_lzw_width = (self->private_impl.f_lzw_literal_width + 1u); self->private_impl.f_lzw_bits = 0u; self->private_impl.f_lzw_n_bits = 0u; self->private_impl.f_lzw_output_ri = 0u; self->private_impl.f_lzw_output_wi = 0u; v_i = 0u; while (v_i < self->private_impl.f_lzw_clear_code) { self->private_data.f_lzw_lm1s[v_i] = 0u; self->private_data.f_lzw_suffixes[v_i][0u] = ((uint8_t)(v_i)); v_i += 1u; } return wuffs_base__make_empty_struct(); } // -------- func gif.decoder.lzw_read_from WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_gif__decoder__lzw_read_from( wuffs_gif__decoder* self, wuffs_base__io_buffer* a_src) { uint32_t v_clear_code = 0; uint32_t v_end_code = 0; uint32_t v_save_code = 0; uint32_t v_prev_code = 0; uint32_t v_width = 0; uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_output_wi = 0; uint32_t v_code = 0; uint32_t v_c = 0; uint32_t v_o = 0; uint32_t v_steps = 0; uint8_t v_first_byte = 0; uint16_t v_lm1_b = 0; uint16_t v_lm1_a = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_clear_code = self->private_impl.f_lzw_clear_code; v_end_code = self->private_impl.f_lzw_end_code; v_save_code = self->private_impl.f_lzw_save_code; v_prev_code = self->private_impl.f_lzw_prev_code; v_width = self->private_impl.f_lzw_width; v_bits = self->private_impl.f_lzw_bits; v_n_bits = self->private_impl.f_lzw_n_bits; v_output_wi = self->private_impl.f_lzw_output_wi; while (true) { if (v_n_bits < v_width) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 4u) { v_bits |= ((uint32_t)(wuffs_base__peek_u32le__no_bounds_check(iop_a_src) << v_n_bits)); iop_a_src += ((31u - v_n_bits) >> 3u); v_n_bits |= 24u; } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { self->private_impl.f_lzw_read_from_return_value = 3u; } else { self->private_impl.f_lzw_read_from_return_value = 2u; } break; } else { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; if (v_n_bits >= v_width) { } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { self->private_impl.f_lzw_read_from_return_value = 3u; } else { self->private_impl.f_lzw_read_from_return_value = 2u; } break; } else { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; if (v_n_bits < v_width) { self->private_impl.f_lzw_read_from_return_value = 5u; break; } } } } v_code = ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_width)); v_bits >>= v_width; v_n_bits -= v_width; if (v_code < v_clear_code) { self->private_data.f_lzw_output[v_output_wi] = ((uint8_t)(v_code)); v_output_wi = ((v_output_wi + 1u) & 8191u); if (v_save_code <= 4095u) { v_lm1_a = ((uint16_t)(((uint16_t)(self->private_data.f_lzw_lm1s[v_prev_code] + 1u)) & 4095u)); self->private_data.f_lzw_lm1s[v_save_code] = v_lm1_a; if (((uint16_t)(v_lm1_a % 8u)) != 0u) { self->private_impl.f_lzw_prefixes[v_save_code] = self->private_impl.f_lzw_prefixes[v_prev_code]; memcpy(self->private_data.f_lzw_suffixes[v_save_code],self->private_data.f_lzw_suffixes[v_prev_code], sizeof(self->private_data.f_lzw_suffixes[v_save_code])); self->private_data.f_lzw_suffixes[v_save_code][((uint16_t)(v_lm1_a % 8u))] = ((uint8_t)(v_code)); } else { self->private_impl.f_lzw_prefixes[v_save_code] = ((uint16_t)(v_prev_code)); self->private_data.f_lzw_suffixes[v_save_code][0u] = ((uint8_t)(v_code)); } v_save_code += 1u; if (v_width < 12u) { v_width += (1u & (v_save_code >> v_width)); } v_prev_code = v_code; } } else if (v_code <= v_end_code) { if (v_code == v_end_code) { self->private_impl.f_lzw_read_from_return_value = 0u; break; } v_save_code = v_end_code; v_prev_code = v_end_code; v_width = (self->private_impl.f_lzw_literal_width + 1u); } else if (v_code <= v_save_code) { v_c = v_code; if (v_code == v_save_code) { v_c = v_prev_code; } v_o = ((v_output_wi + (((uint32_t)(self->private_data.f_lzw_lm1s[v_c])) & 4294967288u)) & 8191u); v_output_wi = ((v_output_wi + 1u + ((uint32_t)(self->private_data.f_lzw_lm1s[v_c]))) & 8191u); v_steps = (((uint32_t)(self->private_data.f_lzw_lm1s[v_c])) >> 3u); while (true) { memcpy((self->private_data.f_lzw_output)+(v_o), (self->private_data.f_lzw_suffixes[v_c]), 8u); if (v_steps <= 0u) { break; } v_steps -= 1u; v_o = (((uint32_t)(v_o - 8u)) & 8191u); v_c = ((uint32_t)(self->private_impl.f_lzw_prefixes[v_c])); } v_first_byte = self->private_data.f_lzw_suffixes[v_c][0u]; if (v_code == v_save_code) { self->private_data.f_lzw_output[v_output_wi] = v_first_byte; v_output_wi = ((v_output_wi + 1u) & 8191u); } if (v_save_code <= 4095u) { v_lm1_b = ((uint16_t)(((uint16_t)(self->private_data.f_lzw_lm1s[v_prev_code] + 1u)) & 4095u)); self->private_data.f_lzw_lm1s[v_save_code] = v_lm1_b; if (((uint16_t)(v_lm1_b % 8u)) != 0u) { self->private_impl.f_lzw_prefixes[v_save_code] = self->private_impl.f_lzw_prefixes[v_prev_code]; memcpy(self->private_data.f_lzw_suffixes[v_save_code],self->private_data.f_lzw_suffixes[v_prev_code], sizeof(self->private_data.f_lzw_suffixes[v_save_code])); self->private_data.f_lzw_suffixes[v_save_code][((uint16_t)(v_lm1_b % 8u))] = v_first_byte; } else { self->private_impl.f_lzw_prefixes[v_save_code] = ((uint16_t)(v_prev_code)); self->private_data.f_lzw_suffixes[v_save_code][0u] = ((uint8_t)(v_first_byte)); } v_save_code += 1u; if (v_width < 12u) { v_width += (1u & (v_save_code >> v_width)); } v_prev_code = v_code; } } else { self->private_impl.f_lzw_read_from_return_value = 4u; break; } if (v_output_wi > 4095u) { self->private_impl.f_lzw_read_from_return_value = 1u; break; } } if (self->private_impl.f_lzw_read_from_return_value != 2u) { while (v_n_bits >= 8u) { v_n_bits -= 8u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { self->private_impl.f_lzw_read_from_return_value = 5u; break; } } } self->private_impl.f_lzw_save_code = v_save_code; self->private_impl.f_lzw_prev_code = v_prev_code; self->private_impl.f_lzw_width = v_width; self->private_impl.f_lzw_bits = v_bits; self->private_impl.f_lzw_n_bits = v_n_bits; self->private_impl.f_lzw_output_wi = v_output_wi; if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return wuffs_base__make_empty_struct(); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GIF) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GZIP) // ---------------- Status Codes Implementations const char wuffs_gzip__error__bad_checksum[] = "#gzip: bad checksum"; const char wuffs_gzip__error__bad_compression_method[] = "#gzip: bad compression method"; const char wuffs_gzip__error__bad_encoding_flags[] = "#gzip: bad encoding flags"; const char wuffs_gzip__error__bad_header[] = "#gzip: bad header"; const char wuffs_gzip__error__truncated_input[] = "#gzip: truncated input"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gzip__decoder__do_transform_io( wuffs_gzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_gzip__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_gzip__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_gzip__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_gzip__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_gzip__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_gzip__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_gzip__decoder__initialize( wuffs_gzip__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } { wuffs_base__status z = wuffs_crc32__ieee_hasher__initialize( &self->private_data.f_checksum, sizeof(self->private_data.f_checksum), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_deflate__decoder__initialize( &self->private_data.f_flate, sizeof(self->private_data.f_flate), WUFFS_VERSION, options); if (z.repr) { return z; } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_gzip__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_gzip__decoder* wuffs_gzip__decoder__alloc(void) { wuffs_gzip__decoder* x = (wuffs_gzip__decoder*)(calloc(1, sizeof(wuffs_gzip__decoder))); if (!x) { return NULL; } if (wuffs_gzip__decoder__initialize( x, sizeof(wuffs_gzip__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_gzip__decoder(void) { return sizeof(wuffs_gzip__decoder); } // ---------------- Function Implementations // -------- func gzip.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_gzip__decoder__get_quirk( const wuffs_gzip__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if ((a_key == 1u) && self->private_impl.f_ignore_checksum) { return 1u; } return 0u; } // -------- func gzip.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gzip__decoder__set_quirk( wuffs_gzip__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func gzip.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_gzip__decoder__dst_history_retain_length( const wuffs_gzip__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func gzip.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_gzip__decoder__workbuf_len( const wuffs_gzip__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(1u, 1u); } // -------- func gzip.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_gzip__decoder__transform_io( wuffs_gzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_gzip__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_gzip__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func gzip.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_gzip__decoder__do_transform_io( wuffs_gzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_flags = 0; uint16_t v_xlen = 0; uint64_t v_mark = 0; uint32_t v_checksum_have = 0; uint32_t v_decoded_length_have = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_checksum_want = 0; uint32_t v_decoded_length_want = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; if (coro_susp_point) { v_flags = self->private_data.s_do_transform_io.v_flags; v_checksum_have = self->private_data.s_do_transform_io.v_checksum_have; v_decoded_length_have = self->private_data.s_do_transform_io.v_decoded_length_have; v_checksum_want = self->private_data.s_do_transform_io.v_checksum_want; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 31u) { status = wuffs_base__make_status(wuffs_gzip__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_c8 != 139u) { status = wuffs_base__make_status(wuffs_gzip__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_c8 != 8u) { status = wuffs_base__make_status(wuffs_gzip__error__bad_compression_method); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_flags = t_3; } self->private_data.s_do_transform_io.scratch = 6u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (self->private_data.s_do_transform_io.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_transform_io.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_transform_io.scratch; if (((uint8_t)(v_flags & 4u)) != 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint16_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 8) { t_4 = ((uint16_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } v_xlen = t_4; } self->private_data.s_do_transform_io.scratch = ((uint32_t)(v_xlen)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (self->private_data.s_do_transform_io.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_transform_io.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_transform_io.scratch; } if (((uint8_t)(v_flags & 8u)) != 0u) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } if (v_c8 == 0u) { break; } } } if (((uint8_t)(v_flags & 16u)) != 0u) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (v_c8 == 0u) { break; } } } if (((uint8_t)(v_flags & 2u)) != 0u) { self->private_data.s_do_transform_io.scratch = 2u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (self->private_data.s_do_transform_io.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_transform_io.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_transform_io.scratch; } if (((uint8_t)(v_flags & 224u)) != 0u) { status = wuffs_base__make_status(wuffs_gzip__error__bad_encoding_flags); goto exit; } while (true) { v_mark = ((uint64_t)(iop_a_dst - io0_a_dst)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_7 = wuffs_deflate__decoder__transform_io(&self->private_data.f_flate, a_dst, a_src, a_workbuf); v_status = t_7; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum) { v_checksum_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_checksum, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); v_decoded_length_have += ((uint32_t)(wuffs_private_impl__io__count_since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst))))); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(12); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); uint32_t t_8; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_8 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_8 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_8; if (num_bits_8 == 24) { t_8 = ((uint32_t)(*scratch)); break; } num_bits_8 += 8u; *scratch |= ((uint64_t)(num_bits_8)) << 56; } } v_checksum_want = t_8; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); uint32_t t_9; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_9 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_9 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_9; if (num_bits_9 == 24) { t_9 = ((uint32_t)(*scratch)); break; } num_bits_9 += 8u; *scratch |= ((uint64_t)(num_bits_9)) << 56; } } v_decoded_length_want = t_9; } if ( ! self->private_impl.f_ignore_checksum && ((v_checksum_have != v_checksum_want) || (v_decoded_length_have != v_decoded_length_want))) { status = wuffs_base__make_status(wuffs_gzip__error__bad_checksum); goto exit; } ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_transform_io.v_flags = v_flags; self->private_data.s_do_transform_io.v_checksum_have = v_checksum_have; self->private_data.s_do_transform_io.v_decoded_length_have = v_decoded_length_have; self->private_data.s_do_transform_io.v_checksum_want = v_checksum_want; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GZIP) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JPEG) // ---------------- Status Codes Implementations const char wuffs_jpeg__error__bad_dht_marker[] = "#jpeg: bad DHT marker"; const char wuffs_jpeg__error__bad_dqt_marker[] = "#jpeg: bad DQT marker"; const char wuffs_jpeg__error__bad_dri_marker[] = "#jpeg: bad DRI marker"; const char wuffs_jpeg__error__bad_sof_marker[] = "#jpeg: bad SOF marker"; const char wuffs_jpeg__error__bad_sos_marker[] = "#jpeg: bad SOS marker"; const char wuffs_jpeg__error__bad_header[] = "#jpeg: bad header"; const char wuffs_jpeg__error__bad_marker[] = "#jpeg: bad marker"; const char wuffs_jpeg__error__bad_scan_count[] = "#jpeg: bad scan count"; const char wuffs_jpeg__error__missing_huffman_table[] = "#jpeg: missing Huffman table"; const char wuffs_jpeg__error__missing_quantization_table[] = "#jpeg: missing Quantization table"; const char wuffs_jpeg__error__rejected_progressive_jpeg[] = "#jpeg: rejected progressive JPEG"; const char wuffs_jpeg__error__truncated_input[] = "#jpeg: truncated input"; const char wuffs_jpeg__error__unsupported_arithmetic_coding[] = "#jpeg: unsupported arithmetic coding"; const char wuffs_jpeg__error__unsupported_color_model[] = "#jpeg: unsupported color model"; const char wuffs_jpeg__error__unsupported_fractional_sampling[] = "#jpeg: unsupported fractional sampling"; const char wuffs_jpeg__error__unsupported_hierarchical_coding[] = "#jpeg: unsupported hierarchical coding"; const char wuffs_jpeg__error__unsupported_implicit_height[] = "#jpeg: unsupported implicit height"; const char wuffs_jpeg__error__unsupported_lossless_coding[] = "#jpeg: unsupported lossless coding"; const char wuffs_jpeg__error__unsupported_marker[] = "#jpeg: unsupported marker"; const char wuffs_jpeg__error__unsupported_precision_12_bits[] = "#jpeg: unsupported precision (12 bits)"; const char wuffs_jpeg__error__unsupported_precision_16_bits[] = "#jpeg: unsupported precision (16 bits)"; const char wuffs_jpeg__error__unsupported_precision[] = "#jpeg: unsupported precision"; const char wuffs_jpeg__error__unsupported_scan_count[] = "#jpeg: unsupported scan count"; const char wuffs_jpeg__error__internal_error_inconsistent_decoder_state[] = "#jpeg: internal error: inconsistent decoder state"; // ---------------- Private Consts static const uint8_t WUFFS_JPEG__UNZIG[80] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 1u, 8u, 16u, 9u, 2u, 3u, 10u, 17u, 24u, 32u, 25u, 18u, 11u, 4u, 5u, 12u, 19u, 26u, 33u, 40u, 48u, 41u, 34u, 27u, 20u, 13u, 6u, 7u, 14u, 21u, 28u, 35u, 42u, 49u, 56u, 57u, 50u, 43u, 36u, 29u, 22u, 15u, 23u, 30u, 37u, 44u, 51u, 58u, 59u, 52u, 45u, 38u, 31u, 39u, 46u, 53u, 60u, 61u, 54u, 47u, 55u, 62u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, 63u, }; static const uint8_t WUFFS_JPEG__BIAS_AND_CLAMP[1024] WUFFS_BASE__POTENTIALLY_UNUSED = { 128u, 129u, 130u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 138u, 139u, 140u, 141u, 142u, 143u, 144u, 145u, 146u, 147u, 148u, 149u, 150u, 151u, 152u, 153u, 154u, 155u, 156u, 157u, 158u, 159u, 160u, 161u, 162u, 163u, 164u, 165u, 166u, 167u, 168u, 169u, 170u, 171u, 172u, 173u, 174u, 175u, 176u, 177u, 178u, 179u, 180u, 181u, 182u, 183u, 184u, 185u, 186u, 187u, 188u, 189u, 190u, 191u, 192u, 193u, 194u, 195u, 196u, 197u, 198u, 199u, 200u, 201u, 202u, 203u, 204u, 205u, 206u, 207u, 208u, 209u, 210u, 211u, 212u, 213u, 214u, 215u, 216u, 217u, 218u, 219u, 220u, 221u, 222u, 223u, 224u, 225u, 226u, 227u, 228u, 229u, 230u, 231u, 232u, 233u, 234u, 235u, 236u, 237u, 238u, 239u, 240u, 241u, 242u, 243u, 244u, 245u, 246u, 247u, 248u, 249u, 250u, 251u, 252u, 253u, 254u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 255u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 1u, 2u, 3u, 4u, 5u, 6u, 7u, 8u, 9u, 10u, 11u, 12u, 13u, 14u, 15u, 16u, 17u, 18u, 19u, 20u, 21u, 22u, 23u, 24u, 25u, 26u, 27u, 28u, 29u, 30u, 31u, 32u, 33u, 34u, 35u, 36u, 37u, 38u, 39u, 40u, 41u, 42u, 43u, 44u, 45u, 46u, 47u, 48u, 49u, 50u, 51u, 52u, 53u, 54u, 55u, 56u, 57u, 58u, 59u, 60u, 61u, 62u, 63u, 64u, 65u, 66u, 67u, 68u, 69u, 70u, 71u, 72u, 73u, 74u, 75u, 76u, 77u, 78u, 79u, 80u, 81u, 82u, 83u, 84u, 85u, 86u, 87u, 88u, 89u, 90u, 91u, 92u, 93u, 94u, 95u, 96u, 97u, 98u, 99u, 100u, 101u, 102u, 103u, 104u, 105u, 106u, 107u, 108u, 109u, 110u, 111u, 112u, 113u, 114u, 115u, 116u, 117u, 118u, 119u, 120u, 121u, 122u, 123u, 124u, 125u, 126u, 127u, }; static const uint16_t WUFFS_JPEG__EXTEND[16] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 65535u, 65533u, 65529u, 65521u, 65505u, 65473u, 65409u, 65281u, 65025u, 64513u, 63489u, 61441u, 57345u, 49153u, 32769u, }; static const uint8_t WUFFS_JPEG__DEFAULT_HUFF_TABLE_DC_LUMA[29] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 1u, 5u, 1u, 1u, 1u, 1u, 1u, 1u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 1u, 2u, 3u, 4u, 5u, 6u, 7u, 8u, 9u, 10u, 11u, }; static const uint8_t WUFFS_JPEG__DEFAULT_HUFF_TABLE_DC_CHROMA[29] WUFFS_BASE__POTENTIALLY_UNUSED = { 1u, 0u, 3u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 1u, 0u, 0u, 0u, 0u, 0u, 0u, 1u, 2u, 3u, 4u, 5u, 6u, 7u, 8u, 9u, 10u, 11u, }; static const uint8_t WUFFS_JPEG__DEFAULT_HUFF_TABLE_AC_LUMA[179] WUFFS_BASE__POTENTIALLY_UNUSED = { 16u, 0u, 2u, 1u, 3u, 3u, 2u, 4u, 3u, 5u, 5u, 4u, 4u, 0u, 0u, 1u, 125u, 1u, 2u, 3u, 0u, 4u, 17u, 5u, 18u, 33u, 49u, 65u, 6u, 19u, 81u, 97u, 7u, 34u, 113u, 20u, 50u, 129u, 145u, 161u, 8u, 35u, 66u, 177u, 193u, 21u, 82u, 209u, 240u, 36u, 51u, 98u, 114u, 130u, 9u, 10u, 22u, 23u, 24u, 25u, 26u, 37u, 38u, 39u, 40u, 41u, 42u, 52u, 53u, 54u, 55u, 56u, 57u, 58u, 67u, 68u, 69u, 70u, 71u, 72u, 73u, 74u, 83u, 84u, 85u, 86u, 87u, 88u, 89u, 90u, 99u, 100u, 101u, 102u, 103u, 104u, 105u, 106u, 115u, 116u, 117u, 118u, 119u, 120u, 121u, 122u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 138u, 146u, 147u, 148u, 149u, 150u, 151u, 152u, 153u, 154u, 162u, 163u, 164u, 165u, 166u, 167u, 168u, 169u, 170u, 178u, 179u, 180u, 181u, 182u, 183u, 184u, 185u, 186u, 194u, 195u, 196u, 197u, 198u, 199u, 200u, 201u, 202u, 210u, 211u, 212u, 213u, 214u, 215u, 216u, 217u, 218u, 225u, 226u, 227u, 228u, 229u, 230u, 231u, 232u, 233u, 234u, 241u, 242u, 243u, 244u, 245u, 246u, 247u, 248u, 249u, 250u, }; static const uint8_t WUFFS_JPEG__DEFAULT_HUFF_TABLE_AC_CHROMA[179] WUFFS_BASE__POTENTIALLY_UNUSED = { 17u, 0u, 2u, 1u, 2u, 4u, 4u, 3u, 4u, 7u, 5u, 4u, 4u, 0u, 1u, 2u, 119u, 0u, 1u, 2u, 3u, 17u, 4u, 5u, 33u, 49u, 6u, 18u, 65u, 81u, 7u, 97u, 113u, 19u, 34u, 50u, 129u, 8u, 20u, 66u, 145u, 161u, 177u, 193u, 9u, 35u, 51u, 82u, 240u, 21u, 98u, 114u, 209u, 10u, 22u, 36u, 52u, 225u, 37u, 241u, 23u, 24u, 25u, 26u, 38u, 39u, 40u, 41u, 42u, 53u, 54u, 55u, 56u, 57u, 58u, 67u, 68u, 69u, 70u, 71u, 72u, 73u, 74u, 83u, 84u, 85u, 86u, 87u, 88u, 89u, 90u, 99u, 100u, 101u, 102u, 103u, 104u, 105u, 106u, 115u, 116u, 117u, 118u, 119u, 120u, 121u, 122u, 130u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 138u, 146u, 147u, 148u, 149u, 150u, 151u, 152u, 153u, 154u, 162u, 163u, 164u, 165u, 166u, 167u, 168u, 169u, 170u, 178u, 179u, 180u, 181u, 182u, 183u, 184u, 185u, 186u, 194u, 195u, 196u, 197u, 198u, 199u, 200u, 201u, 202u, 210u, 211u, 212u, 213u, 214u, 215u, 216u, 217u, 218u, 226u, 227u, 228u, 229u, 230u, 231u, 232u, 233u, 234u, 242u, 243u, 244u, 245u, 246u, 247u, 248u, 249u, 250u, }; #define WUFFS_JPEG__QUIRKS_BASE 1220532224u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct__choosy_default( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct_x86_avx2( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_image_config( wuffs_jpeg__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dqt( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dri( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_appn( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src, uint8_t a_marker); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_sof( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__quantize_dimension( const wuffs_jpeg__decoder* self, uint32_t a_width, uint8_t a_h, uint8_t a_max_incl_h); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_frame_config( wuffs_jpeg__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_frame( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dht( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__calculate_huff_tables( wuffs_jpeg__decoder* self, uint8_t a_tc4_th, uint32_t a_total_count); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_sos( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__prepare_scan( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__use_default_huffman_table( wuffs_jpeg__decoder* self, uint8_t a_tc4_th); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__calculate_single_component_scan_fields( wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__calculate_multiple_component_scan_fields( wuffs_jpeg__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__fill_bitstream( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component__choosy_default( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__save_mcu_blocks( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__skip_past_the_next_restart_marker( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__apply_progressive_idct( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__swizzle_gray( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_x0, uint32_t a_x1, uint32_t a_y0, uint32_t a_y1, uint64_t a_stride); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__swizzle_colorful( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_x0, uint32_t a_x1, uint32_t a_y0, uint32_t a_y1); WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__top_left_quants_has_zero( const wuffs_jpeg__decoder* self, uint32_t a_q); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component_smooth( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu__choosy_default( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_ac_high_bits( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_ac_low_bit( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_dc_high_bits( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_dc_low_bit( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_jpeg__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_jpeg__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_jpeg__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_jpeg__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_jpeg__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_jpeg__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_jpeg__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_jpeg__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_jpeg__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_jpeg__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_jpeg__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_jpeg__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_jpeg__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_jpeg__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_jpeg__decoder__initialize( wuffs_jpeg__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_decode_idct = &wuffs_jpeg__decoder__decode_idct__choosy_default; self->private_impl.choosy_load_mcu_blocks_for_single_component = &wuffs_jpeg__decoder__load_mcu_blocks_for_single_component__choosy_default; self->private_impl.choosy_decode_mcu = &wuffs_jpeg__decoder__decode_mcu__choosy_default; self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_jpeg__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_jpeg__decoder* wuffs_jpeg__decoder__alloc(void) { wuffs_jpeg__decoder* x = (wuffs_jpeg__decoder*)(calloc(1, sizeof(wuffs_jpeg__decoder))); if (!x) { return NULL; } if (wuffs_jpeg__decoder__initialize( x, sizeof(wuffs_jpeg__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_jpeg__decoder(void) { return sizeof(wuffs_jpeg__decoder); } // ---------------- Function Implementations // -------- func jpeg.decoder.decode_idct WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q) { return (*self->private_impl.choosy_decode_idct)(self, a_dst_buffer, a_dst_stride, a_q); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct__choosy_default( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q) { uint32_t v_bq0 = 0; uint32_t v_bq2 = 0; uint32_t v_bq4 = 0; uint32_t v_bq6 = 0; uint32_t v_ca = 0; uint32_t v_cb2 = 0; uint32_t v_cb6 = 0; uint32_t v_ccp = 0; uint32_t v_ccm = 0; uint32_t v_cd0 = 0; uint32_t v_cd1 = 0; uint32_t v_cd2 = 0; uint32_t v_cd3 = 0; uint32_t v_bq1 = 0; uint32_t v_bq3 = 0; uint32_t v_bq5 = 0; uint32_t v_bq7 = 0; uint32_t v_ci51 = 0; uint32_t v_ci53 = 0; uint32_t v_ci71 = 0; uint32_t v_ci73 = 0; uint32_t v_cj = 0; uint32_t v_ck1 = 0; uint32_t v_ck3 = 0; uint32_t v_ck5 = 0; uint32_t v_ck7 = 0; uint32_t v_cl51 = 0; uint32_t v_cl73 = 0; uint32_t v_in0 = 0; uint32_t v_in2 = 0; uint32_t v_in4 = 0; uint32_t v_in6 = 0; uint32_t v_ra = 0; uint32_t v_rb2 = 0; uint32_t v_rb6 = 0; uint32_t v_rcp = 0; uint32_t v_rcm = 0; uint32_t v_rd0 = 0; uint32_t v_rd1 = 0; uint32_t v_rd2 = 0; uint32_t v_rd3 = 0; uint32_t v_in1 = 0; uint32_t v_in3 = 0; uint32_t v_in5 = 0; uint32_t v_in7 = 0; uint32_t v_ri51 = 0; uint32_t v_ri53 = 0; uint32_t v_ri71 = 0; uint32_t v_ri73 = 0; uint32_t v_rj = 0; uint32_t v_rk1 = 0; uint32_t v_rk3 = 0; uint32_t v_rk5 = 0; uint32_t v_rk7 = 0; uint32_t v_rl51 = 0; uint32_t v_rl73 = 0; uint32_t v_intermediate[64] = {0}; if (8u > a_dst_stride) { return wuffs_base__make_empty_struct(); } if (0u == (self->private_data.f_mcu_blocks[0u][8u] | self->private_data.f_mcu_blocks[0u][16u] | self->private_data.f_mcu_blocks[0u][24u] | self->private_data.f_mcu_blocks[0u][32u] | self->private_data.f_mcu_blocks[0u][40u] | self->private_data.f_mcu_blocks[0u][48u] | self->private_data.f_mcu_blocks[0u][56u])) { v_intermediate[0u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][0u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][0u])))) << 2u)); v_intermediate[8u] = v_intermediate[0u]; v_intermediate[16u] = v_intermediate[0u]; v_intermediate[24u] = v_intermediate[0u]; v_intermediate[32u] = v_intermediate[0u]; v_intermediate[40u] = v_intermediate[0u]; v_intermediate[48u] = v_intermediate[0u]; v_intermediate[56u] = v_intermediate[0u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][16u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][16u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][48u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][48u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][0u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][0u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][32u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][32u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][8u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][8u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][24u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][24u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][40u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][40u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][56u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][56u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[0u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[56u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[8u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[48u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[16u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[40u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[24u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[32u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][9u] | self->private_data.f_mcu_blocks[0u][17u] | self->private_data.f_mcu_blocks[0u][25u] | self->private_data.f_mcu_blocks[0u][33u] | self->private_data.f_mcu_blocks[0u][41u] | self->private_data.f_mcu_blocks[0u][49u] | self->private_data.f_mcu_blocks[0u][57u])) { v_intermediate[1u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][1u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][1u])))) << 2u)); v_intermediate[9u] = v_intermediate[1u]; v_intermediate[17u] = v_intermediate[1u]; v_intermediate[25u] = v_intermediate[1u]; v_intermediate[33u] = v_intermediate[1u]; v_intermediate[41u] = v_intermediate[1u]; v_intermediate[49u] = v_intermediate[1u]; v_intermediate[57u] = v_intermediate[1u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][17u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][17u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][49u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][49u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][1u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][1u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][33u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][33u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][9u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][9u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][25u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][25u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][41u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][41u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][57u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][57u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[1u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[57u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[9u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[49u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[17u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[41u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[25u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[33u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][10u] | self->private_data.f_mcu_blocks[0u][18u] | self->private_data.f_mcu_blocks[0u][26u] | self->private_data.f_mcu_blocks[0u][34u] | self->private_data.f_mcu_blocks[0u][42u] | self->private_data.f_mcu_blocks[0u][50u] | self->private_data.f_mcu_blocks[0u][58u])) { v_intermediate[2u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][2u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][2u])))) << 2u)); v_intermediate[10u] = v_intermediate[2u]; v_intermediate[18u] = v_intermediate[2u]; v_intermediate[26u] = v_intermediate[2u]; v_intermediate[34u] = v_intermediate[2u]; v_intermediate[42u] = v_intermediate[2u]; v_intermediate[50u] = v_intermediate[2u]; v_intermediate[58u] = v_intermediate[2u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][18u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][18u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][50u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][50u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][2u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][2u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][34u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][34u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][10u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][10u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][26u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][26u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][42u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][42u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][58u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][58u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[2u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[58u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[10u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[50u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[18u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[42u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[26u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[34u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][11u] | self->private_data.f_mcu_blocks[0u][19u] | self->private_data.f_mcu_blocks[0u][27u] | self->private_data.f_mcu_blocks[0u][35u] | self->private_data.f_mcu_blocks[0u][43u] | self->private_data.f_mcu_blocks[0u][51u] | self->private_data.f_mcu_blocks[0u][59u])) { v_intermediate[3u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][3u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][3u])))) << 2u)); v_intermediate[11u] = v_intermediate[3u]; v_intermediate[19u] = v_intermediate[3u]; v_intermediate[27u] = v_intermediate[3u]; v_intermediate[35u] = v_intermediate[3u]; v_intermediate[43u] = v_intermediate[3u]; v_intermediate[51u] = v_intermediate[3u]; v_intermediate[59u] = v_intermediate[3u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][19u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][19u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][51u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][51u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][3u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][3u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][35u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][35u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][11u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][11u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][27u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][27u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][43u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][43u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][59u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][59u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[3u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[59u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[11u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[51u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[19u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[43u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[27u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[35u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][12u] | self->private_data.f_mcu_blocks[0u][20u] | self->private_data.f_mcu_blocks[0u][28u] | self->private_data.f_mcu_blocks[0u][36u] | self->private_data.f_mcu_blocks[0u][44u] | self->private_data.f_mcu_blocks[0u][52u] | self->private_data.f_mcu_blocks[0u][60u])) { v_intermediate[4u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][4u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][4u])))) << 2u)); v_intermediate[12u] = v_intermediate[4u]; v_intermediate[20u] = v_intermediate[4u]; v_intermediate[28u] = v_intermediate[4u]; v_intermediate[36u] = v_intermediate[4u]; v_intermediate[44u] = v_intermediate[4u]; v_intermediate[52u] = v_intermediate[4u]; v_intermediate[60u] = v_intermediate[4u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][20u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][20u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][52u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][52u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][4u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][4u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][36u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][36u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][12u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][12u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][28u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][28u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][44u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][44u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][60u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][60u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[4u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[60u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[12u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[52u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[20u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[44u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[28u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[36u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][13u] | self->private_data.f_mcu_blocks[0u][21u] | self->private_data.f_mcu_blocks[0u][29u] | self->private_data.f_mcu_blocks[0u][37u] | self->private_data.f_mcu_blocks[0u][45u] | self->private_data.f_mcu_blocks[0u][53u] | self->private_data.f_mcu_blocks[0u][61u])) { v_intermediate[5u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][5u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][5u])))) << 2u)); v_intermediate[13u] = v_intermediate[5u]; v_intermediate[21u] = v_intermediate[5u]; v_intermediate[29u] = v_intermediate[5u]; v_intermediate[37u] = v_intermediate[5u]; v_intermediate[45u] = v_intermediate[5u]; v_intermediate[53u] = v_intermediate[5u]; v_intermediate[61u] = v_intermediate[5u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][21u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][21u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][53u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][53u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][5u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][5u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][37u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][37u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][13u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][13u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][29u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][29u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][45u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][45u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][61u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][61u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[5u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[61u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[13u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[53u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[21u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[45u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[29u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[37u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][14u] | self->private_data.f_mcu_blocks[0u][22u] | self->private_data.f_mcu_blocks[0u][30u] | self->private_data.f_mcu_blocks[0u][38u] | self->private_data.f_mcu_blocks[0u][46u] | self->private_data.f_mcu_blocks[0u][54u] | self->private_data.f_mcu_blocks[0u][62u])) { v_intermediate[6u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][6u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][6u])))) << 2u)); v_intermediate[14u] = v_intermediate[6u]; v_intermediate[22u] = v_intermediate[6u]; v_intermediate[30u] = v_intermediate[6u]; v_intermediate[38u] = v_intermediate[6u]; v_intermediate[46u] = v_intermediate[6u]; v_intermediate[54u] = v_intermediate[6u]; v_intermediate[62u] = v_intermediate[6u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][22u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][22u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][54u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][54u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][6u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][6u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][38u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][38u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][14u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][14u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][30u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][30u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][46u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][46u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][62u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][62u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[6u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[62u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[14u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[54u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[22u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[46u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[30u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[38u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (self->private_data.f_mcu_blocks[0u][15u] | self->private_data.f_mcu_blocks[0u][23u] | self->private_data.f_mcu_blocks[0u][31u] | self->private_data.f_mcu_blocks[0u][39u] | self->private_data.f_mcu_blocks[0u][47u] | self->private_data.f_mcu_blocks[0u][55u] | self->private_data.f_mcu_blocks[0u][63u])) { v_intermediate[7u] = ((uint32_t)(((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][7u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][7u])))) << 2u)); v_intermediate[15u] = v_intermediate[7u]; v_intermediate[23u] = v_intermediate[7u]; v_intermediate[31u] = v_intermediate[7u]; v_intermediate[39u] = v_intermediate[7u]; v_intermediate[47u] = v_intermediate[7u]; v_intermediate[55u] = v_intermediate[7u]; v_intermediate[63u] = v_intermediate[7u]; } else { v_bq2 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][23u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][23u])))); v_bq6 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][55u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][55u])))); v_ca = ((uint32_t)(((uint32_t)(v_bq2 + v_bq6)) * 4433u)); v_cb2 = ((uint32_t)(v_ca + ((uint32_t)(v_bq2 * 6270u)))); v_cb6 = ((uint32_t)(v_ca - ((uint32_t)(v_bq6 * 15137u)))); v_bq0 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][7u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][7u])))); v_bq4 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][39u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][39u])))); v_ccp = ((uint32_t)(((uint32_t)(v_bq0 + v_bq4)) << 13u)); v_ccm = ((uint32_t)(((uint32_t)(v_bq0 - v_bq4)) << 13u)); v_cd0 = ((uint32_t)(v_ccp + v_cb2)); v_cd1 = ((uint32_t)(v_ccm + v_cb6)); v_cd2 = ((uint32_t)(v_ccm - v_cb6)); v_cd3 = ((uint32_t)(v_ccp - v_cb2)); v_bq1 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][15u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][15u])))); v_bq3 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][31u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][31u])))); v_bq5 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][47u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][47u])))); v_bq7 = ((uint32_t)(wuffs_base__utility__sign_extend_convert_u16_u32(self->private_data.f_mcu_blocks[0u][63u]) * ((uint32_t)(self->private_impl.f_quant_tables[a_q][63u])))); v_ci51 = ((uint32_t)(v_bq5 + v_bq1)); v_ci53 = ((uint32_t)(v_bq5 + v_bq3)); v_ci71 = ((uint32_t)(v_bq7 + v_bq1)); v_ci73 = ((uint32_t)(v_bq7 + v_bq3)); v_cj = ((uint32_t)(((uint32_t)(v_ci73 + v_ci51)) * 9633u)); v_ck1 = ((uint32_t)(v_bq1 * 12299u)); v_ck3 = ((uint32_t)(v_bq3 * 25172u)); v_ck5 = ((uint32_t)(v_bq5 * 16819u)); v_ck7 = ((uint32_t)(v_bq7 * 2446u)); v_ci51 *= 4294964100u; v_ci53 *= 4294946301u; v_ci71 *= 4294959923u; v_ci73 *= 4294951227u; v_cl51 = ((uint32_t)(v_ci51 + v_cj)); v_cl73 = ((uint32_t)(v_ci73 + v_cj)); v_ck1 += ((uint32_t)(v_ci71 + v_cl51)); v_ck3 += ((uint32_t)(v_ci53 + v_cl73)); v_ck5 += ((uint32_t)(v_ci53 + v_cl51)); v_ck7 += ((uint32_t)(v_ci71 + v_cl73)); v_intermediate[7u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 + v_ck1)) + 1024u)), 11u); v_intermediate[63u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd0 - v_ck1)) + 1024u)), 11u); v_intermediate[15u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 + v_ck3)) + 1024u)), 11u); v_intermediate[55u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd1 - v_ck3)) + 1024u)), 11u); v_intermediate[23u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 + v_ck5)) + 1024u)), 11u); v_intermediate[47u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd2 - v_ck5)) + 1024u)), 11u); v_intermediate[31u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 + v_ck7)) + 1024u)), 11u); v_intermediate[39u] = wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(((uint32_t)(v_cd3 - v_ck7)) + 1024u)), 11u); } if (0u == (v_intermediate[1u] | v_intermediate[2u] | v_intermediate[3u] | v_intermediate[4u] | v_intermediate[5u] | v_intermediate[6u] | v_intermediate[7u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[0u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[2u]; v_in6 = v_intermediate[6u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[0u]; v_in4 = v_intermediate[4u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[1u]; v_in3 = v_intermediate[3u]; v_in5 = v_intermediate[5u]; v_in7 = v_intermediate[7u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[9u] | v_intermediate[10u] | v_intermediate[11u] | v_intermediate[12u] | v_intermediate[13u] | v_intermediate[14u] | v_intermediate[15u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[8u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[10u]; v_in6 = v_intermediate[14u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[8u]; v_in4 = v_intermediate[12u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[9u]; v_in3 = v_intermediate[11u]; v_in5 = v_intermediate[13u]; v_in7 = v_intermediate[15u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[17u] | v_intermediate[18u] | v_intermediate[19u] | v_intermediate[20u] | v_intermediate[21u] | v_intermediate[22u] | v_intermediate[23u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[16u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[18u]; v_in6 = v_intermediate[22u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[16u]; v_in4 = v_intermediate[20u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[17u]; v_in3 = v_intermediate[19u]; v_in5 = v_intermediate[21u]; v_in7 = v_intermediate[23u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[25u] | v_intermediate[26u] | v_intermediate[27u] | v_intermediate[28u] | v_intermediate[29u] | v_intermediate[30u] | v_intermediate[31u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[24u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[26u]; v_in6 = v_intermediate[30u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[24u]; v_in4 = v_intermediate[28u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[25u]; v_in3 = v_intermediate[27u]; v_in5 = v_intermediate[29u]; v_in7 = v_intermediate[31u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[33u] | v_intermediate[34u] | v_intermediate[35u] | v_intermediate[36u] | v_intermediate[37u] | v_intermediate[38u] | v_intermediate[39u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[32u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[34u]; v_in6 = v_intermediate[38u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[32u]; v_in4 = v_intermediate[36u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[33u]; v_in3 = v_intermediate[35u]; v_in5 = v_intermediate[37u]; v_in7 = v_intermediate[39u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[41u] | v_intermediate[42u] | v_intermediate[43u] | v_intermediate[44u] | v_intermediate[45u] | v_intermediate[46u] | v_intermediate[47u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[40u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[42u]; v_in6 = v_intermediate[46u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[40u]; v_in4 = v_intermediate[44u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[41u]; v_in3 = v_intermediate[43u]; v_in5 = v_intermediate[45u]; v_in7 = v_intermediate[47u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[49u] | v_intermediate[50u] | v_intermediate[51u] | v_intermediate[52u] | v_intermediate[53u] | v_intermediate[54u] | v_intermediate[55u])) { if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[48u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } else { v_in2 = v_intermediate[50u]; v_in6 = v_intermediate[54u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[48u]; v_in4 = v_intermediate[52u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[49u]; v_in3 = v_intermediate[51u]; v_in5 = v_intermediate[53u]; v_in7 = v_intermediate[55u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); } if (0u == (v_intermediate[57u] | v_intermediate[58u] | v_intermediate[59u] | v_intermediate[60u] | v_intermediate[61u] | v_intermediate[62u] | v_intermediate[63u])) { if (8u > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(v_intermediate[56u] + 16u)) >> 5u) & 1023u)]; a_dst_buffer.ptr[1u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[2u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[3u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[4u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[5u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[6u] = a_dst_buffer.ptr[0u]; a_dst_buffer.ptr[7u] = a_dst_buffer.ptr[0u]; } else { v_in2 = v_intermediate[58u]; v_in6 = v_intermediate[62u]; v_ra = ((uint32_t)(((uint32_t)(v_in2 + v_in6)) * 4433u)); v_rb2 = ((uint32_t)(v_ra + ((uint32_t)(v_in2 * 6270u)))); v_rb6 = ((uint32_t)(v_ra - ((uint32_t)(v_in6 * 15137u)))); v_in0 = v_intermediate[56u]; v_in4 = v_intermediate[60u]; v_rcp = ((uint32_t)(((uint32_t)(v_in0 + v_in4)) << 13u)); v_rcm = ((uint32_t)(((uint32_t)(v_in0 - v_in4)) << 13u)); v_rd0 = ((uint32_t)(v_rcp + v_rb2)); v_rd1 = ((uint32_t)(v_rcm + v_rb6)); v_rd2 = ((uint32_t)(v_rcm - v_rb6)); v_rd3 = ((uint32_t)(v_rcp - v_rb2)); v_in1 = v_intermediate[57u]; v_in3 = v_intermediate[59u]; v_in5 = v_intermediate[61u]; v_in7 = v_intermediate[63u]; v_ri51 = ((uint32_t)(v_in5 + v_in1)); v_ri53 = ((uint32_t)(v_in5 + v_in3)); v_ri71 = ((uint32_t)(v_in7 + v_in1)); v_ri73 = ((uint32_t)(v_in7 + v_in3)); v_rj = ((uint32_t)(((uint32_t)(v_ri73 + v_ri51)) * 9633u)); v_rk1 = ((uint32_t)(v_in1 * 12299u)); v_rk3 = ((uint32_t)(v_in3 * 25172u)); v_rk5 = ((uint32_t)(v_in5 * 16819u)); v_rk7 = ((uint32_t)(v_in7 * 2446u)); v_ri51 *= 4294964100u; v_ri53 *= 4294946301u; v_ri71 *= 4294959923u; v_ri73 *= 4294951227u; v_rl51 = ((uint32_t)(v_ri51 + v_rj)); v_rl73 = ((uint32_t)(v_ri73 + v_rj)); v_rk1 += ((uint32_t)(v_ri71 + v_rl51)); v_rk3 += ((uint32_t)(v_ri53 + v_rl73)); v_rk5 += ((uint32_t)(v_ri53 + v_rl51)); v_rk7 += ((uint32_t)(v_ri71 + v_rl73)); if (8u > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } a_dst_buffer.ptr[0u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 + v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[7u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd0 - v_rk1)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[1u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 + v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[6u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd1 - v_rk3)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[2u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 + v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[5u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd2 - v_rk5)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[3u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 + v_rk7)) + 131072u)) >> 18u) & 1023u)]; a_dst_buffer.ptr[4u] = WUFFS_JPEG__BIAS_AND_CLAMP[((((uint32_t)(((uint32_t)(v_rd3 - v_rk7)) + 131072u)) >> 18u) & 1023u)]; } return wuffs_base__make_empty_struct(); } // ‼ WUFFS MULTI-FILE SECTION +x86_avx2 // -------- func jpeg.decoder.decode_idct_x86_avx2 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2,avx2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__decode_idct_x86_avx2( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_dst_buffer, uint64_t a_dst_stride, uint32_t a_q) { __m256i v_k_0000 = {0}; __m256i v_k_8080 = {0}; __m256i v_k_0000_0002 = {0}; __m256i v_k_0001_FFFF = {0}; __m256i v_k_0400_0000 = {0}; __m256i v_k_29CF_1151_D630_1151 = {0}; __m256i v_k_E333_133E_ADFD_1051 = {0}; __m256i v_k_E6DC_25A1_1925_25A1 = {0}; __m256i v_k_ECC1_E333_EFB0_ADFD = {0}; __m128i v_az_coeffs = {0}; __m256i v_az_ah00 = {0}; __m256i v_az_ad00 = {0}; __m256i v_az_eh00 = {0}; __m256i v_az_adeh = {0}; __m256i v_rows01 = {0}; __m256i v_rows23 = {0}; __m256i v_rows45 = {0}; __m256i v_rows67 = {0}; __m256i v_quants01 = {0}; __m256i v_quants23 = {0}; __m256i v_quants45 = {0}; __m256i v_quants67 = {0}; __m256i v_rows04 = {0}; __m256i v_rows31 = {0}; __m256i v_rows26 = {0}; __m256i v_rows75 = {0}; __m256i v_fp_rows62 = {0}; __m256i v_fp_bq2662ad = {0}; __m256i v_fp_bq2662eh = {0}; __m256i v_fp_cb26ad = {0}; __m256i v_fp_cb26eh = {0}; __m256i v_fp_rows40pos = {0}; __m256i v_fp_rows04neg = {0}; __m256i v_fp_rows0pm4 = {0}; __m256i v_fp_ccpmad = {0}; __m256i v_fp_ccpmeh = {0}; __m256i v_fp_cd01ad = {0}; __m256i v_fp_cd01eh = {0}; __m256i v_fp_cd32ad = {0}; __m256i v_fp_cd32eh = {0}; __m256i v_fp_sums7351 = {0}; __m256i v_fp_sums5173 = {0}; __m256i v_fp_ci73515173ad = {0}; __m256i v_fp_ci73515173eh = {0}; __m256i v_fp_cl7351ad = {0}; __m256i v_fp_cl7351eh = {0}; __m256i v_fp_rows13 = {0}; __m256i v_fp_bq7153ad = {0}; __m256i v_fp_bq7153eh = {0}; __m256i v_fp_ck75ad = {0}; __m256i v_fp_ck75eh = {0}; __m256i v_fp_cl5173ad = {0}; __m256i v_fp_cl5173eh = {0}; __m256i v_fp_ck13ad = {0}; __m256i v_fp_ck13eh = {0}; __m256i v_intermediate01ad = {0}; __m256i v_intermediate01eh = {0}; __m256i v_intermediate01 = {0}; __m256i v_intermediate32ad = {0}; __m256i v_intermediate32eh = {0}; __m256i v_intermediate32 = {0}; __m256i v_intermediate45ad = {0}; __m256i v_intermediate45eh = {0}; __m256i v_intermediate45 = {0}; __m256i v_intermediate76ad = {0}; __m256i v_intermediate76eh = {0}; __m256i v_intermediate76 = {0}; __m256i v_ita0a1e0e1 = {0}; __m256i v_ita2a3e2e3 = {0}; __m256i v_ita4a5e4e5 = {0}; __m256i v_ita6a7e6e7 = {0}; __m256i v_ita0c0e0g0 = {0}; __m256i v_ita1c1e1g1 = {0}; __m256i v_ita4c4e4g4 = {0}; __m256i v_ita5c5e5g5 = {0}; __m256i v_ita0b0e0f0 = {0}; __m256i v_ita4b4e4f4 = {0}; __m256i v_itc0d0g0h0 = {0}; __m256i v_itc4d4g4h4 = {0}; __m256i v_intermediateae = {0}; __m256i v_intermediatebf = {0}; __m256i v_intermediatecg = {0}; __m256i v_intermediatedh = {0}; __m256i v_intermediatedb = {0}; __m256i v_intermediatehf = {0}; __m256i v_sp_cols62 = {0}; __m256i v_sp_bq2662ad = {0}; __m256i v_sp_bq2662eh = {0}; __m256i v_sp_rb26ad = {0}; __m256i v_sp_rb26eh = {0}; __m256i v_sp_cols40pos = {0}; __m256i v_sp_cols04neg = {0}; __m256i v_sp_cols0pm4 = {0}; __m256i v_sp_rcpmad = {0}; __m256i v_sp_rcpmeh = {0}; __m256i v_sp_rd01ad = {0}; __m256i v_sp_rd01eh = {0}; __m256i v_sp_rd32ad = {0}; __m256i v_sp_rd32eh = {0}; __m256i v_sp_sums7351 = {0}; __m256i v_sp_sums5173 = {0}; __m256i v_sp_ri73515173ad = {0}; __m256i v_sp_ri73515173eh = {0}; __m256i v_sp_rl7351ad = {0}; __m256i v_sp_rl7351eh = {0}; __m256i v_sp_cols13 = {0}; __m256i v_sp_bq7153ad = {0}; __m256i v_sp_bq7153eh = {0}; __m256i v_sp_rk75ad = {0}; __m256i v_sp_rk75eh = {0}; __m256i v_sp_rl5173ad = {0}; __m256i v_sp_rl5173eh = {0}; __m256i v_sp_rk13ad = {0}; __m256i v_sp_rk13eh = {0}; __m256i v_final01ad = {0}; __m256i v_final01eh = {0}; __m256i v_final01 = {0}; __m256i v_final32ad = {0}; __m256i v_final32eh = {0}; __m256i v_final32 = {0}; __m256i v_final45ad = {0}; __m256i v_final45eh = {0}; __m256i v_final45 = {0}; __m256i v_final76ad = {0}; __m256i v_final76eh = {0}; __m256i v_final76 = {0}; __m256i v_fta0a1e0e1 = {0}; __m256i v_fta2a3e2e3 = {0}; __m256i v_fta4a5e4e5 = {0}; __m256i v_fta6a7e6e7 = {0}; __m256i v_fta0c0e0g0 = {0}; __m256i v_fta1c1e1g1 = {0}; __m256i v_fta4c4e4g4 = {0}; __m256i v_fta5c5e5g5 = {0}; __m256i v_fta0b0e0f0 = {0}; __m256i v_ftc0d0g0h0 = {0}; __m256i v_fta4b4e4f4 = {0}; __m256i v_ftc4d4g4h4 = {0}; __m256i v_finalae = {0}; __m256i v_finalbf = {0}; __m256i v_finalcg = {0}; __m256i v_finaldh = {0}; __m256i v_final0145 = {0}; __m256i v_final2367 = {0}; uint64_t v_final0 = 0; uint64_t v_final1 = 0; uint64_t v_final2 = 0; uint64_t v_final3 = 0; uint64_t v_final4 = 0; uint64_t v_final5 = 0; uint64_t v_final6 = 0; uint64_t v_final7 = 0; wuffs_base__slice_u8 v_remaining = {0}; if (8u > a_dst_stride) { return wuffs_base__make_empty_struct(); } v_k_0000 = _mm256_set_epi16((int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u), (int16_t)(0u)); v_k_8080 = _mm256_set_epi16((int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u), (int16_t)(32896u)); v_k_0000_0002 = _mm256_set_epi16((int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u), (int16_t)(2u), (int16_t)(0u)); v_k_0001_FFFF = _mm256_set_epi16((int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(65535u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u), (int16_t)(1u)); v_k_0400_0000 = _mm256_set_epi16((int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u), (int16_t)(0u), (int16_t)(1024u)); v_k_29CF_1151_D630_1151 = _mm256_set_epi16((int16_t)(4433u), (int16_t)(54832u), (int16_t)(4433u), (int16_t)(54832u), (int16_t)(4433u), (int16_t)(54832u), (int16_t)(4433u), (int16_t)(54832u), (int16_t)(4433u), (int16_t)(10703u), (int16_t)(4433u), (int16_t)(10703u), (int16_t)(4433u), (int16_t)(10703u), (int16_t)(4433u), (int16_t)(10703u)); v_k_E333_133E_ADFD_1051 = _mm256_set_epi16((int16_t)(4177u), (int16_t)(44541u), (int16_t)(4177u), (int16_t)(44541u), (int16_t)(4177u), (int16_t)(44541u), (int16_t)(4177u), (int16_t)(44541u), (int16_t)(4926u), (int16_t)(58163u), (int16_t)(4926u), (int16_t)(58163u), (int16_t)(4926u), (int16_t)(58163u), (int16_t)(4926u), (int16_t)(58163u)); v_k_E6DC_25A1_1925_25A1 = _mm256_set_epi16((int16_t)(9633u), (int16_t)(6437u), (int16_t)(9633u), (int16_t)(6437u), (int16_t)(9633u), (int16_t)(6437u), (int16_t)(9633u), (int16_t)(6437u), (int16_t)(9633u), (int16_t)(59100u), (int16_t)(9633u), (int16_t)(59100u), (int16_t)(9633u), (int16_t)(59100u), (int16_t)(9633u), (int16_t)(59100u)); v_k_ECC1_E333_EFB0_ADFD = _mm256_set_epi16((int16_t)(44541u), (int16_t)(61360u), (int16_t)(44541u), (int16_t)(61360u), (int16_t)(44541u), (int16_t)(61360u), (int16_t)(44541u), (int16_t)(61360u), (int16_t)(58163u), (int16_t)(60609u), (int16_t)(58163u), (int16_t)(60609u), (int16_t)(58163u), (int16_t)(60609u), (int16_t)(58163u), (int16_t)(60609u)); do { if (0u == (wuffs_base__peek_u64le__no_bounds_check((const uint8_t*)(const void*)(self->private_data.f_mcu_blocks[0u] + 8u)) | wuffs_base__peek_u64le__no_bounds_check((const uint8_t*)(const void*)(self->private_data.f_mcu_blocks[0u] + 16u)))) { v_az_coeffs = _mm_or_si128(_mm_or_si128(_mm_or_si128(_mm_or_si128(_mm_or_si128(_mm_or_si128(_mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 8u)), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 16u))), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 24u))), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 32u))), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 40u))), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 48u))), _mm_lddqu_si128((const __m128i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 56u))); if (0u == ((uint64_t)(_mm_cvtsi128_si64(_mm_packs_epi16(v_az_coeffs, v_az_coeffs))))) { v_rows01 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 0u)); v_quants01 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_impl.f_quant_tables[a_q] + 0u)); v_rows01 = _mm256_mullo_epi16(v_rows01, v_quants01); v_az_ah00 = _mm256_slli_epi16(v_rows01, (int32_t)(2u)); v_az_ad00 = _mm256_unpacklo_epi16(v_az_ah00, v_az_ah00); v_az_eh00 = _mm256_unpackhi_epi16(v_az_ah00, v_az_ah00); v_az_adeh = _mm256_inserti128_si256(v_az_ad00, _mm256_castsi256_si128(v_az_eh00), (int32_t)(1u)); v_intermediateae = _mm256_shuffle_epi32(v_az_adeh, (int32_t)(0u)); v_intermediatebf = _mm256_shuffle_epi32(v_az_adeh, (int32_t)(85u)); v_intermediatecg = _mm256_shuffle_epi32(v_az_adeh, (int32_t)(170u)); v_intermediatedh = _mm256_shuffle_epi32(v_az_adeh, (int32_t)(255u)); break; } } v_rows01 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 0u)); v_rows23 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 16u)); v_rows45 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 32u)); v_rows67 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_data.f_mcu_blocks[0u] + 48u)); v_quants01 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_impl.f_quant_tables[a_q] + 0u)); v_quants23 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_impl.f_quant_tables[a_q] + 16u)); v_quants45 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_impl.f_quant_tables[a_q] + 32u)); v_quants67 = _mm256_lddqu_si256((const __m256i*)(const void*)(self->private_impl.f_quant_tables[a_q] + 48u)); v_rows01 = _mm256_mullo_epi16(v_rows01, v_quants01); v_rows23 = _mm256_mullo_epi16(v_rows23, v_quants23); v_rows45 = _mm256_mullo_epi16(v_rows45, v_quants45); v_rows67 = _mm256_mullo_epi16(v_rows67, v_quants67); v_rows04 = _mm256_permute2x128_si256(v_rows01, v_rows45, (int32_t)(32u)); v_rows31 = _mm256_permute2x128_si256(v_rows23, v_rows01, (int32_t)(49u)); v_rows26 = _mm256_permute2x128_si256(v_rows23, v_rows67, (int32_t)(32u)); v_rows75 = _mm256_permute2x128_si256(v_rows67, v_rows45, (int32_t)(49u)); v_fp_rows62 = _mm256_permute2x128_si256(v_rows26, v_rows26, (int32_t)(1u)); v_fp_bq2662ad = _mm256_unpacklo_epi16(v_rows26, v_fp_rows62); v_fp_bq2662eh = _mm256_unpackhi_epi16(v_rows26, v_fp_rows62); v_fp_cb26ad = _mm256_madd_epi16(v_fp_bq2662ad, v_k_29CF_1151_D630_1151); v_fp_cb26eh = _mm256_madd_epi16(v_fp_bq2662eh, v_k_29CF_1151_D630_1151); v_fp_rows40pos = _mm256_permute2x128_si256(v_rows04, v_rows04, (int32_t)(1u)); v_fp_rows04neg = _mm256_sign_epi16(v_rows04, v_k_0001_FFFF); v_fp_rows0pm4 = _mm256_add_epi16(v_fp_rows40pos, v_fp_rows04neg); v_fp_ccpmad = _mm256_srai_epi32(_mm256_unpacklo_epi16(v_k_0000, v_fp_rows0pm4), (int32_t)(3u)); v_fp_ccpmeh = _mm256_srai_epi32(_mm256_unpackhi_epi16(v_k_0000, v_fp_rows0pm4), (int32_t)(3u)); v_fp_cd01ad = _mm256_add_epi32(v_fp_ccpmad, v_fp_cb26ad); v_fp_cd01eh = _mm256_add_epi32(v_fp_ccpmeh, v_fp_cb26eh); v_fp_cd32ad = _mm256_sub_epi32(v_fp_ccpmad, v_fp_cb26ad); v_fp_cd32eh = _mm256_sub_epi32(v_fp_ccpmeh, v_fp_cb26eh); v_fp_sums7351 = _mm256_add_epi16(v_rows75, v_rows31); v_fp_sums5173 = _mm256_permute2x128_si256(v_fp_sums7351, v_fp_sums7351, (int32_t)(1u)); v_fp_ci73515173ad = _mm256_unpacklo_epi16(v_fp_sums7351, v_fp_sums5173); v_fp_ci73515173eh = _mm256_unpackhi_epi16(v_fp_sums7351, v_fp_sums5173); v_fp_cl7351ad = _mm256_madd_epi16(v_fp_ci73515173ad, v_k_E6DC_25A1_1925_25A1); v_fp_cl7351eh = _mm256_madd_epi16(v_fp_ci73515173eh, v_k_E6DC_25A1_1925_25A1); v_fp_rows13 = _mm256_permute2x128_si256(v_rows31, v_rows31, (int32_t)(1u)); v_fp_bq7153ad = _mm256_unpacklo_epi16(v_rows75, v_fp_rows13); v_fp_bq7153eh = _mm256_unpackhi_epi16(v_rows75, v_fp_rows13); v_fp_ck75ad = _mm256_add_epi32(_mm256_madd_epi16(v_fp_bq7153ad, v_k_ECC1_E333_EFB0_ADFD), v_fp_cl7351ad); v_fp_ck75eh = _mm256_add_epi32(_mm256_madd_epi16(v_fp_bq7153eh, v_k_ECC1_E333_EFB0_ADFD), v_fp_cl7351eh); v_fp_cl5173ad = _mm256_permute2x128_si256(v_fp_cl7351ad, v_fp_cl7351ad, (int32_t)(1u)); v_fp_cl5173eh = _mm256_permute2x128_si256(v_fp_cl7351eh, v_fp_cl7351eh, (int32_t)(1u)); v_fp_ck13ad = _mm256_add_epi32(v_fp_cl5173ad, _mm256_madd_epi16(v_fp_bq7153ad, v_k_E333_133E_ADFD_1051)); v_fp_ck13eh = _mm256_add_epi32(v_fp_cl5173eh, _mm256_madd_epi16(v_fp_bq7153eh, v_k_E333_133E_ADFD_1051)); v_intermediate01ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_fp_cd01ad, v_fp_ck13ad), v_k_0400_0000), (int32_t)(11u)); v_intermediate01eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_fp_cd01eh, v_fp_ck13eh), v_k_0400_0000), (int32_t)(11u)); v_intermediate01 = _mm256_packs_epi32(v_intermediate01ad, v_intermediate01eh); v_intermediate32ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_fp_cd32ad, v_fp_ck75ad), v_k_0400_0000), (int32_t)(11u)); v_intermediate32eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_fp_cd32eh, v_fp_ck75eh), v_k_0400_0000), (int32_t)(11u)); v_intermediate32 = _mm256_packs_epi32(v_intermediate32ad, v_intermediate32eh); v_intermediate45ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_fp_cd32ad, v_fp_ck75ad), v_k_0400_0000), (int32_t)(11u)); v_intermediate45eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_fp_cd32eh, v_fp_ck75eh), v_k_0400_0000), (int32_t)(11u)); v_intermediate45 = _mm256_packs_epi32(v_intermediate45ad, v_intermediate45eh); v_intermediate76ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_fp_cd01ad, v_fp_ck13ad), v_k_0400_0000), (int32_t)(11u)); v_intermediate76eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_fp_cd01eh, v_fp_ck13eh), v_k_0400_0000), (int32_t)(11u)); v_intermediate76 = _mm256_packs_epi32(v_intermediate76ad, v_intermediate76eh); v_ita0a1e0e1 = _mm256_permute4x64_epi64(v_intermediate01, (int32_t)(216u)); v_ita2a3e2e3 = _mm256_permute4x64_epi64(v_intermediate32, (int32_t)(114u)); v_ita4a5e4e5 = _mm256_permute4x64_epi64(v_intermediate45, (int32_t)(216u)); v_ita6a7e6e7 = _mm256_permute4x64_epi64(v_intermediate76, (int32_t)(114u)); v_ita0c0e0g0 = _mm256_unpacklo_epi16(v_ita0a1e0e1, v_ita2a3e2e3); v_ita1c1e1g1 = _mm256_unpackhi_epi16(v_ita0a1e0e1, v_ita2a3e2e3); v_ita4c4e4g4 = _mm256_unpacklo_epi16(v_ita4a5e4e5, v_ita6a7e6e7); v_ita5c5e5g5 = _mm256_unpackhi_epi16(v_ita4a5e4e5, v_ita6a7e6e7); v_ita0b0e0f0 = _mm256_unpacklo_epi16(v_ita0c0e0g0, v_ita1c1e1g1); v_itc0d0g0h0 = _mm256_unpackhi_epi16(v_ita0c0e0g0, v_ita1c1e1g1); v_ita4b4e4f4 = _mm256_unpacklo_epi16(v_ita4c4e4g4, v_ita5c5e5g5); v_itc4d4g4h4 = _mm256_unpackhi_epi16(v_ita4c4e4g4, v_ita5c5e5g5); v_intermediateae = _mm256_unpacklo_epi64(v_ita0b0e0f0, v_ita4b4e4f4); v_intermediatebf = _mm256_unpackhi_epi64(v_ita0b0e0f0, v_ita4b4e4f4); v_intermediatecg = _mm256_unpacklo_epi64(v_itc0d0g0h0, v_itc4d4g4h4); v_intermediatedh = _mm256_unpackhi_epi64(v_itc0d0g0h0, v_itc4d4g4h4); } while (0); v_intermediatedb = _mm256_permute2x128_si256(v_intermediatedh, v_intermediatebf, (int32_t)(32u)); v_intermediatehf = _mm256_permute2x128_si256(v_intermediatedh, v_intermediatebf, (int32_t)(49u)); v_sp_cols62 = _mm256_permute2x128_si256(v_intermediatecg, v_intermediatecg, (int32_t)(1u)); v_sp_bq2662ad = _mm256_unpacklo_epi16(v_intermediatecg, v_sp_cols62); v_sp_bq2662eh = _mm256_unpackhi_epi16(v_intermediatecg, v_sp_cols62); v_sp_rb26ad = _mm256_madd_epi16(v_sp_bq2662ad, v_k_29CF_1151_D630_1151); v_sp_rb26eh = _mm256_madd_epi16(v_sp_bq2662eh, v_k_29CF_1151_D630_1151); v_sp_cols40pos = _mm256_permute2x128_si256(v_intermediateae, v_intermediateae, (int32_t)(1u)); v_sp_cols04neg = _mm256_sign_epi16(v_intermediateae, v_k_0001_FFFF); v_sp_cols0pm4 = _mm256_add_epi16(v_sp_cols40pos, v_sp_cols04neg); v_sp_rcpmad = _mm256_srai_epi32(_mm256_unpacklo_epi16(v_k_0000, v_sp_cols0pm4), (int32_t)(3u)); v_sp_rcpmeh = _mm256_srai_epi32(_mm256_unpackhi_epi16(v_k_0000, v_sp_cols0pm4), (int32_t)(3u)); v_sp_rd01ad = _mm256_add_epi32(v_sp_rcpmad, v_sp_rb26ad); v_sp_rd01eh = _mm256_add_epi32(v_sp_rcpmeh, v_sp_rb26eh); v_sp_rd32ad = _mm256_sub_epi32(v_sp_rcpmad, v_sp_rb26ad); v_sp_rd32eh = _mm256_sub_epi32(v_sp_rcpmeh, v_sp_rb26eh); v_sp_sums7351 = _mm256_add_epi16(v_intermediatehf, v_intermediatedb); v_sp_sums5173 = _mm256_permute2x128_si256(v_sp_sums7351, v_sp_sums7351, (int32_t)(1u)); v_sp_ri73515173ad = _mm256_unpacklo_epi16(v_sp_sums7351, v_sp_sums5173); v_sp_ri73515173eh = _mm256_unpackhi_epi16(v_sp_sums7351, v_sp_sums5173); v_sp_rl7351ad = _mm256_madd_epi16(v_sp_ri73515173ad, v_k_E6DC_25A1_1925_25A1); v_sp_rl7351eh = _mm256_madd_epi16(v_sp_ri73515173eh, v_k_E6DC_25A1_1925_25A1); v_sp_cols13 = _mm256_permute2x128_si256(v_intermediatedb, v_intermediatedb, (int32_t)(1u)); v_sp_bq7153ad = _mm256_unpacklo_epi16(v_intermediatehf, v_sp_cols13); v_sp_bq7153eh = _mm256_unpackhi_epi16(v_intermediatehf, v_sp_cols13); v_sp_rk75ad = _mm256_add_epi32(_mm256_madd_epi16(v_sp_bq7153ad, v_k_ECC1_E333_EFB0_ADFD), v_sp_rl7351ad); v_sp_rk75eh = _mm256_add_epi32(_mm256_madd_epi16(v_sp_bq7153eh, v_k_ECC1_E333_EFB0_ADFD), v_sp_rl7351eh); v_sp_rl5173ad = _mm256_permute2x128_si256(v_sp_rl7351ad, v_sp_rl7351ad, (int32_t)(1u)); v_sp_rl5173eh = _mm256_permute2x128_si256(v_sp_rl7351eh, v_sp_rl7351eh, (int32_t)(1u)); v_sp_rk13ad = _mm256_add_epi32(v_sp_rl5173ad, _mm256_madd_epi16(v_sp_bq7153ad, v_k_E333_133E_ADFD_1051)); v_sp_rk13eh = _mm256_add_epi32(v_sp_rl5173eh, _mm256_madd_epi16(v_sp_bq7153eh, v_k_E333_133E_ADFD_1051)); v_final01ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_sp_rd01ad, v_sp_rk13ad), v_k_0000_0002), (int32_t)(18u)); v_final01eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_sp_rd01eh, v_sp_rk13eh), v_k_0000_0002), (int32_t)(18u)); v_final01 = _mm256_packs_epi32(v_final01ad, v_final01eh); v_final32ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_sp_rd32ad, v_sp_rk75ad), v_k_0000_0002), (int32_t)(18u)); v_final32eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_add_epi32(v_sp_rd32eh, v_sp_rk75eh), v_k_0000_0002), (int32_t)(18u)); v_final32 = _mm256_packs_epi32(v_final32ad, v_final32eh); v_final45ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_sp_rd32ad, v_sp_rk75ad), v_k_0000_0002), (int32_t)(18u)); v_final45eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_sp_rd32eh, v_sp_rk75eh), v_k_0000_0002), (int32_t)(18u)); v_final45 = _mm256_packs_epi32(v_final45ad, v_final45eh); v_final76ad = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_sp_rd01ad, v_sp_rk13ad), v_k_0000_0002), (int32_t)(18u)); v_final76eh = _mm256_srai_epi32(_mm256_add_epi32(_mm256_sub_epi32(v_sp_rd01eh, v_sp_rk13eh), v_k_0000_0002), (int32_t)(18u)); v_final76 = _mm256_packs_epi32(v_final76ad, v_final76eh); v_fta0a1e0e1 = _mm256_permute4x64_epi64(v_final01, (int32_t)(216u)); v_fta2a3e2e3 = _mm256_permute4x64_epi64(v_final32, (int32_t)(114u)); v_fta4a5e4e5 = _mm256_permute4x64_epi64(v_final45, (int32_t)(216u)); v_fta6a7e6e7 = _mm256_permute4x64_epi64(v_final76, (int32_t)(114u)); v_fta0c0e0g0 = _mm256_unpacklo_epi16(v_fta0a1e0e1, v_fta2a3e2e3); v_fta1c1e1g1 = _mm256_unpackhi_epi16(v_fta0a1e0e1, v_fta2a3e2e3); v_fta4c4e4g4 = _mm256_unpacklo_epi16(v_fta4a5e4e5, v_fta6a7e6e7); v_fta5c5e5g5 = _mm256_unpackhi_epi16(v_fta4a5e4e5, v_fta6a7e6e7); v_fta0b0e0f0 = _mm256_unpacklo_epi16(v_fta0c0e0g0, v_fta1c1e1g1); v_ftc0d0g0h0 = _mm256_unpackhi_epi16(v_fta0c0e0g0, v_fta1c1e1g1); v_fta4b4e4f4 = _mm256_unpacklo_epi16(v_fta4c4e4g4, v_fta5c5e5g5); v_ftc4d4g4h4 = _mm256_unpackhi_epi16(v_fta4c4e4g4, v_fta5c5e5g5); v_finalae = _mm256_unpacklo_epi64(v_fta0b0e0f0, v_fta4b4e4f4); v_finalbf = _mm256_unpackhi_epi64(v_fta0b0e0f0, v_fta4b4e4f4); v_finalcg = _mm256_unpacklo_epi64(v_ftc0d0g0h0, v_ftc4d4g4h4); v_finaldh = _mm256_unpackhi_epi64(v_ftc0d0g0h0, v_ftc4d4g4h4); v_final0145 = _mm256_add_epi8(_mm256_packs_epi16(v_finalae, v_finalbf), v_k_8080); v_final2367 = _mm256_add_epi8(_mm256_packs_epi16(v_finalcg, v_finaldh), v_k_8080); v_final0 = ((uint64_t)(_mm256_extract_epi64(v_final0145, (int32_t)(0u)))); v_final1 = ((uint64_t)(_mm256_extract_epi64(v_final0145, (int32_t)(1u)))); v_final2 = ((uint64_t)(_mm256_extract_epi64(v_final2367, (int32_t)(0u)))); v_final3 = ((uint64_t)(_mm256_extract_epi64(v_final2367, (int32_t)(1u)))); v_final4 = ((uint64_t)(_mm256_extract_epi64(v_final0145, (int32_t)(2u)))); v_final5 = ((uint64_t)(_mm256_extract_epi64(v_final0145, (int32_t)(3u)))); v_final6 = ((uint64_t)(_mm256_extract_epi64(v_final2367, (int32_t)(2u)))); v_final7 = ((uint64_t)(_mm256_extract_epi64(v_final2367, (int32_t)(3u)))); if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final0); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final1); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final2); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final3); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final4); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final5); a_dst_buffer = v_remaining; if (a_dst_stride > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } v_remaining = wuffs_base__slice_u8__subslice_i(a_dst_buffer, a_dst_stride); wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final6); a_dst_buffer = v_remaining; if (8u > ((uint64_t)(a_dst_buffer.len))) { return wuffs_base__make_empty_struct(); } wuffs_base__poke_u64le__no_bounds_check(a_dst_buffer.ptr, v_final7); return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) // ‼ WUFFS MULTI-FILE SECTION -x86_avx2 // -------- func jpeg.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__get_quirk( const wuffs_jpeg__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (a_key == 2u) { if (self->private_impl.f_use_lower_quality) { return 18446744073709551615u; } } else if (a_key == 1220532224u) { if (self->private_impl.f_reject_progressive_jpegs) { return 1u; } } return 0u; } // -------- func jpeg.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__set_quirk( wuffs_jpeg__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 2u) { self->private_impl.f_use_lower_quality = (a_value >= 9223372036854775808u); return wuffs_base__make_status(NULL); } else if (a_key == 1220532224u) { self->private_impl.f_reject_progressive_jpegs = (a_value != 0u); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func jpeg.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_image_config( wuffs_jpeg__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_jpeg__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_jpeg__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func jpeg.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_image_config( wuffs_jpeg__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_marker = 0; uint32_t v_pixfmt = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; if (coro_susp_point) { v_marker = self->private_data.s_do_decode_image_config.v_marker; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 255u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_c8 != 216u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_header); goto exit; } while (true) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_c8 == 255u) { break; } } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (v_c8 != 255u) { v_marker = v_c8; break; } } if (v_marker == 0u) { continue; } else if ((208u <= v_marker) && (v_marker <= 217u)) { if (v_marker <= 215u) { continue; } } else { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_4); if (num_bits_4 == 8) { t_4 = ((uint32_t)(*scratch >> 48)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)); } } self->private_impl.f_payload_length = t_4; } if (self->private_impl.f_payload_length < 2u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_marker); goto exit; } self->private_impl.f_payload_length -= 2u; } if (v_marker < 192u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } else if (v_marker < 208u) { if (v_marker <= 194u) { if ((v_marker == 194u) && self->private_impl.f_reject_progressive_jpegs) { status = wuffs_base__make_status(wuffs_jpeg__error__rejected_progressive_jpeg); goto exit; } else if (self->private_impl.f_sof_marker != 0u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } self->private_impl.f_sof_marker = v_marker; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); status = wuffs_jpeg__decoder__decode_sof(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } break; } else if (v_marker == 195u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_lossless_coding); goto exit; } else if (v_marker == 196u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } else if ((197u <= v_marker) && (v_marker <= 199u)) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_hierarchical_coding); goto exit; } else if (v_marker == 200u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_arithmetic_coding); goto exit; } } else if (v_marker < 224u) { if (v_marker < 218u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_marker); goto exit; } else if (v_marker == 218u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } else if (v_marker == 219u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_jpeg__decoder__decode_dqt(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else if (v_marker == 221u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_jpeg__decoder__decode_dri(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } } else if (v_marker < 240u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); status = wuffs_jpeg__decoder__decode_appn(self, a_src, v_marker); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else { if (v_marker == 254u) { } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } } self->private_data.s_do_decode_image_config.scratch = self->private_impl.f_payload_length; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; self->private_impl.f_payload_length = 0u; } self->private_impl.choosy_decode_idct = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V3) wuffs_base__cpu_arch__have_x86_avx2() ? &wuffs_jpeg__decoder__decode_idct_x86_avx2 : #endif self->private_impl.choosy_decode_idct); self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { v_pixfmt = 536870920u; if (self->private_impl.f_num_components > 1u) { v_pixfmt = 2415954056u; } wuffs_base__image_config__set( a_dst, v_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, true); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_image_config.v_marker = v_marker; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_dqt WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dqt( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_q = 0; uint32_t v_i = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_dqt; if (coro_susp_point) { v_q = self->private_data.s_decode_dqt.v_q; v_i = self->private_data.s_decode_dqt.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (self->private_impl.f_payload_length > 0u) { self->private_impl.f_payload_length -= 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (((uint8_t)(v_c8 & 15u)) > 3u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dqt_marker); goto exit; } v_q = ((uint8_t)(v_c8 & 15u)); if (((uint8_t)(v_c8 >> 4u)) == 1u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_precision); goto exit; } else if ((((uint8_t)(v_c8 >> 4u)) > 1u) || (self->private_impl.f_payload_length < 64u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dqt_marker); goto exit; } self->private_impl.f_payload_length -= 64u; v_i = 0u; while (v_i < 64u) { v_i += 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint16_t t_1 = *iop_a_src++; self->private_impl.f_quant_tables[v_q][WUFFS_JPEG__UNZIG[v_i]] = t_1; } } self->private_impl.f_seen_dqt[v_q] = true; if (self->private_impl.f_sof_marker == 0u) { v_i = 0u; while (v_i < 64u) { self->private_impl.f_saved_quant_tables[v_q][v_i] = self->private_impl.f_quant_tables[v_q][v_i]; v_i += 1u; } self->private_impl.f_saved_seen_dqt[v_q] = true; } } goto ok; ok: self->private_impl.p_decode_dqt = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_dqt = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_dqt.v_q = v_q; self->private_data.s_decode_dqt.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_dri WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dri( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_dri; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_payload_length != 2u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dri_marker); goto exit; } self->private_impl.f_payload_length = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint16_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = wuffs_base__peek_u16be__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_decode_dri.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_dri.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 8) { t_0 = ((uint16_t)(*scratch >> 48)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } self->private_impl.f_restart_interval = t_0; } if (self->private_impl.f_sof_marker == 0u) { self->private_impl.f_saved_restart_interval = self->private_impl.f_restart_interval; } goto ok; ok: self->private_impl.p_decode_dri = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_dri = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_appn WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_appn( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src, uint8_t a_marker) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_c32 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_appn; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; do { if (a_marker == 224u) { if (self->private_impl.f_payload_length >= 5u) { self->private_impl.f_payload_length -= 5u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_appn.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_appn.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c32 = t_0; } if (v_c32 != 1179207242u) { self->private_impl.f_payload_length = (65535u & (self->private_impl.f_payload_length + 1u)); break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } self->private_impl.f_is_jfif = (v_c8 == 0u); } } else if (a_marker == 238u) { if (self->private_impl.f_payload_length >= 12u) { self->private_impl.f_payload_length -= 12u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_appn.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_appn.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } v_c32 = t_2; } if (v_c32 != 1651467329u) { self->private_impl.f_payload_length = (65535u & (self->private_impl.f_payload_length + 8u)); break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_appn.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_appn.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } v_c32 = t_3; } if ((255u & v_c32) != 101u) { self->private_impl.f_payload_length = (65535u & (self->private_impl.f_payload_length + 4u)); break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_4 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_appn.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_appn.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 24) { t_4 = ((uint32_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } v_c32 = t_4; } if ((v_c32 >> 24u) == 0u) { self->private_impl.f_is_adobe = 1u; } else { self->private_impl.f_is_adobe = 2u; } } } } while (0); self->private_data.s_decode_appn.scratch = self->private_impl.f_payload_length; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (self->private_data.s_decode_appn.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_appn.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_appn.scratch; self->private_impl.f_payload_length = 0u; goto ok; ok: self->private_impl.p_decode_appn = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_appn = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_sof WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_sof( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_comp_h = 0; uint8_t v_comp_v = 0; uint32_t v_i = 0; uint32_t v_j = 0; bool v_has_h24 = false; bool v_has_h3 = false; bool v_has_v24 = false; bool v_has_v3 = false; uint32_t v_upper_bound = 0; uint64_t v_wh0 = 0; uint64_t v_wh1 = 0; uint64_t v_wh2 = 0; uint64_t v_wh3 = 0; uint64_t v_progressive = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_sof; if (coro_susp_point) { v_i = self->private_data.s_decode_sof.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_payload_length < 6u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } self->private_impl.f_payload_length -= 6u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 == 8u) { } else if (v_c8 == 12u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_precision_12_bits); goto exit; } else if (v_c8 == 16u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_precision_16_bits); goto exit; } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_precision); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_1 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_sof.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_sof.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 8) { t_1 = ((uint32_t)(*scratch >> 48)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } self->private_impl.f_height = t_1; } if (self->private_impl.f_height == 0u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_implicit_height); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_2 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_sof.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_sof.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 8) { t_2 = ((uint32_t)(*scratch >> 48)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } self->private_impl.f_width = t_2; } if (self->private_impl.f_width == 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if ((v_c8 == 0u) || (v_c8 > 4u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } else if (v_c8 == 2u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_color_model); goto exit; } self->private_impl.f_num_components = ((uint32_t)(v_c8)); if (self->private_impl.f_payload_length != (3u * self->private_impl.f_num_components)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } self->private_impl.f_payload_length = 0u; v_i = 0u; while (v_i < self->private_impl.f_num_components) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; self->private_impl.f_components_c[v_i] = t_4; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } v_comp_h = ((uint8_t)(v_c8 >> 4u)); v_comp_v = ((uint8_t)(v_c8 & 15u)); if ((v_comp_h == 0u) || (v_comp_h > 4u) || (v_comp_v == 0u) || (v_comp_v > 4u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } self->private_impl.f_components_h[v_i] = v_comp_h; if (self->private_impl.f_max_incl_components_h < self->private_impl.f_components_h[v_i]) { self->private_impl.f_max_incl_components_h = self->private_impl.f_components_h[v_i]; } self->private_impl.f_components_v[v_i] = v_comp_v; if (self->private_impl.f_max_incl_components_v < self->private_impl.f_components_v[v_i]) { self->private_impl.f_max_incl_components_v = self->private_impl.f_components_v[v_i]; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (v_c8 >= 4u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } self->private_impl.f_components_tq[v_i] = v_c8; v_j = 0u; while (v_j < v_i) { if (self->private_impl.f_components_c[v_j] == self->private_impl.f_components_c[v_i]) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } v_j += 1u; } v_i += 1u; } if (self->private_impl.f_num_components == 1u) { self->private_impl.f_max_incl_components_h = 1u; self->private_impl.f_max_incl_components_v = 1u; self->private_impl.f_components_h[0u] = 1u; self->private_impl.f_components_v[0u] = 1u; } else { v_has_h24 = false; v_has_h3 = false; v_has_v24 = false; v_has_v3 = false; v_i = 0u; while (v_i < self->private_impl.f_num_components) { v_has_h24 = (v_has_h24 || (self->private_impl.f_components_h[v_i] == 2u) || (self->private_impl.f_components_h[v_i] == 4u)); v_has_h3 = (v_has_h3 || (self->private_impl.f_components_h[v_i] == 3u)); v_has_v24 = (v_has_v24 || (self->private_impl.f_components_v[v_i] == 2u) || (self->private_impl.f_components_v[v_i] == 4u)); v_has_v3 = (v_has_v3 || (self->private_impl.f_components_v[v_i] == 3u)); v_i += 1u; } if ((v_has_h24 && v_has_h3) || (v_has_v24 && v_has_v3)) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_fractional_sampling); goto exit; } if (self->private_impl.f_num_components == 4u) { self->private_impl.f_is_rgb_or_cmyk = (self->private_impl.f_is_adobe < 2u); } else { if (self->private_impl.f_is_jfif) { self->private_impl.f_is_rgb_or_cmyk = false; } else if (self->private_impl.f_is_adobe > 0u) { self->private_impl.f_is_rgb_or_cmyk = (self->private_impl.f_is_adobe == 1u); } else { self->private_impl.f_is_rgb_or_cmyk = ((self->private_impl.f_components_c[0u] == 82u) && (self->private_impl.f_components_c[1u] == 71u) && (self->private_impl.f_components_c[2u] == 66u)); } } } self->private_impl.f_width_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_width, 1u, self->private_impl.f_max_incl_components_h); self->private_impl.f_height_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_height, 1u, self->private_impl.f_max_incl_components_v); v_upper_bound = 65544u; self->private_impl.f_components_workbuf_widths[0u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_width_in_mcus * ((uint32_t)(self->private_impl.f_components_h[0u])))); self->private_impl.f_components_workbuf_widths[1u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_width_in_mcus * ((uint32_t)(self->private_impl.f_components_h[1u])))); self->private_impl.f_components_workbuf_widths[2u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_width_in_mcus * ((uint32_t)(self->private_impl.f_components_h[2u])))); self->private_impl.f_components_workbuf_widths[3u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_width_in_mcus * ((uint32_t)(self->private_impl.f_components_h[3u])))); self->private_impl.f_components_workbuf_heights[0u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_height_in_mcus * ((uint32_t)(self->private_impl.f_components_v[0u])))); self->private_impl.f_components_workbuf_heights[1u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_height_in_mcus * ((uint32_t)(self->private_impl.f_components_v[1u])))); self->private_impl.f_components_workbuf_heights[2u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_height_in_mcus * ((uint32_t)(self->private_impl.f_components_v[2u])))); self->private_impl.f_components_workbuf_heights[3u] = wuffs_base__u32__min(v_upper_bound, (8u * self->private_impl.f_height_in_mcus * ((uint32_t)(self->private_impl.f_components_v[3u])))); v_wh0 = (((uint64_t)(self->private_impl.f_components_workbuf_widths[0u])) * ((uint64_t)(self->private_impl.f_components_workbuf_heights[0u]))); v_wh1 = (((uint64_t)(self->private_impl.f_components_workbuf_widths[1u])) * ((uint64_t)(self->private_impl.f_components_workbuf_heights[1u]))); v_wh2 = (((uint64_t)(self->private_impl.f_components_workbuf_widths[2u])) * ((uint64_t)(self->private_impl.f_components_workbuf_heights[2u]))); v_wh3 = (((uint64_t)(self->private_impl.f_components_workbuf_widths[3u])) * ((uint64_t)(self->private_impl.f_components_workbuf_heights[3u]))); v_progressive = 0u; if (self->private_impl.f_sof_marker >= 194u) { v_progressive = 2u; v_i = 0u; while (v_i < 4u) { v_j = 0u; while (v_j < 10u) { self->private_impl.f_block_smoothing_lowest_scan_al[v_i][v_j] = 16u; v_j += 1u; } v_i += 1u; } } self->private_impl.f_components_workbuf_offsets[0u] = 0u; self->private_impl.f_components_workbuf_offsets[1u] = (self->private_impl.f_components_workbuf_offsets[0u] + v_wh0); self->private_impl.f_components_workbuf_offsets[2u] = (self->private_impl.f_components_workbuf_offsets[1u] + v_wh1); self->private_impl.f_components_workbuf_offsets[3u] = (self->private_impl.f_components_workbuf_offsets[2u] + v_wh2); self->private_impl.f_components_workbuf_offsets[4u] = (self->private_impl.f_components_workbuf_offsets[3u] + v_wh3); self->private_impl.f_components_workbuf_offsets[5u] = (self->private_impl.f_components_workbuf_offsets[4u] + (v_wh0 * v_progressive)); self->private_impl.f_components_workbuf_offsets[6u] = (self->private_impl.f_components_workbuf_offsets[5u] + (v_wh1 * v_progressive)); self->private_impl.f_components_workbuf_offsets[7u] = (self->private_impl.f_components_workbuf_offsets[6u] + (v_wh2 * v_progressive)); self->private_impl.f_components_workbuf_offsets[8u] = (self->private_impl.f_components_workbuf_offsets[7u] + (v_wh3 * v_progressive)); goto ok; ok: self->private_impl.p_decode_sof = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_sof = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_sof.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.quantize_dimension WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__quantize_dimension( const wuffs_jpeg__decoder* self, uint32_t a_width, uint8_t a_h, uint8_t a_max_incl_h) { uint32_t v_ratio = 0; v_ratio = 0u; if (a_h > 0u) { v_ratio = ((uint32_t)(((uint8_t)(a_max_incl_h / a_h)))); } if (v_ratio == 1u) { return ((a_width + 7u) / 8u); } else if (v_ratio == 2u) { return ((a_width + 15u) / 16u); } else if (v_ratio == 3u) { return ((a_width + 23u) / 24u); } return ((a_width + 31u) / 32u); } // -------- func jpeg.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_frame_config( wuffs_jpeg__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_jpeg__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_jpeg__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func jpeg.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_frame_config( wuffs_jpeg__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_jpeg__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, true, false, 4278190080u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__decode_frame( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_ddf_status = wuffs_base__make_status(NULL); wuffs_base__status v_swizzle_status = wuffs_base__make_status(NULL); uint32_t v_scan_count = 0; uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { v_scan_count = self->private_impl.f_scan_count; { wuffs_base__status t_0 = wuffs_jpeg__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_ddf_status = t_0; } if ((v_ddf_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { v_ddf_status = wuffs_base__make_status(wuffs_jpeg__error__truncated_input); } if ( ! self->private_impl.f_swizzle_immediately && (wuffs_base__status__is_error(&v_ddf_status) || (v_scan_count < self->private_impl.f_scan_count))) { if (self->private_impl.f_sof_marker >= 194u) { wuffs_jpeg__decoder__apply_progressive_idct(self, a_workbuf); } if (self->private_impl.f_num_components == 1u) { v_swizzle_status = wuffs_jpeg__decoder__swizzle_gray(self, a_dst, a_workbuf, 0u, 4294967295u, 0u, 4294967295u, ((uint64_t)(self->private_impl.f_components_workbuf_widths[0u]))); } else { v_swizzle_status = wuffs_jpeg__decoder__swizzle_colorful(self, a_dst, a_workbuf, 0u, 4294967295u, 0u, 4294967295u); } if (wuffs_base__status__is_error(&v_ddf_status)) { status = v_ddf_status; goto exit; } else if (wuffs_base__status__is_error(&v_swizzle_status)) { status = v_swizzle_status; goto exit; } } status = v_ddf_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func jpeg.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__do_decode_frame( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_pixfmt = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_marker = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; if (coro_susp_point) { v_marker = self->private_data.s_do_decode_frame.v_marker; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_jpeg__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } v_pixfmt = 536870920u; if (self->private_impl.f_num_components > 1u) { v_pixfmt = 2415954056u; } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), wuffs_base__utility__make_pixel_format(v_pixfmt), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_swizzle_immediately = false; if (self->private_impl.f_components_workbuf_offsets[8u] > ((uint64_t)(a_workbuf.len))) { if (self->private_impl.f_sof_marker >= 194u) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } self->private_impl.f_swizzle_immediately = self->private_impl.f_use_lower_quality; self->private_impl.f_swizzle_immediately_status = wuffs_base__make_status(NULL); } else if (self->private_impl.f_components_workbuf_offsets[4u] < self->private_impl.f_components_workbuf_offsets[8u]) { wuffs_private_impl__bulk_memset(a_workbuf.ptr + self->private_impl.f_components_workbuf_offsets[4u], (self->private_impl.f_components_workbuf_offsets[8u] - self->private_impl.f_components_workbuf_offsets[4u]), 0u); } if (self->private_impl.f_components_workbuf_offsets[4u] <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_memset(a_workbuf.ptr, self->private_impl.f_components_workbuf_offsets[4u], 128u); } while (true) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 == 255u) { break; } } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_c8 != 255u) { v_marker = v_c8; break; } } if (v_marker == 0u) { continue; } else if ((208u <= v_marker) && (v_marker <= 217u)) { if (v_marker <= 215u) { continue; } } else { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_2 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_frame.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 8) { t_2 = ((uint32_t)(*scratch >> 48)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } self->private_impl.f_payload_length = t_2; } if (self->private_impl.f_payload_length < 2u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_marker); goto exit; } self->private_impl.f_payload_length -= 2u; } if (v_marker < 192u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } else if (v_marker < 208u) { if (v_marker == 196u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); status = wuffs_jpeg__decoder__decode_dht(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else if (v_marker == 200u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } status = wuffs_base__make_status(wuffs_jpeg__error__bad_sof_marker); goto exit; } else if (v_marker < 224u) { if (v_marker < 217u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_marker); goto exit; } else if (v_marker == 217u) { break; } else if (v_marker == 218u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); status = wuffs_jpeg__decoder__decode_sos(self, a_dst, a_src, a_workbuf); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else if (v_marker == 219u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_jpeg__decoder__decode_dqt(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else if (v_marker == 221u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_jpeg__decoder__decode_dri(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } continue; } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } } else if (v_marker < 240u) { } else { if (v_marker == 254u) { } else { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_marker); goto exit; } } self->private_data.s_do_decode_frame.scratch = self->private_impl.f_payload_length; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (self->private_data.s_do_decode_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame.scratch; self->private_impl.f_payload_length = 0u; } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_frame.v_marker = v_marker; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.decode_dht WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_dht( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_tc = 0; uint8_t v_th = 0; uint8_t v_tc4_th = 0; uint32_t v_working_total_count = 0; uint32_t v_total_count = 0; uint32_t v_i = 0; bool v_failed = false; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_dht; if (coro_susp_point) { v_tc4_th = self->private_data.s_decode_dht.v_tc4_th; v_total_count = self->private_data.s_decode_dht.v_total_count; v_i = self->private_data.s_decode_dht.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_sof_marker == 0u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } while (self->private_impl.f_payload_length > 0u) { if (self->private_impl.f_payload_length < 17u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } self->private_impl.f_payload_length -= 17u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if ((((uint8_t)(v_c8 >> 4u)) > 1u) || (((uint8_t)(v_c8 & 15u)) > 3u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } v_tc = ((uint8_t)(v_c8 >> 4u)); v_th = ((uint8_t)(v_c8 & 15u)); v_tc4_th = ((uint8_t)(((uint8_t)(((uint8_t)(v_tc * 4u)) | v_th)))); if ((self->private_impl.f_sof_marker == 192u) && (((uint8_t)(v_tc4_th & 3u)) > 1u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } v_i = 0u; while (v_i < 16u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; self->private_data.f_dht_temp_counts[v_i] = t_1; } v_i += 1u; } v_working_total_count = 0u; v_i = 0u; while (v_i < 16u) { v_working_total_count = ((v_working_total_count + ((uint32_t)(self->private_data.f_dht_temp_counts[v_i]))) & 65535u); v_i += 1u; } if ((v_working_total_count <= 0u) || (256u < v_working_total_count)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } v_total_count = v_working_total_count; if (self->private_impl.f_payload_length < v_total_count) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } self->private_impl.f_payload_length -= v_total_count; v_i = 0u; while (v_i < v_total_count) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; self->private_impl.f_huff_tables_symbols[v_tc4_th][v_i] = t_2; } v_i += 1u; } while (v_i < 256u) { self->private_impl.f_huff_tables_symbols[v_tc4_th][v_i] = 0u; v_i += 1u; } if (((uint8_t)(v_tc4_th & 4u)) == 0u) { v_i = 0u; while (v_i < v_total_count) { if (self->private_impl.f_huff_tables_symbols[v_tc4_th][v_i] > 15u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } v_i += 1u; } } v_failed = wuffs_jpeg__decoder__calculate_huff_tables(self, v_tc4_th, v_total_count); if (v_failed) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_dht_marker); goto exit; } self->private_impl.f_seen_dht[v_tc4_th] = true; } goto ok; ok: self->private_impl.p_decode_dht = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_dht = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_dht.v_tc4_th = v_tc4_th; self->private_data.s_decode_dht.v_total_count = v_total_count; self->private_data.s_decode_dht.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.calculate_huff_tables WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__calculate_huff_tables( wuffs_jpeg__decoder* self, uint8_t a_tc4_th, uint32_t a_total_count) { uint32_t v_i = 0; uint8_t v_j = 0; uint8_t v_k = 0; uint32_t v_bit_length_minus_one = 0; uint8_t v_bit_length = 0; uint32_t v_bit_string = 0; uint32_t v_slow = 0; uint8_t v_prefix = 0; uint16_t v_fast = 0; uint32_t v_reps = 0; v_i = 0u; v_k = 0u; v_bit_length_minus_one = 0u; while (v_i < a_total_count) { while (v_k >= self->private_data.f_dht_temp_counts[v_bit_length_minus_one]) { v_k = 0u; v_bit_length_minus_one = ((v_bit_length_minus_one + 1u) & 15u); } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_k += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_data.f_dht_temp_bit_lengths[v_i] = ((uint8_t)((v_bit_length_minus_one + 1u))); v_i += 1u; } v_bit_length = 0u; v_bit_string = 0u; v_i = 0u; while (v_i < a_total_count) { while (v_bit_length < self->private_data.f_dht_temp_bit_lengths[v_i]) { if (v_bit_length >= 16u) { return true; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_bit_length += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bit_string <<= 1u; } self->private_data.f_dht_temp_bit_strings[v_i] = ((uint16_t)(v_bit_string)); v_bit_string += 1u; if ((v_bit_string >> v_bit_length) > 0u) { return true; } v_i += 1u; } v_k = 0u; v_bit_length_minus_one = 0u; while (true) { if (self->private_data.f_dht_temp_counts[v_bit_length_minus_one] == 0u) { self->private_impl.f_huff_tables_slow[a_tc4_th][v_bit_length_minus_one] = 0u; } else { v_slow = (255u & ((uint32_t)(((uint32_t)(v_k)) - ((uint32_t)(self->private_data.f_dht_temp_bit_strings[v_k]))))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_k += self->private_data.f_dht_temp_counts[v_bit_length_minus_one]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_impl.f_huff_tables_slow[a_tc4_th][v_bit_length_minus_one] = (v_slow | ((((uint32_t)(self->private_data.f_dht_temp_bit_strings[((uint8_t)(v_k - 1u))])) + 1u) << 8u)); } v_bit_length_minus_one = ((v_bit_length_minus_one + 1u) & 15u); if (v_bit_length_minus_one == 0u) { break; } } v_i = 0u; while (v_i < 256u) { self->private_impl.f_huff_tables_fast[a_tc4_th][v_i] = 65535u; v_i += 1u; } v_j = 0u; v_bit_length_minus_one = 0u; while (v_bit_length_minus_one < 8u) { v_k = 0u; while (v_k < self->private_data.f_dht_temp_counts[v_bit_length_minus_one]) { v_prefix = ((uint8_t)((((uint32_t)(self->private_data.f_dht_temp_bit_strings[v_j])) << (7u - v_bit_length_minus_one)))); v_fast = ((uint16_t)(((((uint32_t)((v_bit_length_minus_one + 1u))) << 8u) | ((uint32_t)(self->private_impl.f_huff_tables_symbols[a_tc4_th][v_j]))))); v_reps = (((uint32_t)(1u)) << (7u - v_bit_length_minus_one)); while (v_reps > 0u) { self->private_impl.f_huff_tables_fast[a_tc4_th][v_prefix] = v_fast; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_prefix += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_reps -= 1u; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_k += 1u; v_j += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } v_bit_length_minus_one += 1u; } return false; } // -------- func jpeg.decoder.decode_sos WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__decode_sos( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_my = 0; uint32_t v_mx = 0; uint32_t v_decode_mcu_result = 0; uint32_t v_bitstream_length = 0; uint32_t coro_susp_point = self->private_impl.p_decode_sos; if (coro_susp_point) { v_my = self->private_data.s_decode_sos.v_my; v_mx = self->private_data.s_decode_sos.v_mx; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_scan_count >= 32u) { status = wuffs_base__make_status(wuffs_jpeg__error__unsupported_scan_count); goto exit; } else if ((self->private_impl.f_scan_count > 0u) && ! self->private_impl.f_expect_multiple_scans) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_scan_count); goto exit; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_jpeg__decoder__prepare_scan(self, a_src); if (status.repr) { goto suspend; } self->private_impl.f_next_restart_marker = 0u; self->private_impl.f_mcu_previous_dc_values[0u] = 0u; self->private_impl.f_mcu_previous_dc_values[1u] = 0u; self->private_impl.f_mcu_previous_dc_values[2u] = 0u; self->private_impl.f_mcu_previous_dc_values[3u] = 0u; self->private_impl.f_restarts_remaining = self->private_impl.f_restart_interval; self->private_impl.f_eob_run = 0u; self->private_impl.f_bitstream_bits = 0u; self->private_impl.f_bitstream_n_bits = 0u; self->private_impl.f_bitstream_ri = 0u; self->private_impl.f_bitstream_wi = 0u; self->private_impl.f_bitstream_padding = 12345u; wuffs_jpeg__decoder__fill_bitstream(self, a_src); v_my = 0u; while (v_my < self->private_impl.f_scan_height_in_mcus) { v_mx = 0u; while (v_mx < self->private_impl.f_scan_width_in_mcus) { self->private_impl.f_mcu_current_block = 0u; self->private_impl.f_mcu_zig_index = ((uint32_t)(self->private_impl.f_scan_ss)); if (self->private_impl.f_sof_marker >= 194u) { wuffs_jpeg__decoder__load_mcu_blocks(self, v_mx, v_my, a_workbuf); } while (true) { v_decode_mcu_result = wuffs_jpeg__decoder__decode_mcu(self, a_dst, a_workbuf, v_mx, v_my); if (v_decode_mcu_result == 0u) { break; } else if (v_decode_mcu_result == 1u) { } else if (v_decode_mcu_result == 2u) { status = wuffs_base__make_status(wuffs_jpeg__error__internal_error_inconsistent_decoder_state); goto exit; } else { status = self->private_impl.f_swizzle_immediately_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } while (true) { v_bitstream_length = ((uint32_t)(self->private_impl.f_bitstream_wi - self->private_impl.f_bitstream_ri)); wuffs_jpeg__decoder__fill_bitstream(self, a_src); if (v_bitstream_length < ((uint32_t)(self->private_impl.f_bitstream_wi - self->private_impl.f_bitstream_ri))) { break; } else if (self->private_impl.f_bitstream_padding == 0u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } else if ((a_src && a_src->meta.closed) && ! self->private_impl.f_bitstream_is_closed) { if (self->private_impl.f_bitstream_wi < 1024u) { wuffs_private_impl__bulk_memset(&self->private_data.f_bitstream_buffer[self->private_impl.f_bitstream_wi], 264u, 0u); self->private_impl.f_bitstream_wi += 264u; self->private_impl.f_bitstream_is_closed = true; } break; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } } if (self->private_impl.f_sof_marker >= 194u) { wuffs_jpeg__decoder__save_mcu_blocks(self, v_mx, v_my, a_workbuf); } if (self->private_impl.f_restarts_remaining > 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_restarts_remaining -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif if (self->private_impl.f_restarts_remaining == 0u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_jpeg__decoder__skip_past_the_next_restart_marker(self, a_src); if (status.repr) { goto suspend; } self->private_impl.f_mcu_previous_dc_values[0u] = 0u; self->private_impl.f_mcu_previous_dc_values[1u] = 0u; self->private_impl.f_mcu_previous_dc_values[2u] = 0u; self->private_impl.f_mcu_previous_dc_values[3u] = 0u; self->private_impl.f_restarts_remaining = self->private_impl.f_restart_interval; self->private_impl.f_eob_run = 0u; self->private_impl.f_bitstream_bits = 0u; self->private_impl.f_bitstream_n_bits = 0u; self->private_impl.f_bitstream_ri = 0u; self->private_impl.f_bitstream_wi = 0u; self->private_impl.f_bitstream_padding = 12345u; } } v_mx += 1u; } v_my += 1u; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_scan_count, 1u); ok: self->private_impl.p_decode_sos = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_sos = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_sos.v_my = v_my; self->private_data.s_decode_sos.v_mx = v_mx; goto exit; exit: return status; } // -------- func jpeg.decoder.prepare_scan WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__prepare_scan( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_i = 0; uint32_t v_j = 0; uint32_t v_j_max_incl = 0; bool v_failed = false; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_prepare_scan; if (coro_susp_point) { v_i = self->private_data.s_prepare_scan.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_payload_length < 6u) || (self->private_impl.f_payload_length > 12u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if ((v_c8 < 1u) || (v_c8 > 4u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_scan_num_components = ((uint32_t)(v_c8)); if ((self->private_impl.f_scan_num_components > self->private_impl.f_num_components) || (self->private_impl.f_payload_length != (4u + (2u * self->private_impl.f_scan_num_components)))) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_payload_length = 0u; v_i = 0u; while (v_i < self->private_impl.f_scan_num_components) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } v_j = 0u; while (true) { if (v_j >= self->private_impl.f_num_components) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } if (v_c8 == self->private_impl.f_components_c[v_j]) { if ( ! self->private_impl.f_seen_dqt[self->private_impl.f_components_tq[v_j]]) { status = wuffs_base__make_status(wuffs_jpeg__error__missing_quantization_table); goto exit; } self->private_impl.f_scan_comps_cselector[v_i] = ((uint8_t)(v_j)); break; } v_j += 1u; } v_j = 0u; while (v_j < v_i) { if (self->private_impl.f_scan_comps_cselector[v_i] == self->private_impl.f_scan_comps_cselector[v_j]) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } v_j += 1u; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if ((((uint8_t)(v_c8 >> 4u)) > 3u) || (((uint8_t)(v_c8 & 15u)) > 3u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_scan_comps_td[v_i] = ((uint8_t)(v_c8 >> 4u)); self->private_impl.f_scan_comps_ta[v_i] = ((uint8_t)(v_c8 & 15u)); if (self->private_impl.f_sof_marker == 192u) { if ((self->private_impl.f_scan_comps_td[v_i] > 1u) || (self->private_impl.f_scan_comps_ta[v_i] > 1u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } } v_i += 1u; } if (self->private_impl.f_scan_count == 0u) { self->private_impl.f_expect_multiple_scans = ((self->private_impl.f_sof_marker >= 194u) || (self->private_impl.f_scan_num_components < self->private_impl.f_num_components)); } if (self->private_impl.f_sof_marker < 194u) { self->private_data.s_prepare_scan.scratch = 3u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (self->private_data.s_prepare_scan.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_prepare_scan.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_prepare_scan.scratch; self->private_impl.f_scan_ss = 0u; self->private_impl.f_scan_se = 63u; self->private_impl.f_scan_ah = 0u; self->private_impl.f_scan_al = 0u; } else { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (v_c8 > 63u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_scan_ss = v_c8; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if ((v_c8 > 63u) || (v_c8 < self->private_impl.f_scan_ss)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_scan_se = v_c8; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } if ((((uint8_t)(v_c8 >> 4u)) > 14u) || (((uint8_t)(v_c8 & 15u)) > 13u)) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } self->private_impl.f_scan_ah = ((uint8_t)(v_c8 >> 4u)); self->private_impl.f_scan_al = ((uint8_t)(v_c8 & 15u)); if (self->private_impl.f_scan_ah > 0u) { if (((uint8_t)(self->private_impl.f_scan_ah - 1u)) != self->private_impl.f_scan_al) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } } if (self->private_impl.f_scan_ss == 0u) { if (self->private_impl.f_scan_se != 0u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } else if (self->private_impl.f_scan_ah == 0u) { self->private_impl.choosy_decode_mcu = ( &wuffs_jpeg__decoder__decode_mcu_progressive_dc_high_bits); } else { self->private_impl.choosy_decode_mcu = ( &wuffs_jpeg__decoder__decode_mcu_progressive_dc_low_bit); } } else { if (self->private_impl.f_scan_num_components != 1u) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } else if (self->private_impl.f_scan_ah == 0u) { self->private_impl.choosy_decode_mcu = ( &wuffs_jpeg__decoder__decode_mcu_progressive_ac_high_bits); } else { self->private_impl.choosy_decode_mcu = ( &wuffs_jpeg__decoder__decode_mcu_progressive_ac_low_bit); } } } v_i = 0u; while (v_i < self->private_impl.f_scan_num_components) { if ((self->private_impl.f_scan_ss == 0u) && ! self->private_impl.f_seen_dht[((uint8_t)(0u | self->private_impl.f_scan_comps_td[v_i]))]) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_jpeg__decoder__use_default_huffman_table(self, ((uint8_t)(0u | self->private_impl.f_scan_comps_td[v_i]))); if (status.repr) { goto suspend; } } if ((self->private_impl.f_scan_se != 0u) && ! self->private_impl.f_seen_dht[((uint8_t)(4u | self->private_impl.f_scan_comps_ta[v_i]))]) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_jpeg__decoder__use_default_huffman_table(self, ((uint8_t)(4u | self->private_impl.f_scan_comps_ta[v_i]))); if (status.repr) { goto suspend; } } v_j = ((uint32_t)(self->private_impl.f_scan_ss)); v_j_max_incl = ((uint32_t)(wuffs_base__u8__min(self->private_impl.f_scan_se, 9u))); while (v_j <= v_j_max_incl) { self->private_impl.f_block_smoothing_lowest_scan_al[self->private_impl.f_scan_comps_cselector[v_i]][v_j] = self->private_impl.f_scan_al; v_j += 1u; } v_i += 1u; } if (self->private_impl.f_scan_num_components == 1u) { wuffs_jpeg__decoder__calculate_single_component_scan_fields(self); } else { v_failed = wuffs_jpeg__decoder__calculate_multiple_component_scan_fields(self); if (v_failed) { status = wuffs_base__make_status(wuffs_jpeg__error__bad_sos_marker); goto exit; } } goto ok; ok: self->private_impl.p_prepare_scan = 0; goto exit; } goto suspend; suspend: self->private_impl.p_prepare_scan = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_prepare_scan.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.use_default_huffman_table WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__use_default_huffman_table( wuffs_jpeg__decoder* self, uint8_t a_tc4_th) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__slice_u8 v_data = {0}; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__status v_status = wuffs_base__make_status(NULL); if (a_tc4_th == 0u) { v_data = wuffs_base__make_slice_u8(wuffs_base__strip_const_from_u8_ptr(WUFFS_JPEG__DEFAULT_HUFF_TABLE_DC_LUMA), 29); } else if (a_tc4_th == 1u) { v_data = wuffs_base__make_slice_u8(wuffs_base__strip_const_from_u8_ptr(WUFFS_JPEG__DEFAULT_HUFF_TABLE_DC_CHROMA), 29); } else if (a_tc4_th == 4u) { v_data = wuffs_base__make_slice_u8(wuffs_base__strip_const_from_u8_ptr(WUFFS_JPEG__DEFAULT_HUFF_TABLE_AC_LUMA), 179); } else if (a_tc4_th == 5u) { v_data = wuffs_base__make_slice_u8(wuffs_base__strip_const_from_u8_ptr(WUFFS_JPEG__DEFAULT_HUFF_TABLE_AC_CHROMA), 179); } else { status = wuffs_base__make_status(wuffs_jpeg__error__missing_huffman_table); goto exit; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, v_data, 0u); self->private_impl.f_payload_length = ((uint32_t)((((uint64_t)(v_data.len)) & 65535u))); { wuffs_base__status t_0 = wuffs_jpeg__decoder__decode_dht(self, v_r); v_status = t_0; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; ok: goto exit; exit: return status; } // -------- func jpeg.decoder.calculate_single_component_scan_fields WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__calculate_single_component_scan_fields( wuffs_jpeg__decoder* self) { uint8_t v_csel = 0; self->private_impl.f_scan_comps_bx_offset[0u] = 0u; self->private_impl.f_scan_comps_by_offset[0u] = 0u; self->private_impl.f_mcu_num_blocks = 1u; self->private_impl.f_mcu_blocks_sselector[0u] = 0u; v_csel = self->private_impl.f_scan_comps_cselector[0u]; self->private_impl.f_mcu_blocks_offset[0u] = self->private_impl.f_components_workbuf_offsets[v_csel]; self->private_impl.f_mcu_blocks_mx_mul[0u] = 8u; self->private_impl.f_mcu_blocks_my_mul[0u] = (8u * self->private_impl.f_components_workbuf_widths[v_csel]); self->private_impl.f_mcu_blocks_dc_hselector[0u] = ((uint8_t)(0u | self->private_impl.f_scan_comps_td[0u])); self->private_impl.f_mcu_blocks_ac_hselector[0u] = ((uint8_t)(4u | self->private_impl.f_scan_comps_ta[0u])); self->private_impl.f_scan_width_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_width, self->private_impl.f_components_h[v_csel], self->private_impl.f_max_incl_components_h); self->private_impl.f_scan_height_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_height, self->private_impl.f_components_v[v_csel], self->private_impl.f_max_incl_components_v); return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.calculate_multiple_component_scan_fields WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__calculate_multiple_component_scan_fields( wuffs_jpeg__decoder* self) { uint32_t v_i = 0; uint32_t v_h = 0; uint32_t v_v = 0; uint32_t v_hv = 0; uint32_t v_total_hv = 0; uint32_t v_b = 0; uint32_t v_bx_offset = 0; uint32_t v_by_offset = 0; uint32_t v_sibo = 0; uint8_t v_ssel = 0; uint8_t v_csel = 0; v_total_hv = 0u; v_i = 0u; v_b = 0u; v_bx_offset = 0u; v_by_offset = 0u; while (v_i < self->private_impl.f_scan_num_components) { v_h = ((uint32_t)(self->private_impl.f_components_h[self->private_impl.f_scan_comps_cselector[v_i]])); v_v = ((uint32_t)(self->private_impl.f_components_v[self->private_impl.f_scan_comps_cselector[v_i]])); v_hv = (((uint32_t)(self->private_impl.f_components_h[self->private_impl.f_scan_comps_cselector[v_i]])) * ((uint32_t)(self->private_impl.f_components_v[self->private_impl.f_scan_comps_cselector[v_i]]))); self->private_impl.f_swizzle_immediately_c_offsets[v_i] = ((uint32_t)(64u * v_total_hv)); v_total_hv += v_hv; while (v_hv > 0u) { self->private_impl.f_scan_comps_bx_offset[(v_b & 15u)] = ((uint8_t)((v_bx_offset & 3u))); self->private_impl.f_scan_comps_by_offset[(v_b & 15u)] = ((uint8_t)((v_by_offset & 3u))); self->private_impl.f_mcu_blocks_sselector[(v_b & 15u)] = ((uint8_t)(v_i)); v_b += 1u; v_bx_offset += 1u; if (v_bx_offset == v_h) { v_bx_offset = 0u; v_by_offset += 1u; if (v_by_offset == v_v) { v_by_offset = 0u; } } v_hv -= 1u; } v_i += 1u; } if (v_total_hv > 10u) { return true; } self->private_impl.f_mcu_num_blocks = v_total_hv; self->private_impl.f_swizzle_immediately_c_offsets[self->private_impl.f_scan_num_components] = ((uint32_t)(64u * v_total_hv)); v_b = 0u; while (v_b < self->private_impl.f_mcu_num_blocks) { v_ssel = self->private_impl.f_mcu_blocks_sselector[v_b]; v_csel = self->private_impl.f_scan_comps_cselector[v_ssel]; self->private_impl.f_mcu_blocks_offset[v_b] = (self->private_impl.f_components_workbuf_offsets[v_csel] + (8u * ((uint64_t)(self->private_impl.f_scan_comps_bx_offset[v_b]))) + (8u * ((uint64_t)(self->private_impl.f_scan_comps_by_offset[v_b])) * ((uint64_t)(self->private_impl.f_components_workbuf_widths[v_csel])))); self->private_impl.f_mcu_blocks_mx_mul[v_b] = (8u * ((uint32_t)(self->private_impl.f_components_h[v_csel]))); self->private_impl.f_mcu_blocks_my_mul[v_b] = (8u * ((uint32_t)(self->private_impl.f_components_v[v_csel])) * self->private_impl.f_components_workbuf_widths[v_csel]); self->private_impl.f_mcu_blocks_dc_hselector[v_b] = ((uint8_t)(0u | self->private_impl.f_scan_comps_td[v_ssel])); self->private_impl.f_mcu_blocks_ac_hselector[v_b] = ((uint8_t)(4u | self->private_impl.f_scan_comps_ta[v_ssel])); v_sibo = ((uint32_t)(self->private_impl.f_swizzle_immediately_c_offsets[v_csel] + ((8u * ((uint32_t)(self->private_impl.f_scan_comps_bx_offset[v_b]))) + (64u * ((uint32_t)(self->private_impl.f_scan_comps_by_offset[v_b])) * ((uint32_t)(self->private_impl.f_components_h[v_csel])))))); self->private_impl.f_swizzle_immediately_b_offsets[v_b] = wuffs_base__u32__min(v_sibo, 576u); v_b += 1u; } self->private_impl.f_scan_width_in_mcus = self->private_impl.f_width_in_mcus; self->private_impl.f_scan_height_in_mcus = self->private_impl.f_height_in_mcus; return false; } // -------- func jpeg.decoder.fill_bitstream WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__fill_bitstream( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { uint32_t v_wi = 0; uint8_t v_c8 = 0; uint32_t v_new_wi = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } if (self->private_impl.f_bitstream_ri <= 0u) { } else if (self->private_impl.f_bitstream_ri >= self->private_impl.f_bitstream_wi) { self->private_impl.f_bitstream_ri = 0u; self->private_impl.f_bitstream_wi = 0u; } else { v_wi = (self->private_impl.f_bitstream_wi - self->private_impl.f_bitstream_ri); wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__make_slice_u8(self->private_data.f_bitstream_buffer, 2048), wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi)); self->private_impl.f_bitstream_ri = 0u; self->private_impl.f_bitstream_wi = v_wi; } v_wi = self->private_impl.f_bitstream_wi; while ((v_wi < 2048u) && (((uint64_t)(io2_a_src - iop_a_src)) > 0u)) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (v_c8 < 255u) { self->private_data.f_bitstream_buffer[v_wi] = v_c8; v_wi += 1u; iop_a_src += 1u; continue; } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 1u) { break; } else if (((uint16_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src) >> 8u)) > 0u) { break; } else { self->private_data.f_bitstream_buffer[v_wi] = 255u; v_wi += 1u; iop_a_src += 2u; } } if (((uint64_t)(io2_a_src - iop_a_src)) > 1u) { if ((wuffs_base__peek_u8be__no_bounds_check(iop_a_src) >= 255u) && (((uint16_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src) >> 8u)) > 0u)) { v_new_wi = (wuffs_base__u32__min(v_wi, 1784u) + 264u); v_new_wi = wuffs_base__u32__min(v_new_wi, (v_wi + self->private_impl.f_bitstream_padding)); if (v_wi < v_new_wi) { wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_bitstream_padding, (v_new_wi - v_wi)); wuffs_private_impl__bulk_memset(&self->private_data.f_bitstream_buffer[v_wi], (v_new_wi - v_wi), 0u); v_wi = v_new_wi; } } } self->private_impl.f_bitstream_wi = v_wi; if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.load_mcu_blocks_for_single_component WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel) { return (*self->private_impl.choosy_load_mcu_blocks_for_single_component)(self, a_mx, a_my, a_workbuf, a_csel); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component__choosy_default( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel) { uint64_t v_stride16 = 0; uint64_t v_offset = 0; v_stride16 = ((uint64_t)((self->private_impl.f_components_workbuf_widths[a_csel] * 16u))); v_offset = (self->private_impl.f_components_workbuf_offsets[(a_csel | 4u)] + (((uint64_t)(a_mx)) * 128u) + (((uint64_t)(a_my)) * v_stride16)); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_load_host_endian(&self->private_data.f_mcu_blocks[0], 1u * (size_t)128u, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset)); } return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.load_mcu_blocks WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf) { uint32_t v_b = 0; uint8_t v_csel = 0; uint64_t v_h = 0; uint64_t v_v = 0; uint64_t v_stride16 = 0; uint64_t v_offset = 0; v_h = 1u; v_v = 1u; v_b = 0u; while (v_b < self->private_impl.f_mcu_num_blocks) { v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[v_b]]; if (self->private_impl.f_scan_num_components > 1u) { v_h = ((uint64_t)(self->private_impl.f_components_h[v_csel])); v_v = ((uint64_t)(self->private_impl.f_components_v[v_csel])); } v_stride16 = ((uint64_t)((self->private_impl.f_components_workbuf_widths[v_csel] * 16u))); v_offset = (self->private_impl.f_components_workbuf_offsets[((uint8_t)(v_csel | 4u))] + (((v_h * ((uint64_t)(a_mx))) + ((uint64_t)(self->private_impl.f_scan_comps_bx_offset[v_b]))) * 128u) + (((v_v * ((uint64_t)(a_my))) + ((uint64_t)(self->private_impl.f_scan_comps_by_offset[v_b]))) * v_stride16)); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_load_host_endian(&self->private_data.f_mcu_blocks[v_b], 1u * (size_t)128u, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset)); } v_b += 1u; } return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.save_mcu_blocks WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__save_mcu_blocks( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf) { uint32_t v_b = 0; uint8_t v_csel = 0; uint64_t v_h = 0; uint64_t v_v = 0; uint64_t v_stride16 = 0; uint64_t v_offset = 0; v_h = 1u; v_v = 1u; v_b = 0u; while (v_b < self->private_impl.f_mcu_num_blocks) { v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[v_b]]; if (self->private_impl.f_scan_num_components > 1u) { v_h = ((uint64_t)(self->private_impl.f_components_h[v_csel])); v_v = ((uint64_t)(self->private_impl.f_components_v[v_csel])); } v_stride16 = ((uint64_t)((self->private_impl.f_components_workbuf_widths[v_csel] * 16u))); v_offset = (self->private_impl.f_components_workbuf_offsets[((uint8_t)(v_csel | 4u))] + (((v_h * ((uint64_t)(a_mx))) + ((uint64_t)(self->private_impl.f_scan_comps_bx_offset[v_b]))) * 128u) + (((v_v * ((uint64_t)(a_my))) + ((uint64_t)(self->private_impl.f_scan_comps_by_offset[v_b]))) * v_stride16)); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_save_host_endian(&self->private_data.f_mcu_blocks[v_b], 1u * (size_t)128u, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset)); } v_b += 1u; } return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.skip_past_the_next_restart_marker WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__skip_past_the_next_restart_marker( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_skip_past_the_next_restart_marker; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } else if (wuffs_base__peek_u8be__no_bounds_check(iop_a_src) < 255u) { iop_a_src += 1u; continue; } v_c8 = ((uint8_t)(((uint16_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src) >> 8u)))); if (v_c8 < 192u) { iop_a_src += 2u; continue; } else if ((v_c8 < 208u) || (215u < v_c8)) { break; } v_c8 &= 7u; if ((self->private_impl.f_next_restart_marker == ((uint8_t)(((uint8_t)(v_c8 + 1u)) & 7u))) || (self->private_impl.f_next_restart_marker == ((uint8_t)(((uint8_t)(v_c8 + 2u)) & 7u)))) { break; } else if ((self->private_impl.f_next_restart_marker == ((uint8_t)(((uint8_t)(v_c8 + 7u)) & 7u))) || (self->private_impl.f_next_restart_marker == ((uint8_t)(((uint8_t)(v_c8 + 6u)) & 7u)))) { iop_a_src += 2u; continue; } else { iop_a_src += 2u; break; } } self->private_impl.f_next_restart_marker = ((uint8_t)(((uint8_t)(self->private_impl.f_next_restart_marker + 1u)) & 7u)); ok: self->private_impl.p_skip_past_the_next_restart_marker = 0; goto exit; } goto suspend; suspend: self->private_impl.p_skip_past_the_next_restart_marker = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func jpeg.decoder.apply_progressive_idct WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__apply_progressive_idct( wuffs_jpeg__decoder* self, wuffs_base__slice_u8 a_workbuf) { uint32_t v_csel = 0; bool v_block_smoothing_applicable = false; uint32_t v_scan_width_in_mcus = 0; uint32_t v_scan_height_in_mcus = 0; uint32_t v_mcu_blocks_mx_mul_0 = 0; uint32_t v_mcu_blocks_my_mul_0 = 0; uint32_t v_my = 0; uint32_t v_mx = 0; uint64_t v_stride = 0; uint64_t v_offset = 0; uint8_t v_stashed_mcu_blocks_0[128] = {0}; wuffs_private_impl__bulk_save_host_endian(&self->private_data.f_mcu_blocks[0], 1u * (size_t)128u, wuffs_base__make_slice_u8(v_stashed_mcu_blocks_0, 128)); v_block_smoothing_applicable = true; v_csel = 0u; while (v_csel < self->private_impl.f_num_components) { if ((self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][0u] >= 16u) || wuffs_jpeg__decoder__top_left_quants_has_zero(self, ((uint32_t)(self->private_impl.f_components_tq[v_csel])))) { v_block_smoothing_applicable = false; } v_csel += 1u; } v_csel = 0u; while (v_csel < self->private_impl.f_num_components) { v_scan_width_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_width, self->private_impl.f_components_h[v_csel], self->private_impl.f_max_incl_components_h); v_scan_height_in_mcus = wuffs_jpeg__decoder__quantize_dimension(self, self->private_impl.f_height, self->private_impl.f_components_v[v_csel], self->private_impl.f_max_incl_components_v); v_mcu_blocks_mx_mul_0 = 8u; v_mcu_blocks_my_mul_0 = (8u * self->private_impl.f_components_workbuf_widths[v_csel]); if (v_block_smoothing_applicable && (0u != (self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][1u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][2u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][3u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][4u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][5u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][6u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][8u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][8u] | self->private_impl.f_block_smoothing_lowest_scan_al[v_csel][9u]))) { self->private_impl.choosy_load_mcu_blocks_for_single_component = ( &wuffs_jpeg__decoder__load_mcu_blocks_for_single_component_smooth); self->private_impl.f_block_smoothing_mx_max_incl = wuffs_base__u32__sat_sub(v_scan_width_in_mcus, 1u); self->private_impl.f_block_smoothing_my_max_incl = wuffs_base__u32__sat_sub(v_scan_height_in_mcus, 1u); } else { self->private_impl.choosy_load_mcu_blocks_for_single_component = ( &wuffs_jpeg__decoder__load_mcu_blocks_for_single_component__choosy_default); } v_my = 0u; while (v_my < v_scan_height_in_mcus) { v_mx = 0u; while (v_mx < v_scan_width_in_mcus) { wuffs_jpeg__decoder__load_mcu_blocks_for_single_component(self, v_mx, v_my, a_workbuf, v_csel); v_stride = ((uint64_t)(self->private_impl.f_components_workbuf_widths[v_csel])); v_offset = (self->private_impl.f_components_workbuf_offsets[v_csel] + (((uint64_t)(v_mcu_blocks_mx_mul_0)) * ((uint64_t)(v_mx))) + (((uint64_t)(v_mcu_blocks_my_mul_0)) * ((uint64_t)(v_my)))); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_jpeg__decoder__decode_idct(self, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset), v_stride, ((uint32_t)(self->private_impl.f_components_tq[v_csel]))); } v_mx += 1u; } v_my += 1u; } v_csel += 1u; } wuffs_private_impl__bulk_load_host_endian(&self->private_data.f_mcu_blocks[0], 1u * (size_t)128u, wuffs_base__make_slice_u8(v_stashed_mcu_blocks_0, 128)); return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.swizzle_gray WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__swizzle_gray( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_x0, uint32_t a_x1, uint32_t a_y0, uint32_t a_y1, uint64_t a_stride) { wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_x0 = 0; uint64_t v_x1 = 0; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint32_t v_y = 0; uint32_t v_y1 = 0; v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_x0 = ((uint64_t)((v_dst_bytes_per_pixel * wuffs_base__u32__min(a_x0, self->private_impl.f_width)))); v_x1 = ((uint64_t)((v_dst_bytes_per_pixel * wuffs_base__u32__min(a_x1, self->private_impl.f_width)))); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_y = a_y0; v_y1 = wuffs_base__u32__min(a_y1, self->private_impl.f_height); while (v_y < v_y1) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_y); if (v_x1 < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_x1); } if (v_x0 < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_x0); } else { v_dst = wuffs_base__utility__empty_slice_u8(); } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), a_workbuf); if (a_stride <= ((uint64_t)(a_workbuf.len))) { a_workbuf = wuffs_base__slice_u8__subslice_i(a_workbuf, a_stride); } else { a_workbuf = wuffs_base__utility__empty_slice_u8(); } v_y += 1u; } return wuffs_base__make_status(NULL); } // -------- func jpeg.decoder.swizzle_colorful WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_jpeg__decoder__swizzle_colorful( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_x0, uint32_t a_x1, uint32_t a_y0, uint32_t a_y1) { uint64_t v_i = 0; uint64_t v_j = 0; wuffs_base__slice_u8 v_src0 = {0}; wuffs_base__slice_u8 v_src1 = {0}; wuffs_base__slice_u8 v_src2 = {0}; wuffs_base__slice_u8 v_src3 = {0}; uint32_t v_width0 = 0; uint32_t v_width1 = 0; uint32_t v_width2 = 0; uint32_t v_width3 = 0; uint32_t v_height0 = 0; uint32_t v_height1 = 0; uint32_t v_height2 = 0; uint32_t v_height3 = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); if (self->private_impl.f_swizzle_immediately) { v_i = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[0u])); v_j = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[1u])); if ((v_i <= v_j) && (v_j <= 640u)) { v_src0 = wuffs_base__make_slice_u8_ij(self->private_data.f_swizzle_immediately_buffer, v_i, v_j); v_width0 = (8u * ((uint32_t)(self->private_impl.f_components_h[0u]))); v_height0 = (8u * ((uint32_t)(self->private_impl.f_components_v[0u]))); } v_i = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[1u])); v_j = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[2u])); if ((v_i <= v_j) && (v_j <= 640u)) { v_src1 = wuffs_base__make_slice_u8_ij(self->private_data.f_swizzle_immediately_buffer, v_i, v_j); v_width1 = (8u * ((uint32_t)(self->private_impl.f_components_h[1u]))); v_height1 = (8u * ((uint32_t)(self->private_impl.f_components_v[1u]))); } v_i = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[2u])); v_j = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[3u])); if ((v_i <= v_j) && (v_j <= 640u)) { v_src2 = wuffs_base__make_slice_u8_ij(self->private_data.f_swizzle_immediately_buffer, v_i, v_j); v_width2 = (8u * ((uint32_t)(self->private_impl.f_components_h[2u]))); v_height2 = (8u * ((uint32_t)(self->private_impl.f_components_v[2u]))); } v_i = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[3u])); v_j = ((uint64_t)(self->private_impl.f_swizzle_immediately_c_offsets[4u])); if ((v_i <= v_j) && (v_j <= 640u)) { v_src3 = wuffs_base__make_slice_u8_ij(self->private_data.f_swizzle_immediately_buffer, v_i, v_j); v_width3 = (8u * ((uint32_t)(self->private_impl.f_components_h[3u]))); v_height3 = (8u * ((uint32_t)(self->private_impl.f_components_v[3u]))); } } else { if ((self->private_impl.f_components_workbuf_offsets[0u] <= self->private_impl.f_components_workbuf_offsets[1u]) && (self->private_impl.f_components_workbuf_offsets[1u] <= ((uint64_t)(a_workbuf.len)))) { v_src0 = wuffs_base__slice_u8__subslice_ij(a_workbuf, self->private_impl.f_components_workbuf_offsets[0u], self->private_impl.f_components_workbuf_offsets[1u]); v_width0 = self->private_impl.f_components_workbuf_widths[0u]; v_height0 = self->private_impl.f_components_workbuf_heights[0u]; } if ((self->private_impl.f_components_workbuf_offsets[1u] <= self->private_impl.f_components_workbuf_offsets[2u]) && (self->private_impl.f_components_workbuf_offsets[2u] <= ((uint64_t)(a_workbuf.len)))) { v_src1 = wuffs_base__slice_u8__subslice_ij(a_workbuf, self->private_impl.f_components_workbuf_offsets[1u], self->private_impl.f_components_workbuf_offsets[2u]); v_width1 = self->private_impl.f_components_workbuf_widths[1u]; v_height1 = self->private_impl.f_components_workbuf_heights[1u]; } if ((self->private_impl.f_components_workbuf_offsets[2u] <= self->private_impl.f_components_workbuf_offsets[3u]) && (self->private_impl.f_components_workbuf_offsets[3u] <= ((uint64_t)(a_workbuf.len)))) { v_src2 = wuffs_base__slice_u8__subslice_ij(a_workbuf, self->private_impl.f_components_workbuf_offsets[2u], self->private_impl.f_components_workbuf_offsets[3u]); v_width2 = self->private_impl.f_components_workbuf_widths[2u]; v_height2 = self->private_impl.f_components_workbuf_heights[2u]; } if ((self->private_impl.f_components_workbuf_offsets[3u] <= self->private_impl.f_components_workbuf_offsets[4u]) && (self->private_impl.f_components_workbuf_offsets[4u] <= ((uint64_t)(a_workbuf.len)))) { v_src3 = wuffs_base__slice_u8__subslice_ij(a_workbuf, self->private_impl.f_components_workbuf_offsets[3u], self->private_impl.f_components_workbuf_offsets[4u]); v_width3 = self->private_impl.f_components_workbuf_widths[3u]; v_height3 = self->private_impl.f_components_workbuf_heights[3u]; } } v_status = wuffs_base__pixel_swizzler__swizzle_ycck(&self->private_impl.f_swizzler, a_dst, wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), (a_x0 & 65535u), wuffs_base__u32__min(a_x1, self->private_impl.f_width), (a_y0 & 65535u), wuffs_base__u32__min(a_y1, self->private_impl.f_height), v_src0, v_src1, v_src2, v_src3, v_width0, v_width1, v_width2, v_width3, v_height0, v_height1, v_height2, v_height3, v_width0, v_width1, v_width2, v_width3, self->private_impl.f_components_h[0u], self->private_impl.f_components_h[1u], self->private_impl.f_components_h[2u], self->private_impl.f_components_h[3u], self->private_impl.f_components_v[0u], self->private_impl.f_components_v[1u], self->private_impl.f_components_v[2u], self->private_impl.f_components_v[3u], self->private_impl.f_is_rgb_or_cmyk, ! self->private_impl.f_use_lower_quality, wuffs_base__make_slice_u8(self->private_data.f_swizzle_ycck_scratch_buffer_2k, 2048)); return wuffs_private_impl__status__ensure_not_a_suspension(v_status); } // -------- func jpeg.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_jpeg__decoder__frame_dirty_rect( const wuffs_jpeg__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func jpeg.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_jpeg__decoder__num_animation_loops( const wuffs_jpeg__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func jpeg.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__num_decoded_frame_configs( const wuffs_jpeg__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func jpeg.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_jpeg__decoder__num_decoded_frames( const wuffs_jpeg__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func jpeg.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__restart_frame( wuffs_jpeg__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } uint32_t v_i = 0; uint32_t v_j = 0; if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if (a_index != 0u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; self->private_impl.f_bitstream_is_closed = false; self->private_impl.f_expect_multiple_scans = false; self->private_impl.f_frame_config_io_position = a_io_position; self->private_impl.f_scan_count = 0u; self->private_impl.f_restart_interval = self->private_impl.f_saved_restart_interval; v_i = 0u; while (v_i < 4u) { self->private_impl.f_seen_dqt[v_i] = self->private_impl.f_saved_seen_dqt[v_i]; v_j = 0u; while (v_j < 64u) { self->private_impl.f_quant_tables[v_i][v_j] = self->private_impl.f_saved_quant_tables[v_i][v_j]; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 4u) { v_j = 0u; while (v_j < 10u) { self->private_impl.f_block_smoothing_lowest_scan_al[v_i][v_j] = 16u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 8u) { self->private_impl.f_seen_dht[v_i] = false; v_i += 1u; } return wuffs_base__make_status(NULL); } // -------- func jpeg.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_jpeg__decoder__set_report_metadata( wuffs_jpeg__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_jpeg__decoder__tell_me_more( wuffs_jpeg__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func jpeg.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_jpeg__decoder__workbuf_len( const wuffs_jpeg__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } if (self->private_impl.f_use_lower_quality && (self->private_impl.f_sof_marker < 194u)) { return wuffs_base__utility__make_range_ii_u64(0u, self->private_impl.f_components_workbuf_offsets[8u]); } return wuffs_base__utility__make_range_ii_u64(self->private_impl.f_components_workbuf_offsets[8u], self->private_impl.f_components_workbuf_offsets[8u]); } // -------- func jpeg.decoder.top_left_quants_has_zero WUFFS_BASE__GENERATED_C_CODE static bool wuffs_jpeg__decoder__top_left_quants_has_zero( const wuffs_jpeg__decoder* self, uint32_t a_q) { return ((self->private_impl.f_quant_tables[a_q][0u] == 0u) || (self->private_impl.f_quant_tables[a_q][1u] == 0u) || (self->private_impl.f_quant_tables[a_q][2u] == 0u) || (self->private_impl.f_quant_tables[a_q][3u] == 0u) || (self->private_impl.f_quant_tables[a_q][8u] == 0u) || (self->private_impl.f_quant_tables[a_q][9u] == 0u) || (self->private_impl.f_quant_tables[a_q][10u] == 0u) || (self->private_impl.f_quant_tables[a_q][16u] == 0u) || (self->private_impl.f_quant_tables[a_q][17u] == 0u) || (self->private_impl.f_quant_tables[a_q][24u] == 0u)); } // -------- func jpeg.decoder.load_mcu_blocks_for_single_component_smooth WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_jpeg__decoder__load_mcu_blocks_for_single_component_smooth( wuffs_jpeg__decoder* self, uint32_t a_mx, uint32_t a_my, wuffs_base__slice_u8 a_workbuf, uint32_t a_csel) { uint64_t v_stride16 = 0; uint64_t v_offset = 0; uint32_t v_dx = 0; uint32_t v_dy = 0; uint32_t v_mx = 0; uint32_t v_my = 0; uint8_t v_q = 0; uint32_t v_q_00 = 0; uint32_t v_q_xy = 0; uint8_t v_al = 0; uint32_t v_scratch = 0; uint32_t v_limit = 0; v_stride16 = ((uint64_t)((self->private_impl.f_components_workbuf_widths[a_csel] * 16u))); v_offset = (self->private_impl.f_components_workbuf_offsets[(a_csel | 4u)] + (((uint64_t)(a_mx)) * 128u) + (((uint64_t)(a_my)) * v_stride16)); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_load_host_endian(&self->private_data.f_mcu_blocks[0], 1u * (size_t)128u, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset)); } v_dy = 0u; while (v_dy < 5u) { v_my = wuffs_base__u32__min(self->private_impl.f_block_smoothing_my_max_incl, wuffs_base__u32__sat_sub((a_my + v_dy), 2u)); v_dx = 0u; while (v_dx < 5u) { v_mx = wuffs_base__u32__min(self->private_impl.f_block_smoothing_mx_max_incl, wuffs_base__u32__sat_sub((a_mx + v_dx), 2u)); v_offset = (self->private_impl.f_components_workbuf_offsets[(a_csel | 4u)] + (((uint64_t)(v_mx)) * 128u) + (((uint64_t)(v_my)) * v_stride16)); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_private_impl__bulk_load_host_endian(&self->private_impl.f_block_smoothing_dc_values[v_dy][v_dx], 1u * (size_t)2u, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset)); } v_dx += 1u; } v_dy += 1u; } v_q = self->private_impl.f_components_tq[a_csel]; v_q_00 = ((uint32_t)(self->private_impl.f_quant_tables[v_q][0u])); if (v_q_00 <= 0u) { return wuffs_base__make_empty_struct(); } if (0u != (16u & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][1u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][2u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][3u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][4u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][5u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][6u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][7u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][8u] & self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][9u])) { v_scratch = 0u; v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(4294967288u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(6u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(42u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(6u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(4294967288u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(42u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(152u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(42u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(4294967288u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(6u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(42u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(6u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(4294967288u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(4294967290u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + 128u)) / 256u))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + 128u)) / 256u))); } self->private_data.f_mcu_blocks[0u][0u] = ((uint16_t)(v_scratch)); v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][1u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][1u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(4294967283u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(38u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(4294967258u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967283u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][1u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][2u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][2u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(4294967291u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(4294967282u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(4294967291u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][2u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][3u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][3u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][3u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][8u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][8u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(38u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(4294967283u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(4294967258u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967283u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][8u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][9u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][9u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(9u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(4294967287u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(4294967287u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(9u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][9u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][10u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][10u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][10u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][16u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][16u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(4294967291u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(4294967282u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(4294967291u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][16u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][17u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][17u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(4294967293u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(3u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][17u] = ((uint16_t)(v_scratch)); } v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][24u])); if ((v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][24u] == 0u)) { v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(2u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(4294967294u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } else { v_scratch = ((uint32_t)(0u - (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u)))); } self->private_data.f_mcu_blocks[0u][24u] = ((uint16_t)(v_scratch)); } } else { v_al = self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][1u]; v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][1u])); if ((v_al > 0u) && (v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][1u] == 0u)) { v_limit = ((((uint32_t)(1u)) << v_al) - 1u); v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(4294967289u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(50u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(4294967246u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } else { v_scratch = ((uint32_t)(0u - wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } self->private_data.f_mcu_blocks[0u][1u] = ((uint16_t)(v_scratch)); } v_al = self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][5u]; v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][2u])); if ((v_al > 0u) && (v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][2u] == 0u)) { v_limit = ((((uint32_t)(1u)) << v_al) - 1u); v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(4294967272u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } else { v_scratch = ((uint32_t)(0u - wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } self->private_data.f_mcu_blocks[0u][2u] = ((uint16_t)(v_scratch)); } v_al = self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][2u]; v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][8u])); if ((v_al > 0u) && (v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][8u] == 0u)) { v_limit = ((((uint32_t)(1u)) << v_al) - 1u); v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(4294967289u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(50u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(4294967246u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(7u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } else { v_scratch = ((uint32_t)(0u - wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } self->private_data.f_mcu_blocks[0u][8u] = ((uint16_t)(v_scratch)); } v_al = self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][4u]; v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][9u])); if ((v_al > 0u) && (v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][9u] == 0u)) { v_limit = ((((uint32_t)(1u)) << v_al) - 1u); v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(10u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(4294967286u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(4294967286u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(10u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(1u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } else { v_scratch = ((uint32_t)(0u - wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } self->private_data.f_mcu_blocks[0u][9u] = ((uint16_t)(v_scratch)); } v_al = self->private_impl.f_block_smoothing_lowest_scan_al[a_csel][3u]; v_q_xy = ((uint32_t)(self->private_impl.f_quant_tables[v_q][16u])); if ((v_al > 0u) && (v_q_xy > 0u) && (self->private_data.f_mcu_blocks[0u][16u] == 0u)) { v_limit = ((((uint32_t)(1u)) << v_al) - 1u); v_scratch = 0u; v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][1u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[0u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][1u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[1u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][1u]))); v_scratch += ((uint32_t)(4294967272u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[2u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][1u]))); v_scratch += ((uint32_t)(13u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[3u][4u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][0u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][1u]))); v_scratch += ((uint32_t)(4294967295u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][2u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][3u]))); v_scratch += ((uint32_t)(0u * wuffs_base__utility__sign_extend_convert_u16_u32(self->private_impl.f_block_smoothing_dc_values[4u][4u]))); v_scratch *= v_q_00; if (v_scratch < 2147483648u) { v_scratch = ((uint32_t)(0u + wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u + v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } else { v_scratch = ((uint32_t)(0u - wuffs_base__u32__min(v_limit, (((uint32_t)(((uint32_t)(0u - v_scratch)) + (v_q_xy << 7u))) / (v_q_xy << 8u))))); } self->private_data.f_mcu_blocks[0u][16u] = ((uint16_t)(v_scratch)); } } return wuffs_base__make_empty_struct(); } // -------- func jpeg.decoder.decode_mcu WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { return (*self->private_impl.choosy_decode_mcu)(self, a_dst, a_workbuf, a_mx, a_my); } WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu__choosy_default( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { uint32_t v_ret = 0; uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint8_t v_csel = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint32_t v_pos = 0; uint8_t v_dc_h = 0; uint32_t v_dc_symbol = 0; uint32_t v_dc_ht_fast = 0; uint32_t v_dc_bl = 0; uint32_t v_dc_code = 0; uint32_t v_dc_blm1 = 0; uint32_t v_dc_ht_slow = 0; uint16_t v_dc_value = 0; uint16_t v_dc_extend = 0; const uint16_t* v_ac_huff_table_fast = NULL; uint8_t v_ac_h = 0; uint32_t v_ac_symbol = 0; uint32_t v_ac_ht_fast = 0; uint32_t v_ac_bl = 0; uint32_t v_ac_code = 0; uint32_t v_ac_blm1 = 0; uint32_t v_ac_ht_slow = 0; uint16_t v_ac_value = 0; uint16_t v_ac_extend = 0; uint32_t v_ac_rrrr = 0; uint32_t v_ac_ssss = 0; uint32_t v_z = 0; uint32_t v_mcb = 0; uint64_t v_stride = 0; uint64_t v_offset = 0; v_bits = self->private_impl.f_bitstream_bits; v_n_bits = self->private_impl.f_bitstream_n_bits; if (self->private_impl.f_bitstream_ri > self->private_impl.f_bitstream_wi) { return 2u; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi), ((uint64_t)(self->private_impl.f_bitstream_ri))); do { while (self->private_impl.f_mcu_current_block < self->private_impl.f_mcu_num_blocks) { while (self->private_impl.f_mcu_zig_index <= 0u) { wuffs_private_impl__bulk_memset(&self->private_data.f_mcu_blocks[0], 1u * (size_t)128u, 0u); if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_dc_h = self->private_impl.f_mcu_blocks_dc_hselector[self->private_impl.f_mcu_current_block]; v_dc_ht_fast = ((uint32_t)(self->private_impl.f_huff_tables_fast[v_dc_h][(v_bits >> 56u)])); v_dc_bl = (v_dc_ht_fast >> 8u); if (v_n_bits >= v_dc_bl) { v_dc_symbol = (15u & v_dc_ht_fast); v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; v_bits <<= (v_dc_bl & 63u); v_n_bits -= v_dc_bl; } else { v_dc_code = ((uint32_t)((v_bits >> 55u))); v_dc_blm1 = 8u; v_bits <<= 9u; v_n_bits -= 9u; while (true) { v_dc_ht_slow = self->private_impl.f_huff_tables_slow[v_dc_h][v_dc_blm1]; if (v_dc_code < (v_dc_ht_slow >> 8u)) { v_dc_symbol = (15u & ((uint32_t)(self->private_impl.f_huff_tables_symbols[v_dc_h][(255u & ((uint32_t)(v_dc_code + v_dc_ht_slow)))]))); v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; break; } v_dc_code = (((uint32_t)(v_dc_code << 1u)) | ((uint32_t)((v_bits >> 63u)))); v_bits <<= 1u; v_n_bits -= 1u; v_dc_blm1 = ((v_dc_blm1 + 1u) & 15u); if (v_dc_blm1 == 0u) { v_dc_symbol = 0u; v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; break; } } } v_dc_value = ((uint16_t)(((v_bits >> 32u) >> (32u - v_dc_symbol)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_dc_value += ((uint16_t)(v_dc_extend & ((uint16_t)(((uint16_t)(wuffs_base__utility__sign_extend_rshift_u64(v_bits, 63u))) ^ 65535u)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_dc_symbol; v_n_bits -= v_dc_symbol; v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[self->private_impl.f_mcu_current_block]]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_mcu_previous_dc_values[v_csel] += v_dc_value; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_data.f_mcu_blocks[0u][0u] = self->private_impl.f_mcu_previous_dc_values[v_csel]; self->private_impl.f_mcu_zig_index = 1u; break; } if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } if (v_n_bits < 16u) { v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); } v_z = 1u; self->private_impl.f_mcu_zig_index = 0u; v_ac_h = self->private_impl.f_mcu_blocks_ac_hselector[self->private_impl.f_mcu_current_block]; v_ac_huff_table_fast = &self->private_impl.f_huff_tables_fast[v_ac_h][0u]; while (v_z < 64u) { v_ac_ht_fast = ((uint32_t)(v_ac_huff_table_fast[(v_bits >> 56u)])); if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_ac_bl = (v_ac_ht_fast >> 8u); if (v_n_bits >= v_ac_bl) { v_ac_symbol = (255u & v_ac_ht_fast); v_bits <<= (v_ac_bl & 63u); v_n_bits -= v_ac_bl; } else { v_ac_code = ((uint32_t)((v_bits >> 55u))); v_ac_blm1 = 8u; v_bits <<= 9u; v_n_bits -= 9u; while (true) { v_ac_ht_slow = self->private_impl.f_huff_tables_slow[v_ac_h][v_ac_blm1]; if (v_ac_code < (v_ac_ht_slow >> 8u)) { v_ac_symbol = ((uint32_t)(self->private_impl.f_huff_tables_symbols[v_ac_h][(255u & ((uint32_t)(v_ac_code + v_ac_ht_slow)))])); break; } v_ac_code = (((uint32_t)(v_ac_code << 1u)) | ((uint32_t)((v_bits >> 63u)))); v_bits <<= 1u; v_n_bits -= 1u; v_ac_blm1 = ((v_ac_blm1 + 1u) & 15u); if (v_ac_blm1 == 0u) { v_ac_symbol = 0u; break; } } } v_ac_rrrr = (v_ac_symbol >> 4u); v_z += (v_ac_rrrr + 1u); v_ac_ssss = (v_ac_symbol & 15u); v_ac_extend = WUFFS_JPEG__EXTEND[v_ac_ssss]; if (v_ac_ssss > 0u) { v_ac_value = ((uint16_t)((v_bits >> (64u - v_ac_ssss)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_ac_value += ((uint16_t)(v_ac_extend & ((uint16_t)(((uint16_t)(wuffs_base__utility__sign_extend_rshift_u64(v_bits, 63u))) ^ 65535u)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_ac_ssss; v_n_bits -= v_ac_ssss; self->private_data.f_mcu_blocks[0u][WUFFS_JPEG__UNZIG[v_z]] = v_ac_value; } else if (v_ac_rrrr < 15u) { break; } } v_mcb = self->private_impl.f_mcu_current_block; self->private_impl.f_mcu_current_block += 1u; if (self->private_impl.f_test_only_interrupt_decode_mcu) { goto label__goto_done__break; } if ( ! self->private_impl.f_swizzle_immediately) { v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[v_mcb]]; v_stride = ((uint64_t)(self->private_impl.f_components_workbuf_widths[v_csel])); v_offset = (self->private_impl.f_mcu_blocks_offset[v_mcb] + (((uint64_t)(self->private_impl.f_mcu_blocks_mx_mul[v_mcb])) * ((uint64_t)(a_mx))) + (((uint64_t)(self->private_impl.f_mcu_blocks_my_mul[v_mcb])) * ((uint64_t)(a_my)))); if (v_offset <= ((uint64_t)(a_workbuf.len))) { wuffs_jpeg__decoder__decode_idct(self, wuffs_base__slice_u8__subslice_i(a_workbuf, v_offset), v_stride, ((uint32_t)(self->private_impl.f_components_tq[v_csel]))); } } else if (self->private_impl.f_num_components == 1u) { wuffs_jpeg__decoder__decode_idct(self, wuffs_base__make_slice_u8(self->private_data.f_swizzle_immediately_buffer, 64), 8u, ((uint32_t)(self->private_impl.f_components_tq[v_csel]))); self->private_impl.f_swizzle_immediately_status = wuffs_jpeg__decoder__swizzle_gray(self, a_dst, wuffs_base__make_slice_u8(self->private_data.f_swizzle_immediately_buffer, 64), ((a_mx + 0u) * 8u), ((a_mx + 1u) * 8u), ((a_my + 0u) * 8u), ((a_my + 1u) * 8u), 8u); if ( ! wuffs_base__status__is_ok(&self->private_impl.f_swizzle_immediately_status)) { v_ret = 3u; goto label__goto_done__break; } break; } else { v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[v_mcb]]; v_stride = (8u * ((uint64_t)(self->private_impl.f_components_h[v_csel]))); wuffs_jpeg__decoder__decode_idct(self, wuffs_base__make_slice_u8_ij(self->private_data.f_swizzle_immediately_buffer, self->private_impl.f_swizzle_immediately_b_offsets[v_mcb], 640), v_stride, ((uint32_t)(self->private_impl.f_components_tq[v_csel]))); if (self->private_impl.f_mcu_current_block < self->private_impl.f_mcu_num_blocks) { continue; } self->private_impl.f_swizzle_immediately_status = wuffs_jpeg__decoder__swizzle_colorful(self, a_dst, wuffs_base__utility__empty_slice_u8(), ((a_mx + 0u) * 8u * ((uint32_t)(self->private_impl.f_max_incl_components_h))), ((a_mx + 1u) * 8u * ((uint32_t)(self->private_impl.f_max_incl_components_h))), ((a_my + 0u) * 8u * ((uint32_t)(self->private_impl.f_max_incl_components_v))), ((a_my + 1u) * 8u * ((uint32_t)(self->private_impl.f_max_incl_components_v)))); if ( ! wuffs_base__status__is_ok(&self->private_impl.f_swizzle_immediately_status)) { v_ret = 3u; goto label__goto_done__break; } break; } } self->private_impl.f_mcu_current_block = 0u; } while (0); label__goto_done__break:; v_pos = ((uint32_t)(wuffs_base__u64__sat_add((v_r ? v_r->meta.pos : 0), ((uint64_t)(iop_v_r - io0_v_r))))); if (v_pos > self->private_impl.f_bitstream_wi) { v_ret = 2u; } else { self->private_impl.f_bitstream_ri = v_pos; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } self->private_impl.f_bitstream_bits = v_bits; self->private_impl.f_bitstream_n_bits = v_n_bits; return v_ret; } // -------- func jpeg.decoder.decode_mcu_progressive_ac_high_bits WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_ac_high_bits( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { uint32_t v_ret = 0; uint64_t v_bits = 0; uint32_t v_n_bits = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint32_t v_pos = 0; const uint16_t* v_ac_huff_table_fast = NULL; uint8_t v_ac_h = 0; uint32_t v_ac_symbol = 0; uint32_t v_ac_ht_fast = 0; uint32_t v_ac_bl = 0; uint32_t v_ac_code = 0; uint32_t v_ac_blm1 = 0; uint32_t v_ac_ht_slow = 0; uint16_t v_ac_value = 0; uint16_t v_ac_extend = 0; uint32_t v_ac_rrrr = 0; uint32_t v_ac_ssss = 0; uint32_t v_z = 0; if (self->private_impl.f_eob_run > 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_eob_run -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif return 0u; } v_bits = self->private_impl.f_bitstream_bits; v_n_bits = self->private_impl.f_bitstream_n_bits; if (self->private_impl.f_bitstream_ri > self->private_impl.f_bitstream_wi) { return 2u; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi), ((uint64_t)(self->private_impl.f_bitstream_ri))); do { do { if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } if (v_n_bits < 16u) { v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); } v_z = self->private_impl.f_mcu_zig_index; self->private_impl.f_mcu_zig_index = 0u; v_ac_h = self->private_impl.f_mcu_blocks_ac_hselector[0u]; v_ac_huff_table_fast = &self->private_impl.f_huff_tables_fast[v_ac_h][0u]; while (v_z <= ((uint32_t)(self->private_impl.f_scan_se))) { v_ac_ht_fast = ((uint32_t)(v_ac_huff_table_fast[(v_bits >> 56u)])); if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_ac_bl = (v_ac_ht_fast >> 8u); if (v_n_bits >= v_ac_bl) { v_ac_symbol = (255u & v_ac_ht_fast); v_bits <<= (v_ac_bl & 63u); v_n_bits -= v_ac_bl; } else { v_ac_code = ((uint32_t)((v_bits >> 55u))); v_ac_blm1 = 8u; v_bits <<= 9u; v_n_bits -= 9u; while (true) { v_ac_ht_slow = self->private_impl.f_huff_tables_slow[v_ac_h][v_ac_blm1]; if (v_ac_code < (v_ac_ht_slow >> 8u)) { v_ac_symbol = ((uint32_t)(self->private_impl.f_huff_tables_symbols[v_ac_h][(255u & ((uint32_t)(v_ac_code + v_ac_ht_slow)))])); break; } v_ac_code = (((uint32_t)(v_ac_code << 1u)) | ((uint32_t)((v_bits >> 63u)))); v_bits <<= 1u; v_n_bits -= 1u; v_ac_blm1 = ((v_ac_blm1 + 1u) & 15u); if (v_ac_blm1 == 0u) { v_ac_symbol = 0u; break; } } } v_ac_rrrr = (v_ac_symbol >> 4u); v_z += (v_ac_rrrr + 1u); v_ac_ssss = (v_ac_symbol & 15u); v_ac_extend = WUFFS_JPEG__EXTEND[v_ac_ssss]; if (v_ac_ssss > 0u) { v_ac_value = ((uint16_t)((v_bits >> (64u - v_ac_ssss)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_ac_value += ((uint16_t)(v_ac_extend & ((uint16_t)(((uint16_t)(wuffs_base__utility__sign_extend_rshift_u64(v_bits, 63u))) ^ 65535u)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_ac_ssss; v_n_bits -= v_ac_ssss; self->private_data.f_mcu_blocks[0u][WUFFS_JPEG__UNZIG[v_z]] = ((uint16_t)(((uint16_t)(v_ac_value << self->private_impl.f_scan_al)))); } else if (v_ac_rrrr < 15u) { self->private_impl.f_eob_run = ((uint16_t)(((uint16_t)(((uint16_t)(((uint16_t)(1u)) << v_ac_rrrr)) - 1u)))); if (v_ac_rrrr > 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_eob_run += ((uint16_t)((v_bits >> (64u - v_ac_rrrr)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_ac_rrrr; v_n_bits -= v_ac_rrrr; } break; } } } while (0); } while (0); label__goto_done__break:; v_pos = ((uint32_t)(wuffs_base__u64__sat_add((v_r ? v_r->meta.pos : 0), ((uint64_t)(iop_v_r - io0_v_r))))); if (v_pos > self->private_impl.f_bitstream_wi) { v_ret = 2u; } else { self->private_impl.f_bitstream_ri = v_pos; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } self->private_impl.f_bitstream_bits = v_bits; self->private_impl.f_bitstream_n_bits = v_n_bits; return v_ret; } // -------- func jpeg.decoder.decode_mcu_progressive_ac_low_bit WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_ac_low_bit( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { uint32_t v_ret = 0; uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint16_t v_one_lshift_scan_al = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint32_t v_pos = 0; const uint16_t* v_ac_huff_table_fast = NULL; uint8_t v_ac_h = 0; uint32_t v_ac_symbol = 0; uint32_t v_ac_ht_fast = 0; uint32_t v_ac_bl = 0; uint32_t v_ac_code = 0; uint32_t v_ac_blm1 = 0; uint32_t v_ac_ht_slow = 0; uint16_t v_ac_value = 0; uint32_t v_ac_rrrr = 0; uint32_t v_ac_ssss = 0; uint8_t v_unzig = 0; bool v_bit = false; v_bits = self->private_impl.f_bitstream_bits; v_n_bits = self->private_impl.f_bitstream_n_bits; v_one_lshift_scan_al = ((uint16_t)(((uint16_t)(1u)) << self->private_impl.f_scan_al)); if (self->private_impl.f_bitstream_ri > self->private_impl.f_bitstream_wi) { return 2u; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi), ((uint64_t)(self->private_impl.f_bitstream_ri))); do { do { if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } while (true) { if (self->private_impl.f_eob_run > 0u) { break; } v_ac_h = self->private_impl.f_mcu_blocks_ac_hselector[0u]; v_ac_huff_table_fast = &self->private_impl.f_huff_tables_fast[v_ac_h][0u]; while (true) { if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_ac_ht_fast = ((uint32_t)(v_ac_huff_table_fast[(v_bits >> 56u)])); v_ac_bl = (v_ac_ht_fast >> 8u); if (v_n_bits >= v_ac_bl) { v_ac_symbol = (255u & v_ac_ht_fast); v_bits <<= (v_ac_bl & 63u); v_n_bits -= v_ac_bl; } else { v_ac_code = ((uint32_t)((v_bits >> 55u))); v_ac_blm1 = 8u; v_bits <<= 9u; v_n_bits -= 9u; while (true) { v_ac_ht_slow = self->private_impl.f_huff_tables_slow[v_ac_h][v_ac_blm1]; if (v_ac_code < (v_ac_ht_slow >> 8u)) { v_ac_symbol = ((uint32_t)(self->private_impl.f_huff_tables_symbols[v_ac_h][(255u & ((uint32_t)(v_ac_code + v_ac_ht_slow)))])); break; } v_ac_code = (((uint32_t)(v_ac_code << 1u)) | ((uint32_t)((v_bits >> 63u)))); v_bits <<= 1u; v_n_bits -= 1u; v_ac_blm1 = ((v_ac_blm1 + 1u) & 15u); if (v_ac_blm1 == 0u) { v_ac_symbol = 0u; break; } } } v_ac_rrrr = (v_ac_symbol >> 4u); v_ac_ssss = (v_ac_symbol & 15u); v_ac_value = 0u; if (v_ac_ssss > 0u) { v_ac_value = ((uint16_t)(((uint16_t)(1u)) << self->private_impl.f_scan_al)); if ((v_bits >> 63u) == 0u) { v_ac_value = ((uint16_t)(((uint16_t)(65535u)) << self->private_impl.f_scan_al)); } v_bits <<= 1u; v_n_bits -= 1u; } else if (v_ac_rrrr < 15u) { self->private_impl.f_eob_run = ((uint16_t)(((uint16_t)(1u)) << v_ac_rrrr)); if (v_ac_rrrr > 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_eob_run += ((uint16_t)((v_bits >> (64u - v_ac_rrrr)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_ac_rrrr; v_n_bits -= v_ac_rrrr; } goto label__goto_do_eob__break; } while (true) { v_unzig = WUFFS_JPEG__UNZIG[(1u + self->private_impl.f_mcu_zig_index)]; if (self->private_data.f_mcu_blocks[0u][v_unzig] != 0u) { if (v_n_bits == 0u) { if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; } v_bit = ((v_bits >> 63u) > 0u); v_bits <<= 1u; v_n_bits -= 1u; if (v_bit) { if (self->private_data.f_mcu_blocks[0u][v_unzig] < 32768u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_mcu_blocks[0u][v_unzig] += v_one_lshift_scan_al; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_mcu_blocks[0u][v_unzig] -= v_one_lshift_scan_al; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } } } else if (v_ac_rrrr <= 0u) { break; } else { v_ac_rrrr -= 1u; } if (self->private_impl.f_mcu_zig_index >= ((uint32_t)(self->private_impl.f_scan_se))) { break; } self->private_impl.f_mcu_zig_index += 1u; } if (v_ac_value != 0u) { self->private_data.f_mcu_blocks[0u][WUFFS_JPEG__UNZIG[(1u + self->private_impl.f_mcu_zig_index)]] = v_ac_value; } if (self->private_impl.f_mcu_zig_index >= ((uint32_t)(self->private_impl.f_scan_se))) { break; } self->private_impl.f_mcu_zig_index += 1u; } goto label__block__break; } label__goto_do_eob__break:; if (self->private_impl.f_eob_run <= 0u) { v_ret = 2u; goto label__goto_done__break; } while (true) { v_unzig = WUFFS_JPEG__UNZIG[(1u + self->private_impl.f_mcu_zig_index)]; if (self->private_data.f_mcu_blocks[0u][v_unzig] != 0u) { if (v_n_bits == 0u) { if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; } v_bit = ((v_bits >> 63u) > 0u); v_bits <<= 1u; v_n_bits -= 1u; if (v_bit) { if (self->private_data.f_mcu_blocks[0u][v_unzig] < 32768u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_mcu_blocks[0u][v_unzig] += v_one_lshift_scan_al; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_mcu_blocks[0u][v_unzig] -= v_one_lshift_scan_al; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } } } if (self->private_impl.f_mcu_zig_index >= ((uint32_t)(self->private_impl.f_scan_se))) { break; } self->private_impl.f_mcu_zig_index += 1u; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_eob_run -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } while (0); label__block__break:; } while (0); label__goto_done__break:; v_pos = ((uint32_t)(wuffs_base__u64__sat_add((v_r ? v_r->meta.pos : 0), ((uint64_t)(iop_v_r - io0_v_r))))); if (v_pos > self->private_impl.f_bitstream_wi) { v_ret = 2u; } else { self->private_impl.f_bitstream_ri = v_pos; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } self->private_impl.f_bitstream_bits = v_bits; self->private_impl.f_bitstream_n_bits = v_n_bits; return v_ret; } // -------- func jpeg.decoder.decode_mcu_progressive_dc_high_bits WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_dc_high_bits( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { uint32_t v_ret = 0; uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint8_t v_csel = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint32_t v_pos = 0; uint8_t v_dc_h = 0; uint32_t v_dc_symbol = 0; uint32_t v_dc_ht_fast = 0; uint32_t v_dc_bl = 0; uint32_t v_dc_code = 0; uint32_t v_dc_blm1 = 0; uint32_t v_dc_ht_slow = 0; uint16_t v_dc_value = 0; uint16_t v_dc_extend = 0; v_bits = self->private_impl.f_bitstream_bits; v_n_bits = self->private_impl.f_bitstream_n_bits; if (self->private_impl.f_bitstream_ri > self->private_impl.f_bitstream_wi) { return 2u; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi), ((uint64_t)(self->private_impl.f_bitstream_ri))); do { while (self->private_impl.f_mcu_current_block < self->private_impl.f_mcu_num_blocks) { if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } do { if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; v_dc_h = self->private_impl.f_mcu_blocks_dc_hselector[self->private_impl.f_mcu_current_block]; v_dc_ht_fast = ((uint32_t)(self->private_impl.f_huff_tables_fast[v_dc_h][(v_bits >> 56u)])); v_dc_bl = (v_dc_ht_fast >> 8u); if (v_n_bits >= v_dc_bl) { v_dc_symbol = (15u & v_dc_ht_fast); v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; v_bits <<= (v_dc_bl & 63u); v_n_bits -= v_dc_bl; } else { v_dc_code = ((uint32_t)((v_bits >> 55u))); v_dc_blm1 = 8u; v_bits <<= 9u; v_n_bits -= 9u; while (true) { v_dc_ht_slow = self->private_impl.f_huff_tables_slow[v_dc_h][v_dc_blm1]; if (v_dc_code < (v_dc_ht_slow >> 8u)) { v_dc_symbol = (15u & ((uint32_t)(self->private_impl.f_huff_tables_symbols[v_dc_h][(255u & ((uint32_t)(v_dc_code + v_dc_ht_slow)))]))); v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; break; } v_dc_code = (((uint32_t)(v_dc_code << 1u)) | ((uint32_t)((v_bits >> 63u)))); v_bits <<= 1u; v_n_bits -= 1u; v_dc_blm1 = ((v_dc_blm1 + 1u) & 15u); if (v_dc_blm1 == 0u) { v_dc_symbol = 0u; v_dc_extend = WUFFS_JPEG__EXTEND[v_dc_symbol]; break; } } } v_dc_value = ((uint16_t)(((v_bits >> 32u) >> (32u - v_dc_symbol)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_dc_value += ((uint16_t)(v_dc_extend & ((uint16_t)(((uint16_t)(wuffs_base__utility__sign_extend_rshift_u64(v_bits, 63u))) ^ 65535u)))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_bits <<= v_dc_symbol; v_n_bits -= v_dc_symbol; v_csel = self->private_impl.f_scan_comps_cselector[self->private_impl.f_mcu_blocks_sselector[self->private_impl.f_mcu_current_block]]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_mcu_previous_dc_values[v_csel] += v_dc_value; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_data.f_mcu_blocks[self->private_impl.f_mcu_current_block][0u] = ((uint16_t)(self->private_impl.f_mcu_previous_dc_values[v_csel] << self->private_impl.f_scan_al)); } while (0); self->private_impl.f_mcu_current_block += 1u; } self->private_impl.f_mcu_current_block = 0u; } while (0); label__goto_done__break:; v_pos = ((uint32_t)(wuffs_base__u64__sat_add((v_r ? v_r->meta.pos : 0), ((uint64_t)(iop_v_r - io0_v_r))))); if (v_pos > self->private_impl.f_bitstream_wi) { v_ret = 2u; } else { self->private_impl.f_bitstream_ri = v_pos; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } self->private_impl.f_bitstream_bits = v_bits; self->private_impl.f_bitstream_n_bits = v_n_bits; return v_ret; } // -------- func jpeg.decoder.decode_mcu_progressive_dc_low_bit WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_jpeg__decoder__decode_mcu_progressive_dc_low_bit( wuffs_jpeg__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf, uint32_t a_mx, uint32_t a_my) { uint32_t v_ret = 0; uint64_t v_bits = 0; uint32_t v_n_bits = 0; uint16_t v_one_lshift_scan_al = 0; wuffs_base__io_buffer u_r = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_r = &u_r; const uint8_t* iop_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io0_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_v_r WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint32_t v_pos = 0; v_bits = self->private_impl.f_bitstream_bits; v_n_bits = self->private_impl.f_bitstream_n_bits; v_one_lshift_scan_al = ((uint16_t)(((uint16_t)(1u)) << self->private_impl.f_scan_al)); if (self->private_impl.f_bitstream_ri > self->private_impl.f_bitstream_wi) { return 2u; } { wuffs_base__io_buffer* o_0_v_r = v_r; const uint8_t* o_0_iop_v_r = iop_v_r; const uint8_t* o_0_io0_v_r = io0_v_r; const uint8_t* o_0_io1_v_r = io1_v_r; const uint8_t* o_0_io2_v_r = io2_v_r; v_r = wuffs_private_impl__io_reader__set( &u_r, &iop_v_r, &io0_v_r, &io1_v_r, &io2_v_r, wuffs_base__make_slice_u8_ij(self->private_data.f_bitstream_buffer, self->private_impl.f_bitstream_ri, self->private_impl.f_bitstream_wi), ((uint64_t)(self->private_impl.f_bitstream_ri))); do { while (self->private_impl.f_mcu_current_block < self->private_impl.f_mcu_num_blocks) { if (((uint64_t)(io2_v_r - iop_v_r)) < 264u) { v_ret = 1u; goto label__goto_done__break; } do { if (((uint64_t)(io2_v_r - iop_v_r)) < 8u) { v_ret = 2u; goto label__goto_done__break; } v_bits |= (wuffs_base__peek_u64be__no_bounds_check(iop_v_r) >> (v_n_bits & 63u)); iop_v_r += ((63u - (v_n_bits & 63u)) >> 3u); v_n_bits |= 56u; if ((v_bits >> 63u) != 0u) { self->private_data.f_mcu_blocks[self->private_impl.f_mcu_current_block][0u] |= v_one_lshift_scan_al; } v_bits <<= 1u; v_n_bits -= 1u; } while (0); self->private_impl.f_mcu_current_block += 1u; } self->private_impl.f_mcu_current_block = 0u; } while (0); label__goto_done__break:; v_pos = ((uint32_t)(wuffs_base__u64__sat_add((v_r ? v_r->meta.pos : 0), ((uint64_t)(iop_v_r - io0_v_r))))); if (v_pos > self->private_impl.f_bitstream_wi) { v_ret = 2u; } else { self->private_impl.f_bitstream_ri = v_pos; } v_r = o_0_v_r; iop_v_r = o_0_iop_v_r; io0_v_r = o_0_io0_v_r; io1_v_r = o_0_io1_v_r; io2_v_r = o_0_io2_v_r; } self->private_impl.f_bitstream_bits = v_bits; self->private_impl.f_bitstream_n_bits = v_n_bits; return v_ret; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JPEG) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JSON) // ---------------- Status Codes Implementations const char wuffs_json__error__bad_c0_control_code[] = "#json: bad C0 control code"; const char wuffs_json__error__bad_utf_8[] = "#json: bad UTF-8"; const char wuffs_json__error__bad_backslash_escape[] = "#json: bad backslash-escape"; const char wuffs_json__error__bad_input[] = "#json: bad input"; const char wuffs_json__error__bad_new_line_in_a_string[] = "#json: bad new-line in a string"; const char wuffs_json__error__bad_quirk_combination[] = "#json: bad quirk combination"; const char wuffs_json__error__unsupported_number_length[] = "#json: unsupported number length"; const char wuffs_json__error__unsupported_recursion_depth[] = "#json: unsupported recursion depth"; const char wuffs_json__error__internal_error_inconsistent_i_o[] = "#json: internal error: inconsistent I/O"; // ---------------- Private Consts #define WUFFS_JSON__DECODER_NUMBER_LENGTH_MAX_INCL 99u static const uint8_t WUFFS_JSON__LUT_BACKSLASHES[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 3u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 162u, 0u, 0u, 0u, 0u, 5u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 175u, 7u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 4u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 220u, 0u, 0u, 0u, 0u, 1u, 136u, 0u, 0u, 2u, 140u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 138u, 0u, 0u, 0u, 141u, 0u, 137u, 0u, 6u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, }; static const uint8_t WUFFS_JSON__LUT_QUIRKY_BACKSLASHES_QUIRKS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 1u, 3u, 4u, 5u, 6u, 7u, 10u, }; static const uint8_t WUFFS_JSON__LUT_QUIRKY_BACKSLASHES_CHARS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 7u, 27u, 10u, 63u, 39u, 11u, 0u, }; static const uint8_t WUFFS_JSON__LUT_CHARS[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 128u, 129u, 130u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 138u, 139u, 140u, 141u, 142u, 143u, 144u, 145u, 146u, 147u, 148u, 149u, 150u, 151u, 152u, 153u, 154u, 155u, 156u, 157u, 158u, 159u, 0u, 0u, 1u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 2u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 16u, 32u, 32u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 3u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 5u, 5u, 5u, 5u, 5u, 32u, 32u, 32u, 32u, 32u, 32u, 32u, 32u, 32u, 32u, 32u, }; #define WUFFS_JSON__CLASS_WHITESPACE 0u #define WUFFS_JSON__CLASS_STRING 1u #define WUFFS_JSON__CLASS_COMMA 2u #define WUFFS_JSON__CLASS_COLON 3u #define WUFFS_JSON__CLASS_NUMBER 4u #define WUFFS_JSON__CLASS_OPEN_CURLY_BRACE 5u #define WUFFS_JSON__CLASS_CLOSE_CURLY_BRACE 6u #define WUFFS_JSON__CLASS_OPEN_SQUARE_BRACKET 7u #define WUFFS_JSON__CLASS_CLOSE_SQUARE_BRACKET 8u #define WUFFS_JSON__CLASS_FALSE 9u #define WUFFS_JSON__CLASS_TRUE 10u #define WUFFS_JSON__CLASS_NULL_NAN_INF 11u #define WUFFS_JSON__CLASS_COMMENT 12u #define WUFFS_JSON__EXPECT_VALUE 7858u #define WUFFS_JSON__EXPECT_NON_STRING_VALUE 7856u #define WUFFS_JSON__EXPECT_STRING 4098u #define WUFFS_JSON__EXPECT_COMMA 4100u #define WUFFS_JSON__EXPECT_COLON 4104u #define WUFFS_JSON__EXPECT_NUMBER 4112u #define WUFFS_JSON__EXPECT_CLOSE_CURLY_BRACE 4160u #define WUFFS_JSON__EXPECT_CLOSE_SQUARE_BRACKET 4352u static const uint8_t WUFFS_JSON__LUT_CLASSES[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 0u, 0u, 15u, 15u, 0u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 0u, 15u, 1u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 11u, 2u, 4u, 15u, 12u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 4u, 3u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 11u, 15u, 15u, 15u, 15u, 11u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 7u, 15u, 8u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 9u, 15u, 15u, 11u, 15u, 15u, 15u, 15u, 11u, 15u, 15u, 15u, 15u, 15u, 10u, 15u, 15u, 15u, 15u, 15u, 15u, 5u, 15u, 6u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, 15u, }; static const uint8_t WUFFS_JSON__LUT_DECIMAL_DIGITS[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 128u, 129u, 130u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, }; static const uint8_t WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 128u, 129u, 130u, 131u, 132u, 133u, 134u, 135u, 136u, 137u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 138u, 139u, 140u, 141u, 142u, 143u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 138u, 139u, 140u, 141u, 142u, 143u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, }; #define WUFFS_JSON__QUIRKS_BASE 1225364480u #define WUFFS_JSON__QUIRKS_COUNT 21u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_json__decoder__decode_number( wuffs_json__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_json__decoder__decode_digits( wuffs_json__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_n); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_leading( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_comment( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_inf_nan( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_trailer( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__token_decoder__func_ptrs wuffs_json__decoder__func_ptrs_for__wuffs_base__token_decoder = { (wuffs_base__status(*)(void*, wuffs_base__token_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_json__decoder__decode_tokens), (uint64_t(*)(const void*, uint32_t))(&wuffs_json__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_json__decoder__set_quirk), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_json__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_json__decoder__initialize( wuffs_json__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__token_decoder.vtable_name = wuffs_base__token_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__token_decoder.function_pointers = (const void*)(&wuffs_json__decoder__func_ptrs_for__wuffs_base__token_decoder); return wuffs_base__make_status(NULL); } wuffs_json__decoder* wuffs_json__decoder__alloc(void) { wuffs_json__decoder* x = (wuffs_json__decoder*)(calloc(1, sizeof(wuffs_json__decoder))); if (!x) { return NULL; } if (wuffs_json__decoder__initialize( x, sizeof(wuffs_json__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_json__decoder(void) { return sizeof(wuffs_json__decoder); } // ---------------- Function Implementations // -------- func json.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_json__decoder__get_quirk( const wuffs_json__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } uint32_t v_key = 0; if (a_key >= 1225364480u) { v_key = (a_key - 1225364480u); if (v_key < 21u) { if (self->private_impl.f_quirks[v_key]) { return 1u; } } } return 0u; } // -------- func json.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_json__decoder__set_quirk( wuffs_json__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key >= 1225364480u) { a_key -= 1225364480u; if (a_key < 21u) { self->private_impl.f_quirks[a_key] = (a_value > 0u); return wuffs_base__make_status(NULL); } } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func json.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_json__decoder__workbuf_len( const wuffs_json__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__empty_range_ii_u64(); } // -------- func json.decoder.decode_tokens WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_json__decoder__decode_tokens( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_vminor = 0; uint32_t v_number_length = 0; uint32_t v_number_status = 0; uint32_t v_string_length = 0; uint32_t v_whitespace_length = 0; uint32_t v_depth = 0; uint32_t v_stack_byte = 0; uint32_t v_stack_bit = 0; uint32_t v_match = 0; uint32_t v_c32 = 0; uint8_t v_c8 = 0; uint8_t v_backslash = 0; uint8_t v_char = 0; uint8_t v_class = 0; uint32_t v_multi_byte_utf8 = 0; uint8_t v_backslash_x_ok = 0; uint8_t v_backslash_x_value = 0; uint32_t v_backslash_x_string = 0; uint8_t v_uni4_ok = 0; uint64_t v_uni4_string = 0; uint32_t v_uni4_value = 0; uint32_t v_uni4_high_surrogate = 0; uint8_t v_uni8_ok = 0; uint64_t v_uni8_string = 0; uint32_t v_uni8_value = 0; uint32_t v_expect = 0; uint32_t v_expect_after_value = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_tokens; if (coro_susp_point) { v_depth = self->private_data.s_decode_tokens.v_depth; v_expect = self->private_data.s_decode_tokens.v_expect; v_expect_after_value = self->private_data.s_decode_tokens.v_expect_after_value; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_end_of_data) { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (self->private_impl.f_quirks[18u]) { if (self->private_impl.f_quirks[11u] || self->private_impl.f_quirks[12u] || self->private_impl.f_quirks[17u]) { status = wuffs_base__make_status(wuffs_json__error__bad_quirk_combination); goto exit; } } if (self->private_impl.f_quirks[15u] || self->private_impl.f_quirks[16u]) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_json__decoder__decode_leading(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } v_expect = 7858u; label__outer__continue:; while (true) { while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); goto label__outer__continue; } v_whitespace_length = 0u; v_c8 = 0u; v_class = 0u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (v_whitespace_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_whitespace_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_whitespace_length = 0u; } if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); goto label__outer__continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); v_class = WUFFS_JSON__LUT_CLASSES[v_c8]; if (v_class != 0u) { break; } iop_a_src += 1u; if (v_whitespace_length >= 65534u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(65535u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_whitespace_length = 0u; goto label__outer__continue; } v_whitespace_length += 1u; } if (v_whitespace_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_whitespace_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_whitespace_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__outer__continue; } } if (0u == (v_expect & (((uint32_t)(1u)) << v_class))) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } if (v_class == 1u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194579u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; label__string_loop_outer__continue:; while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); continue; } v_string_length = 0u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; } if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); goto label__string_loop_outer__continue; } while (((uint64_t)(io2_a_src - iop_a_src)) > 4u) { v_c32 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); if (0u != (WUFFS_JSON__LUT_CHARS[(255u & (v_c32 >> 0u))] | WUFFS_JSON__LUT_CHARS[(255u & (v_c32 >> 8u))] | WUFFS_JSON__LUT_CHARS[(255u & (v_c32 >> 16u))] | WUFFS_JSON__LUT_CHARS[(255u & (v_c32 >> 24u))])) { break; } iop_a_src += 4u; if (v_string_length > 65527u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_string_length + 4u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; goto label__string_loop_outer__continue; } v_string_length += 4u; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); v_char = WUFFS_JSON__LUT_CHARS[v_c8]; if (v_char == 0u) { iop_a_src += 1u; if (v_string_length >= 65531u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(65532u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; goto label__string_loop_outer__continue; } v_string_length += 1u; continue; } else if (v_char == 1u) { if (v_string_length != 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; } goto label__string_loop_outer__break; } else if (v_char == 2u) { if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__string_loop_outer__continue; } } if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); goto label__string_loop_outer__continue; } v_c8 = ((uint8_t)(((uint16_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src) >> 8u)))); v_backslash = WUFFS_JSON__LUT_BACKSLASHES[v_c8]; if (((uint8_t)(v_backslash & 128u)) != 0u) { iop_a_src += 2u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | ((uint32_t)(((uint8_t)(v_backslash & 127u))))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } else if (v_backslash != 0u) { if (self->private_impl.f_quirks[WUFFS_JSON__LUT_QUIRKY_BACKSLASHES_QUIRKS[((uint8_t)(v_backslash & 7u))]]) { iop_a_src += 2u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | ((uint32_t)(WUFFS_JSON__LUT_QUIRKY_BACKSLASHES_CHARS[((uint8_t)(v_backslash & 7u))]))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } } else if (v_c8 == 117u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 6u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); goto label__string_loop_outer__continue; } v_uni4_string = (((uint64_t)(wuffs_base__peek_u48le__no_bounds_check(iop_a_src))) >> 16u); v_uni4_value = 0u; v_uni4_ok = 128u; v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 0u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 12u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 8u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 8u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 16u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 4u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 24u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 0u); if (v_uni4_ok == 0u) { } else if ((v_uni4_value < 55296u) || (57343u < v_uni4_value)) { iop_a_src += 6u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | v_uni4_value))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(6u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } else if (v_uni4_value >= 56320u) { } else { if (((uint64_t)(io2_a_src - iop_a_src)) < 12u) { if (a_src && a_src->meta.closed) { if (self->private_impl.f_quirks[20u]) { iop_a_src += 6u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(6u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); goto label__string_loop_outer__continue; } v_uni4_string = (wuffs_base__peek_u64le__no_bounds_check(iop_a_src + 4u) >> 16u); if (((255u & (v_uni4_string >> 0u)) != 92u) || ((255u & (v_uni4_string >> 8u)) != 117u)) { v_uni4_high_surrogate = 0u; v_uni4_value = 0u; v_uni4_ok = 0u; } else { v_uni4_high_surrogate = (65536u + ((v_uni4_value - 55296u) << 10u)); v_uni4_value = 0u; v_uni4_ok = 128u; v_uni4_string >>= 16u; v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 0u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 12u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 8u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 8u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 16u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 4u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni4_string >> 24u))]; v_uni4_ok &= v_c8; v_uni4_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 0u); } if ((v_uni4_ok != 0u) && (56320u <= v_uni4_value) && (v_uni4_value <= 57343u)) { v_uni4_value -= 56320u; iop_a_src += 12u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | v_uni4_high_surrogate | v_uni4_value))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(12u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } } if (self->private_impl.f_quirks[20u]) { if (((uint64_t)(io2_a_src - iop_a_src)) < 6u) { status = wuffs_base__make_status(wuffs_json__error__internal_error_inconsistent_i_o); goto exit; } iop_a_src += 6u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(6u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } } else if ((v_c8 == 85u) && self->private_impl.f_quirks[2u]) { if (((uint64_t)(io2_a_src - iop_a_src)) < 10u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); goto label__string_loop_outer__continue; } v_uni8_string = wuffs_base__peek_u64le__no_bounds_check(iop_a_src + 2u); v_uni8_value = 0u; v_uni8_ok = 128u; v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 0u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 28u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 8u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 24u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 16u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 20u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 24u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 16u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 32u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 12u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 40u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 8u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 48u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 4u); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_uni8_string >> 56u))]; v_uni8_ok &= v_c8; v_uni8_value |= (((uint32_t)(((uint8_t)(v_c8 & 15u)))) << 0u); if (v_uni8_ok == 0u) { } else if ((v_uni8_value < 55296u) || ((57343u < v_uni8_value) && (v_uni8_value <= 1114111u))) { iop_a_src += 10u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | (v_uni8_value & 2097151u)))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(10u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } else if (self->private_impl.f_quirks[20u]) { iop_a_src += 10u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(10u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } } else if ((v_c8 == 120u) && self->private_impl.f_quirks[9u]) { if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); goto label__string_loop_outer__continue; } v_backslash_x_string = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); v_backslash_x_ok = 128u; v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_backslash_x_string >> 16u))]; v_backslash_x_ok &= v_c8; v_backslash_x_value = ((uint8_t)(((uint8_t)(((uint8_t)(v_c8 & 15u)) << 4u)))); v_c8 = WUFFS_JSON__LUT_HEXADECIMAL_DIGITS[(255u & (v_backslash_x_string >> 24u))]; v_backslash_x_ok &= v_c8; v_backslash_x_value = ((uint8_t)(((uint8_t)(v_backslash_x_value | ((uint8_t)(v_c8 & 15u)))))); if ((v_backslash_x_ok == 0u) || ((v_backslash_x_string & 65535u) != 30812u)) { status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } iop_a_src += 4u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | ((uint32_t)(v_backslash_x_value))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_backslash_escape); goto exit; } else if (v_char == 3u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__string_loop_outer__continue; } } if (a_src && a_src->meta.closed) { if (self->private_impl.f_quirks[20u]) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_utf_8); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(11); goto label__string_loop_outer__continue; } v_multi_byte_utf8 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); if ((v_multi_byte_utf8 & 49152u) == 32768u) { v_multi_byte_utf8 = ((1984u & ((uint32_t)(v_multi_byte_utf8 << 6u))) | (63u & (v_multi_byte_utf8 >> 8u))); iop_a_src += 2u; if (v_string_length >= 65528u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_string_length + 2u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; goto label__string_loop_outer__continue; } v_string_length += 2u; continue; } } else if (v_char == 4u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 3u) { if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__string_loop_outer__continue; } } if (a_src && a_src->meta.closed) { if (self->private_impl.f_quirks[20u]) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_utf_8); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(12); goto label__string_loop_outer__continue; } v_multi_byte_utf8 = ((uint32_t)(wuffs_base__peek_u24le__no_bounds_check(iop_a_src))); if ((v_multi_byte_utf8 & 12632064u) == 8421376u) { v_multi_byte_utf8 = ((61440u & ((uint32_t)(v_multi_byte_utf8 << 12u))) | (4032u & (v_multi_byte_utf8 >> 2u)) | (63u & (v_multi_byte_utf8 >> 16u))); if ((2047u < v_multi_byte_utf8) && ((v_multi_byte_utf8 < 55296u) || (57343u < v_multi_byte_utf8))) { iop_a_src += 3u; if (v_string_length >= 65528u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_string_length + 3u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; goto label__string_loop_outer__continue; } v_string_length += 3u; continue; } } } else if (v_char == 5u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__string_loop_outer__continue; } } if (a_src && a_src->meta.closed) { if (self->private_impl.f_quirks[20u]) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_utf_8); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(13); goto label__string_loop_outer__continue; } v_multi_byte_utf8 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); if ((v_multi_byte_utf8 & 3233857536u) == 2155905024u) { v_multi_byte_utf8 = ((1835008u & ((uint32_t)(v_multi_byte_utf8 << 18u))) | (258048u & ((uint32_t)(v_multi_byte_utf8 << 4u))) | (4032u & (v_multi_byte_utf8 >> 10u)) | (63u & (v_multi_byte_utf8 >> 24u))); if ((65535u < v_multi_byte_utf8) && (v_multi_byte_utf8 <= 1114111u)) { iop_a_src += 4u; if (v_string_length >= 65528u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_string_length + 4u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; goto label__string_loop_outer__continue; } v_string_length += 4u; continue; } } } if (v_string_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194819u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_string_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_string_length = 0u; if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { goto label__string_loop_outer__continue; } } if (((uint8_t)(v_char & 128u)) != 0u) { if (self->private_impl.f_quirks[0u]) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((6291456u | ((uint32_t)(((uint8_t)(v_char & 127u))))))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; goto label__string_loop_outer__continue; } if (v_char == 138u) { status = wuffs_base__make_status(wuffs_json__error__bad_new_line_in_a_string); goto exit; } status = wuffs_base__make_status(wuffs_json__error__bad_c0_control_code); goto exit; } if (self->private_impl.f_quirks[20u]) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(6356989u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 1u; goto label__string_loop_outer__continue; } status = wuffs_base__make_status(wuffs_json__error__bad_utf_8); goto exit; } } label__string_loop_outer__break:; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(14); continue; } if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(15); continue; } iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4194579u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); break; } if (0u == (v_expect & (((uint32_t)(1u)) << 4u))) { v_expect = 4104u; goto label__outer__continue; } break; } else if (v_class == 2u) { iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (0u == (v_expect & (((uint32_t)(1u)) << 8u))) { if (self->private_impl.f_quirks[13u]) { v_expect = 4162u; } else { v_expect = 4098u; } } else { if (self->private_impl.f_quirks[13u]) { v_expect = 8114u; } else { v_expect = 7858u; } } goto label__outer__continue; } else if (v_class == 3u) { iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 7858u; goto label__outer__continue; } else if (v_class == 4u) { while (true) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_number_length = wuffs_json__decoder__decode_number(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } v_number_status = (v_number_length >> 8u); v_vminor = 10486787u; if ((v_number_length & 128u) != 0u) { v_vminor = 10486785u; } v_number_length = (v_number_length & 127u); if (v_number_status == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_number_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); break; } while (v_number_length > 0u) { v_number_length -= 1u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { status = wuffs_base__make_status(wuffs_json__error__internal_error_inconsistent_i_o); goto exit; } } if (v_number_status == 1u) { if (self->private_impl.f_quirks[14u]) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); status = wuffs_json__decoder__decode_inf_nan(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } break; } status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } else if (v_number_status == 2u) { status = wuffs_base__make_status(wuffs_json__error__unsupported_number_length); goto exit; } else { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(17); while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(18); } } } break; } else if (v_class == 5u) { v_vminor = 2113553u; if (v_depth == 0u) { } else if (0u != (v_expect_after_value & (((uint32_t)(1u)) << 6u))) { v_vminor = 2113601u; } else { v_vminor = 2113569u; } if (v_depth >= 1024u) { status = wuffs_base__make_status(wuffs_json__error__unsupported_recursion_depth); goto exit; } v_stack_byte = (v_depth / 32u); v_stack_bit = (v_depth & 31u); self->private_data.f_stack[v_stack_byte] |= (((uint32_t)(1u)) << v_stack_bit); v_depth += 1u; iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 4162u; v_expect_after_value = 4164u; goto label__outer__continue; } else if (v_class == 6u) { iop_a_src += 1u; if (v_depth <= 1u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2101314u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__outer__break; } v_depth -= 1u; v_stack_byte = ((v_depth - 1u) / 32u); v_stack_bit = ((v_depth - 1u) & 31u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2105410u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 4356u; v_expect_after_value = 4356u; } else { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2113602u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 4164u; v_expect_after_value = 4164u; } goto label__outer__continue; } else if (v_class == 7u) { v_vminor = 2105361u; if (v_depth == 0u) { } else if (0u != (v_expect_after_value & (((uint32_t)(1u)) << 6u))) { v_vminor = 2105409u; } else { v_vminor = 2105377u; } if (v_depth >= 1024u) { status = wuffs_base__make_status(wuffs_json__error__unsupported_recursion_depth); goto exit; } v_stack_byte = (v_depth / 32u); v_stack_bit = (v_depth & 31u); self->private_data.f_stack[v_stack_byte] &= (4294967295u ^ (((uint32_t)(1u)) << v_stack_bit)); v_depth += 1u; iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(v_vminor)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 8114u; v_expect_after_value = 4356u; goto label__outer__continue; } else if (v_class == 8u) { iop_a_src += 1u; if (v_depth <= 1u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2101282u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); goto label__outer__break; } v_depth -= 1u; v_stack_byte = ((v_depth - 1u) / 32u); v_stack_bit = ((v_depth - 1u) & 31u); if (0u == (self->private_data.f_stack[v_stack_byte] & (((uint32_t)(1u)) << v_stack_bit))) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2105378u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 4356u; v_expect_after_value = 4356u; } else { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2113570u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); v_expect = 4164u; v_expect_after_value = 4164u; } goto label__outer__continue; } else if (v_class == 9u) { v_match = wuffs_private_impl__io_reader__match7(iop_a_src, io2_a_src, a_src, 111546413966853u); if (v_match == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(8388612u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(5u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (((uint64_t)(io2_a_src - iop_a_src)) < 5u) { status = wuffs_base__make_status(wuffs_json__error__internal_error_inconsistent_i_o); goto exit; } iop_a_src += 5u; break; } else if (v_match == 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(19); goto label__outer__continue; } } else if (v_class == 10u) { v_match = wuffs_private_impl__io_reader__match7(iop_a_src, io2_a_src, a_src, 435762131972u); if (v_match == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(8388616u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { status = wuffs_base__make_status(wuffs_json__error__internal_error_inconsistent_i_o); goto exit; } iop_a_src += 4u; break; } else if (v_match == 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(20); goto label__outer__continue; } } else if (v_class == 11u) { v_match = wuffs_private_impl__io_reader__match7(iop_a_src, io2_a_src, a_src, 465676103172u); if (v_match == 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(8388610u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { status = wuffs_base__make_status(wuffs_json__error__internal_error_inconsistent_i_o); goto exit; } iop_a_src += 4u; break; } else if (v_match == 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(21); goto label__outer__continue; } if (self->private_impl.f_quirks[14u]) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(22); status = wuffs_json__decoder__decode_inf_nan(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } break; } } else if (v_class == 12u) { if (self->private_impl.f_quirks[11u] || self->private_impl.f_quirks[12u]) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(23); status = wuffs_json__decoder__decode_comment(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_comment_type > 0u) { goto label__outer__continue; } } } status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } if (v_depth == 0u) { break; } v_expect = v_expect_after_value; } label__outer__break:; if (self->private_impl.f_quirks[17u] || self->private_impl.f_quirks[18u]) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(24); status = wuffs_json__decoder__decode_trailer(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } self->private_impl.f_end_of_data = true; ok: self->private_impl.p_decode_tokens = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_tokens = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; self->private_data.s_decode_tokens.v_depth = v_depth; self->private_data.s_decode_tokens.v_expect = v_expect; self->private_data.s_decode_tokens.v_expect_after_value = v_expect_after_value; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func json.decoder.decode_number WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_json__decoder__decode_number( wuffs_json__decoder* self, wuffs_base__io_buffer* a_src) { uint8_t v_c8 = 0; uint32_t v_n = 0; uint32_t v_floating_point = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } do { v_n = 0u; if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (v_c8 != 45u) { } else { v_n += 1u; iop_a_src += 1u; if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } v_n |= 256u; break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); } if (v_c8 == 48u) { v_n += 1u; iop_a_src += 1u; } else { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_n = wuffs_json__decoder__decode_digits(self, a_src, v_n); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (v_n > 99u) { break; } } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (v_c8 != 46u) { } else { if (v_n >= 99u) { v_n |= 512u; break; } v_n += 1u; iop_a_src += 1u; v_floating_point = 128u; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_n = wuffs_json__decoder__decode_digits(self, a_src, v_n); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (v_n > 99u) { break; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); } if ((v_c8 != 69u) && (v_c8 != 101u)) { break; } if (v_n >= 99u) { v_n |= 512u; break; } v_n += 1u; iop_a_src += 1u; v_floating_point = 128u; if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } v_n |= 256u; break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if ((v_c8 != 43u) && (v_c8 != 45u)) { } else { if (v_n >= 99u) { v_n |= 512u; break; } v_n += 1u; iop_a_src += 1u; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } v_n = wuffs_json__decoder__decode_digits(self, a_src, v_n); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } while (0); if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return (v_n | v_floating_point); } // -------- func json.decoder.decode_digits WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_json__decoder__decode_digits( wuffs_json__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_n) { uint8_t v_c8 = 0; uint32_t v_n = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_n = a_n; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if ( ! (a_src && a_src->meta.closed)) { v_n |= 768u; } break; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (0u == WUFFS_JSON__LUT_DECIMAL_DIGITS[v_c8]) { break; } if (v_n >= 99u) { v_n |= 512u; break; } v_n += 1u; iop_a_src += 1u; } if (v_n == a_n) { v_n |= 256u; } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return v_n; } // -------- func json.decoder.decode_leading WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_leading( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_u = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_leading; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_allow_leading_ars = self->private_impl.f_quirks[15u]; self->private_impl.f_allow_leading_ubom = self->private_impl.f_quirks[16u]; while (self->private_impl.f_allow_leading_ars || self->private_impl.f_allow_leading_ubom) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { break; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if ((v_c8 == 30u) && self->private_impl.f_allow_leading_ars) { self->private_impl.f_allow_leading_ars = false; iop_a_src += 1u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); continue; } else if ((v_c8 == 239u) && self->private_impl.f_allow_leading_ubom) { if (((uint64_t)(io2_a_src - iop_a_src)) < 3u) { if (a_src && a_src->meta.closed) { break; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); continue; } v_u = ((uint32_t)(wuffs_base__peek_u24le__no_bounds_check(iop_a_src))); if (v_u == 12565487u) { self->private_impl.f_allow_leading_ubom = false; iop_a_src += 3u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(3u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); continue; } } break; } ok: self->private_impl.p_decode_leading = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_leading = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func json.decoder.decode_comment WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_comment( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint16_t v_c16 = 0; uint32_t v_length = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_comment; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_comment_type = 0u; while ((((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) || (((uint64_t)(io2_a_src - iop_a_src)) <= 1u)) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(NULL); goto ok; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } v_c16 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); if ((v_c16 == 10799u) && self->private_impl.f_quirks[11u]) { iop_a_src += 2u; v_length = 2u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 1u) { if (v_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); } v_length = 0u; continue; } v_c16 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); if (v_c16 == 12074u) { iop_a_src += 2u; *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)((v_length + 2u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); self->private_impl.f_comment_type = 1u; status = wuffs_base__make_status(NULL); goto ok; } iop_a_src += 1u; if (v_length >= 65533u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(2u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_length + 1u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } v_length = 0u; continue; } v_length += 1u; } } else if ((v_c16 == 12079u) && self->private_impl.f_quirks[12u]) { iop_a_src += 2u; v_length = 2u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); self->private_impl.f_comment_type = 2u; status = wuffs_base__make_status(NULL); goto ok; } else if (v_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)(v_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); } v_length = 0u; continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (v_c8 == 10u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); self->private_impl.f_comment_type = 2u; status = wuffs_base__make_status(NULL); goto ok; } iop_a_src += 1u; if (v_length >= 65533u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(1u)) << WUFFS_BASE__TOKEN__CONTINUED__SHIFT) | (((uint64_t)((v_length + 1u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); } v_length = 0u; continue; } v_length += 1u; } } ok: self->private_impl.p_decode_comment = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_comment = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func json.decoder.decode_inf_nan WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_inf_nan( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; uint32_t v_neg = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_inf_nan; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 2u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); continue; } v_c32 = ((uint32_t)(wuffs_base__peek_u24le__no_bounds_check(iop_a_src))); if ((v_c32 | 2105376u) == 6712937u) { if (((uint64_t)(io2_a_src - iop_a_src)) > 7u) { if ((wuffs_base__peek_u64le__no_bounds_check(iop_a_src) | 2314885530818453536u) == 8751735898823356009u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(10485792u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(8u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 8u; status = wuffs_base__make_status(NULL); goto ok; } } else if ( ! (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); continue; } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(10485792u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(3u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 3u; status = wuffs_base__make_status(NULL); goto ok; } else if ((v_c32 | 2105376u) == 7233902u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(10485888u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(3u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 3u; status = wuffs_base__make_status(NULL); goto ok; } else if ((v_c32 & 255u) == 43u) { v_neg = 0u; } else if ((v_c32 & 255u) == 45u) { v_neg = 1u; } else { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } if (((uint64_t)(io2_a_src - iop_a_src)) <= 3u) { if (a_src && a_src->meta.closed) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); continue; } v_c32 = (wuffs_base__peek_u32le__no_bounds_check(iop_a_src) >> 8u); if ((v_c32 | 2105376u) == 6712937u) { if (((uint64_t)(io2_a_src - iop_a_src)) > 8u) { if ((wuffs_base__peek_u64le__no_bounds_check(iop_a_src + 1u) | 2314885530818453536u) == 8751735898823356009u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((10485760u | (((uint32_t)(32u)) >> v_neg)))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(9u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 9u; status = wuffs_base__make_status(NULL); goto ok; } } else if ( ! (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); continue; } *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((10485760u | (((uint32_t)(32u)) >> v_neg)))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 4u; status = wuffs_base__make_status(NULL); goto ok; } else if ((v_c32 | 2105376u) == 7233902u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)((10485760u | (((uint32_t)(128u)) >> v_neg)))) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(4u)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); iop_a_src += 4u; status = wuffs_base__make_status(NULL); goto ok; } status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } ok: self->private_impl.p_decode_inf_nan = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_inf_nan = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func json.decoder.decode_trailer WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_json__decoder__decode_trailer( wuffs_json__decoder* self, wuffs_base__token_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_whitespace_length = 0; wuffs_base__token* iop_a_dst = NULL; wuffs_base__token* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__token* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_trailer; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_quirks[18u]) { self->private_impl.f_trailer_stop = 10u; } else { self->private_impl.f_trailer_stop = 0u; } label__outer__continue:; while (true) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } v_whitespace_length = 0u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (v_whitespace_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_whitespace_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } if (a_src && a_src->meta.closed) { goto label__outer__break; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); goto label__outer__continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (WUFFS_JSON__LUT_CLASSES[v_c8] != 0u) { if (v_whitespace_length > 0u) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)(v_whitespace_length)) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); } if (self->private_impl.f_trailer_stop > 0u) { status = wuffs_base__make_status(wuffs_json__error__bad_input); goto exit; } if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_json__decoder__decode_comment(self, a_dst, a_src); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_comment_type > 0u) { goto label__outer__continue; } status = wuffs_base__make_status(NULL); goto ok; } iop_a_src += 1u; if ((v_whitespace_length >= 65534u) || (v_c8 == self->private_impl.f_trailer_stop)) { *iop_a_dst++ = wuffs_base__make_token( (((uint64_t)(0u)) << WUFFS_BASE__TOKEN__VALUE_MINOR__SHIFT) | (((uint64_t)((v_whitespace_length + 1u))) << WUFFS_BASE__TOKEN__LENGTH__SHIFT)); if (v_c8 == self->private_impl.f_trailer_stop) { status = wuffs_base__make_status(NULL); goto ok; } goto label__outer__continue; } v_whitespace_length += 1u; } } label__outer__break:; ok: self->private_impl.p_decode_trailer = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_trailer = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JSON) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZMA) // ---------------- Status Codes Implementations const char wuffs_lzma__error__bad_lzma2_header[] = "#lzma: bad LZMA2 header"; const char wuffs_lzma__error__bad_bitstream_trailer[] = "#lzma: bad bitstream trailer"; const char wuffs_lzma__error__bad_code[] = "#lzma: bad code"; const char wuffs_lzma__error__bad_decoded_length[] = "#lzma: bad decoded length"; const char wuffs_lzma__error__bad_distance[] = "#lzma: bad distance"; const char wuffs_lzma__error__bad_header[] = "#lzma: bad header"; const char wuffs_lzma__error__truncated_input[] = "#lzma: truncated input"; const char wuffs_lzma__error__unsupported_decoded_length[] = "#lzma: unsupported decoded length"; const char wuffs_lzma__error__unsupported_properties[] = "#lzma: unsupported properties"; const char wuffs_lzma__error__internal_error_inconsistent_i_o[] = "#lzma: internal error: inconsistent I/O"; const char wuffs_lzma__error__internal_error_inconsistent_dictionary_state[] = "#lzma: internal error: inconsistent dictionary state"; // ---------------- Private Consts static const uint8_t WUFFS_LZMA__STATE_TRANSITION_LITERAL[12] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 1u, 2u, 3u, 4u, 5u, 6u, 4u, 5u, }; static const uint8_t WUFFS_LZMA__STATE_TRANSITION_MATCH[12] WUFFS_BASE__POTENTIALLY_UNUSED = { 7u, 7u, 7u, 7u, 7u, 7u, 7u, 10u, 10u, 10u, 10u, 10u, }; static const uint8_t WUFFS_LZMA__STATE_TRANSITION_LONGREP[12] WUFFS_BASE__POTENTIALLY_UNUSED = { 8u, 8u, 8u, 8u, 8u, 8u, 8u, 11u, 11u, 11u, 11u, 11u, }; static const uint8_t WUFFS_LZMA__STATE_TRANSITION_SHORTREP[12] WUFFS_BASE__POTENTIALLY_UNUSED = { 9u, 9u, 9u, 9u, 9u, 9u, 9u, 11u, 11u, 11u, 11u, 11u, }; static const uint8_t WUFFS_LZMA__CLAMP_NO_MORE_THAN_3[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 1u, 2u, 3u, 3u, 3u, 3u, 3u, }; #define WUFFS_LZMA__QUIRKS_BASE 1348001792u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream_fast( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream_slow( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__add_history( wuffs_lzma__decoder* self, wuffs_base__slice_u8 a_hist, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__do_transform_io( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__update_stashed_bytes( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_optional_end_of_stream( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzma__decoder__initialize_dict( wuffs_lzma__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzma__decoder__initialize_probs( wuffs_lzma__decoder* self); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_lzma__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_lzma__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_lzma__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_lzma__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_lzma__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_lzma__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzma__decoder__initialize( wuffs_lzma__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_lzma__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_lzma__decoder* wuffs_lzma__decoder__alloc(void) { wuffs_lzma__decoder* x = (wuffs_lzma__decoder*)(calloc(1, sizeof(wuffs_lzma__decoder))); if (!x) { return NULL; } if (wuffs_lzma__decoder__initialize( x, sizeof(wuffs_lzma__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_lzma__decoder(void) { return sizeof(wuffs_lzma__decoder); } // ---------------- Function Implementations // -------- func lzma.decoder.decode_bitstream_fast WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream_fast( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_bits = 0; uint32_t v_range = 0; uint32_t v_state = 0; uint32_t v_rep0 = 0; uint32_t v_rep1 = 0; uint32_t v_rep2 = 0; uint32_t v_rep3 = 0; uint32_t v_reptmp = 0; uint32_t v_rep = 0; uint64_t v_pos = 0; uint64_t v_pos_end = 0; uint32_t v_lc = 0; uint64_t v_lp_mask = 0; uint64_t v_pb_mask = 0; uint32_t v_prob = 0; uint32_t v_threshold = 0; uint32_t v_tree_node = 0; uint8_t v_prev_byte = 0; uint32_t v_match_byte = 0; uint32_t v_match_cusp = 0; uint32_t v_len_state = 0; uint32_t v_slot = 0; uint32_t v_len = 0; uint32_t v_lanl_offset = 0; uint32_t v_lanl_old_offset = 0; uint32_t v_lanl_index = 0; uint32_t v_num_extra_bits = 0; uint32_t v_dist_extra_bits = 0; uint32_t v_high_bit_was_on = 0; uint32_t v_i = 0; uint32_t v_index_ao00 = 0; uint32_t v_index_ao41 = 0; uint32_t v_index_lit = 0; uint32_t v_index_len = 0; uint32_t v_index_small_dist_base = 0; uint32_t v_index_small_dist_extra = 0; uint32_t v_index_small_dist = 0; uint32_t v_index_large_dist = 0; uint32_t v_dist = 0; uint32_t v_adj_dist = 0; uint64_t v_wb_index = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_prev_byte = self->private_impl.f_stashed_bytes[0u]; v_match_byte = ((uint32_t)(self->private_impl.f_stashed_bytes[1u])); v_bits = self->private_impl.f_stashed_bits; v_range = self->private_impl.f_stashed_range; v_state = self->private_impl.f_stashed_state; v_rep0 = self->private_impl.f_stashed_rep0; v_rep1 = self->private_impl.f_stashed_rep1; v_rep2 = self->private_impl.f_stashed_rep2; v_rep3 = self->private_impl.f_stashed_rep3; v_pos = self->private_impl.f_stashed_pos; v_pos_end = self->private_impl.f_stashed_pos_end; v_lc = self->private_impl.f_lc; v_lp_mask = ((((uint64_t)(1u)) << self->private_impl.f_lp) - 1u); v_pb_mask = ((((uint64_t)(1u)) << self->private_impl.f_pb) - 1u); while ((((uint64_t)(io2_a_dst - iop_a_dst)) >= 282u) && (((uint64_t)(io2_a_src - iop_a_src)) >= 48u)) { if (v_pos >= v_pos_end) { self->private_impl.f_end_of_chunk = true; break; } v_index_ao00 = ((v_state << 4u) | ((uint32_t)((v_pos & v_pb_mask)))); v_prob = ((uint32_t)(self->private_data.f_probs_ao00[v_index_ao00])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao00[v_index_ao00] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_lit = (15u & ((((uint32_t)((v_pos & v_lp_mask))) << v_lc) | (((uint32_t)(v_prev_byte)) >> (8u - v_lc)))); v_lanl_offset = 0u; if (v_state >= 7u) { v_lanl_offset = 256u; } v_tree_node = 1u; while (v_tree_node < 256u) { v_match_byte <<= 1u; v_lanl_old_offset = v_lanl_offset; v_lanl_offset &= v_match_byte; v_lanl_index = (v_lanl_offset + v_lanl_old_offset + v_tree_node); v_prob = ((uint32_t)(self->private_data.f_probs_lit[v_index_lit][v_lanl_index])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_lanl_offset = ((v_lanl_offset ^ v_lanl_old_offset) & 256u); v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_lit[v_index_lit][v_lanl_index] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_lit[v_index_lit][v_lanl_index] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_prev_byte = ((uint8_t)(v_tree_node)); (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, v_prev_byte), iop_a_dst += 1); v_pos += 1u; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LITERAL[v_state])); continue; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao00[v_index_ao00] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } do { v_prob = ((uint32_t)(self->private_data.f_probs_ao20[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao20[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } do { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_low[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_low[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len_state = ((uint32_t)(WUFFS_LZMA__CLAMP_NO_MORE_THAN_3[(v_tree_node & 7u)])); v_len = ((v_tree_node & 7u) + 2u); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_match_len_mid[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 10u); v_len_state = 3u; break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_tree_node = 1u; while (v_tree_node < 256u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_high[0u][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 255u) + 18u); v_len_state = 3u; } while (0); v_slot = 1u; while (v_slot < 64u) { v_prob = ((uint32_t)(self->private_data.f_probs_slot[v_len_state][v_slot])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_slot[v_len_state][v_slot] = ((uint16_t)(v_prob)); v_slot = (v_slot << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_slot[v_len_state][v_slot] = ((uint16_t)(v_prob)); v_slot = ((v_slot << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_slot &= 63u; v_rep = v_slot; if (v_slot < 4u) { } else if (v_slot < 14u) { v_num_extra_bits = ((v_slot >> 1u) - 1u); v_rep = ((2u | (v_slot & 1u)) << v_num_extra_bits); v_index_small_dist_base = ((uint32_t)(v_rep - v_slot)); v_index_small_dist_extra = 1u; v_dist_extra_bits = 0u; v_i = 0u; while (v_i < v_num_extra_bits) { v_index_small_dist = (((uint32_t)(v_index_small_dist_base + v_index_small_dist_extra)) & 127u); v_prob = ((uint32_t)(self->private_data.f_probs_small_dist[v_index_small_dist])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_small_dist[v_index_small_dist] = ((uint16_t)(v_prob)); v_index_small_dist_extra = ((uint32_t)(v_index_small_dist_extra << 1u)); v_i += 1u; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_small_dist[v_index_small_dist] = ((uint16_t)(v_prob)); v_index_small_dist_extra = (((uint32_t)(v_index_small_dist_extra << 1u)) | 1u); v_dist_extra_bits |= (((uint32_t)(1u)) << v_i); v_i += 1u; } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_rep += v_dist_extra_bits; } else { v_num_extra_bits = ((v_slot >> 1u) - 1u); v_rep = ((2u | (v_slot & 1u)) << v_num_extra_bits); v_dist_extra_bits = 0u; while (true) { v_range >>= 1u; v_bits -= v_range; v_high_bit_was_on = ((uint32_t)(0u - (v_bits >> 31u))); v_bits += (v_range & v_high_bit_was_on); v_dist_extra_bits = (((uint32_t)(v_dist_extra_bits << 1u)) | (((uint32_t)(v_high_bit_was_on + 1u)) & 1u)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_num_extra_bits -= 1u; if (v_num_extra_bits <= 4u) { break; } } v_dist_extra_bits <<= 4u; v_index_large_dist = 1u; while (true) { v_prob = ((uint32_t)(self->private_data.f_probs_large_dist[v_index_large_dist])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_large_dist[v_index_large_dist] = ((uint16_t)(v_prob)); v_index_large_dist = (15u & ((uint32_t)(v_index_large_dist << 1u))); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_large_dist[v_index_large_dist] = ((uint16_t)(v_prob)); v_index_large_dist = (15u & (((uint32_t)(v_index_large_dist << 1u)) | 1u)); v_dist_extra_bits |= (((uint32_t)(1u)) << (4u - v_num_extra_bits)); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_num_extra_bits -= 1u; if (v_num_extra_bits <= 0u) { break; } } v_rep += v_dist_extra_bits; } if (v_rep >= 4294967295u) { self->private_impl.f_end_of_chunk = true; goto label__outer__break; } v_rep3 = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_rep; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_MATCH[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao20[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } v_prob = ((uint32_t)(self->private_data.f_probs_ao40[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao40[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } v_index_ao41 = ((v_state << 4u) | ((uint32_t)((v_pos & v_pb_mask)))); v_prob = ((uint32_t)(self->private_data.f_probs_ao41[v_index_ao41])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao41[v_index_ao41] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_len = 1u; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_SHORTREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao41[v_index_ao41] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao40[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } v_prob = ((uint32_t)(self->private_data.f_probs_ao60[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao60[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao60[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } else { } v_prob = ((uint32_t)(self->private_data.f_probs_ao63[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao63[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao63[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep3; v_rep3 = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } } } do { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_low[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 2u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_mid[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 10u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_tree_node = 1u; while (v_tree_node < 256u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_high[0u][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_i_o); goto exit; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 255u) + 18u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); } while (0); } while (0); v_dist = (v_rep0 + 1u); if ((((uint64_t)(v_dist)) > v_pos) || (((uint64_t)(v_dist)) > ((uint64_t)(self->private_impl.f_dict_size)))) { status = wuffs_base__make_status(wuffs_lzma__error__bad_distance); goto exit; } v_pos += ((uint64_t)(v_len)); if (((uint64_t)(v_dist)) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_adj_dist = ((uint32_t)((((uint64_t)(v_dist)) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_adj_dist > self->private_impl.f_dict_seen) { status = wuffs_base__make_status(wuffs_lzma__error__bad_distance); goto exit; } v_wb_index = ((uint64_t)(((uint64_t)(self->private_impl.f_dict_workbuf_index)) - ((uint64_t)(v_adj_dist)))); while (v_wb_index >= 9223372036854775808u) { v_wb_index += ((uint64_t)(self->private_impl.f_dict_size)); } if (v_wb_index >= ((uint64_t)(a_workbuf.len))) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } if (v_len < v_adj_dist) { wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,(v_len + 1u), wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_match_byte = ((uint32_t)(iop_a_dst[-1])); iop_a_dst--; if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_prev_byte = iop_a_dst[-1]; continue; } else if (v_len == v_adj_dist) { wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_len, wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); wuffs_private_impl__io_writer__limited_copy_u32_from_history( &iop_a_dst, io0_a_dst, io2_a_dst, 1u, v_dist); if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_match_byte = ((uint32_t)(iop_a_dst[-1])); iop_a_dst--; if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_prev_byte = iop_a_dst[-1]; continue; } wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_adj_dist, wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); v_len -= v_adj_dist; if ((((uint64_t)(v_len)) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)((v_len + 8u))) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)(v_dist)) > ((uint64_t)(iop_a_dst - io0_a_dst)))) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } } if (v_dist >= 8u) { v_match_cusp = wuffs_private_impl__io_writer__limited_copy_u32_from_history_8_byte_chunks_fast_return_cusp( &iop_a_dst, io0_a_dst, io2_a_dst, v_len, v_dist); v_match_byte = (v_match_cusp >> 8u); v_prev_byte = ((uint8_t)(v_match_cusp)); } else { v_match_cusp = wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast_return_cusp( &iop_a_dst, io0_a_dst, io2_a_dst, v_len, v_dist); v_match_byte = (v_match_cusp >> 8u); v_prev_byte = ((uint8_t)(v_match_cusp)); } } label__outer__break:; self->private_impl.f_stashed_bytes[0u] = v_prev_byte; self->private_impl.f_stashed_bytes[1u] = ((uint8_t)(v_match_byte)); self->private_impl.f_stashed_bits = v_bits; self->private_impl.f_stashed_range = v_range; self->private_impl.f_stashed_state = v_state; self->private_impl.f_stashed_rep0 = v_rep0; self->private_impl.f_stashed_rep1 = v_rep1; self->private_impl.f_stashed_rep2 = v_rep2; self->private_impl.f_stashed_rep3 = v_rep3; self->private_impl.f_stashed_pos = v_pos; self->private_impl.f_stashed_pos_end = v_pos_end; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func lzma.decoder.decode_bitstream_slow WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream_slow( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_bits = 0; uint32_t v_range = 0; uint32_t v_state = 0; uint32_t v_rep0 = 0; uint32_t v_rep1 = 0; uint32_t v_rep2 = 0; uint32_t v_rep3 = 0; uint32_t v_reptmp = 0; uint32_t v_rep = 0; uint64_t v_pos = 0; uint64_t v_pos_end = 0; uint32_t v_lc = 0; uint64_t v_lp_mask = 0; uint64_t v_pb_mask = 0; uint32_t v_prob = 0; uint32_t v_threshold = 0; uint32_t v_tree_node = 0; uint8_t v_prev_byte = 0; uint32_t v_match_byte = 0; uint32_t v_match_cusp = 0; uint32_t v_len_state = 0; uint32_t v_slot = 0; uint32_t v_len = 0; uint32_t v_lanl_offset = 0; uint32_t v_lanl_old_offset = 0; uint32_t v_lanl_index = 0; uint32_t v_num_extra_bits = 0; uint32_t v_dist_extra_bits = 0; uint32_t v_high_bit_was_on = 0; uint32_t v_i = 0; uint32_t v_index_ao00 = 0; uint32_t v_index_ao41 = 0; uint32_t v_index_lit = 0; uint32_t v_index_len = 0; uint32_t v_index_small_dist_base = 0; uint32_t v_index_small_dist_extra = 0; uint32_t v_index_small_dist = 0; uint32_t v_index_large_dist = 0; uint32_t v_dist = 0; uint32_t v_adj_dist = 0; uint64_t v_wb_index = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_bitstream_slow; if (coro_susp_point) { v_bits = self->private_data.s_decode_bitstream_slow.v_bits; v_range = self->private_data.s_decode_bitstream_slow.v_range; v_state = self->private_data.s_decode_bitstream_slow.v_state; v_rep0 = self->private_data.s_decode_bitstream_slow.v_rep0; v_rep1 = self->private_data.s_decode_bitstream_slow.v_rep1; v_rep2 = self->private_data.s_decode_bitstream_slow.v_rep2; v_rep3 = self->private_data.s_decode_bitstream_slow.v_rep3; v_rep = self->private_data.s_decode_bitstream_slow.v_rep; v_pos = self->private_data.s_decode_bitstream_slow.v_pos; v_pos_end = self->private_data.s_decode_bitstream_slow.v_pos_end; v_lc = self->private_data.s_decode_bitstream_slow.v_lc; v_lp_mask = self->private_data.s_decode_bitstream_slow.v_lp_mask; v_pb_mask = self->private_data.s_decode_bitstream_slow.v_pb_mask; v_tree_node = self->private_data.s_decode_bitstream_slow.v_tree_node; v_prev_byte = self->private_data.s_decode_bitstream_slow.v_prev_byte; v_match_byte = self->private_data.s_decode_bitstream_slow.v_match_byte; v_len_state = self->private_data.s_decode_bitstream_slow.v_len_state; v_slot = self->private_data.s_decode_bitstream_slow.v_slot; v_len = self->private_data.s_decode_bitstream_slow.v_len; v_lanl_offset = self->private_data.s_decode_bitstream_slow.v_lanl_offset; v_num_extra_bits = self->private_data.s_decode_bitstream_slow.v_num_extra_bits; v_dist_extra_bits = self->private_data.s_decode_bitstream_slow.v_dist_extra_bits; v_i = self->private_data.s_decode_bitstream_slow.v_i; v_index_lit = self->private_data.s_decode_bitstream_slow.v_index_lit; v_index_len = self->private_data.s_decode_bitstream_slow.v_index_len; v_index_small_dist_base = self->private_data.s_decode_bitstream_slow.v_index_small_dist_base; v_index_small_dist_extra = self->private_data.s_decode_bitstream_slow.v_index_small_dist_extra; v_index_large_dist = self->private_data.s_decode_bitstream_slow.v_index_large_dist; v_dist = self->private_data.s_decode_bitstream_slow.v_dist; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_prev_byte = self->private_impl.f_stashed_bytes[0u]; v_match_byte = ((uint32_t)(self->private_impl.f_stashed_bytes[1u])); v_bits = self->private_impl.f_stashed_bits; v_range = self->private_impl.f_stashed_range; v_state = self->private_impl.f_stashed_state; v_rep0 = self->private_impl.f_stashed_rep0; v_rep1 = self->private_impl.f_stashed_rep1; v_rep2 = self->private_impl.f_stashed_rep2; v_rep3 = self->private_impl.f_stashed_rep3; v_pos = self->private_impl.f_stashed_pos; v_pos_end = self->private_impl.f_stashed_pos_end; v_lc = self->private_impl.f_lc; v_lp_mask = ((((uint64_t)(1u)) << self->private_impl.f_lp) - 1u); v_pb_mask = ((((uint64_t)(1u)) << self->private_impl.f_pb) - 1u); while ( ! (self->private_impl.p_decode_bitstream_slow != 0)) { if (v_pos >= v_pos_end) { self->private_impl.f_end_of_chunk = true; break; } v_index_ao00 = ((v_state << 4u) | ((uint32_t)((v_pos & v_pb_mask)))); v_prob = ((uint32_t)(self->private_data.f_probs_ao00[v_index_ao00])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao00[v_index_ao00] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_lit = (15u & ((((uint32_t)((v_pos & v_lp_mask))) << v_lc) | (((uint32_t)(v_prev_byte)) >> (8u - v_lc)))); if (v_state >= 7u) { v_lanl_offset = 256u; v_tree_node = 1u; while (v_tree_node < 256u) { v_match_byte <<= 1u; v_lanl_old_offset = v_lanl_offset; v_lanl_offset &= v_match_byte; v_lanl_index = (v_lanl_offset + v_lanl_old_offset + v_tree_node); v_prob = ((uint32_t)(self->private_data.f_probs_lit[v_index_lit][v_lanl_index])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_lanl_offset = ((v_lanl_offset ^ v_lanl_old_offset) & 256u); v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_lit[v_index_lit][v_lanl_index] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_lit[v_index_lit][v_lanl_index] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } } else { v_tree_node = 1u; while (v_tree_node < 256u) { v_prob = ((uint32_t)(self->private_data.f_probs_lit[v_index_lit][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_lit[v_index_lit][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_lit[v_index_lit][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } } v_prev_byte = ((uint8_t)(v_tree_node)); self->private_data.s_decode_bitstream_slow.scratch = v_prev_byte; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (iop_a_dst == io2_a_dst) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); goto suspend; } *iop_a_dst++ = ((uint8_t)(self->private_data.s_decode_bitstream_slow.scratch)); v_pos += 1u; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LITERAL[v_state])); continue; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao00[v_index_ao00] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } do { v_prob = ((uint32_t)(self->private_data.f_probs_ao20[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao20[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } do { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_low[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_low[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len_state = ((uint32_t)(WUFFS_LZMA__CLAMP_NO_MORE_THAN_3[(v_tree_node & 7u)])); v_len = ((v_tree_node & 7u) + 2u); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_7 = *iop_a_src++; v_c8 = t_7; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_match_len_mid[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; v_c8 = t_8; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_9 = *iop_a_src++; v_c8 = t_9; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 10u); v_len_state = 3u; break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_10 = *iop_a_src++; v_c8 = t_10; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_tree_node = 1u; while (v_tree_node < 256u) { v_prob = ((uint32_t)(self->private_data.f_probs_match_len_high[0u][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_match_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_match_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_11 = *iop_a_src++; v_c8 = t_11; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 255u) + 18u); v_len_state = 3u; } while (0); v_slot = 1u; while (v_slot < 64u) { v_prob = ((uint32_t)(self->private_data.f_probs_slot[v_len_state][v_slot])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_slot[v_len_state][v_slot] = ((uint16_t)(v_prob)); v_slot = (v_slot << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_slot[v_len_state][v_slot] = ((uint16_t)(v_prob)); v_slot = ((v_slot << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_12 = *iop_a_src++; v_c8 = t_12; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_slot &= 63u; v_rep = v_slot; if (v_slot < 4u) { } else if (v_slot < 14u) { v_num_extra_bits = ((v_slot >> 1u) - 1u); v_rep = ((2u | (v_slot & 1u)) << v_num_extra_bits); v_index_small_dist_base = ((uint32_t)(v_rep - v_slot)); v_index_small_dist_extra = 1u; v_dist_extra_bits = 0u; v_i = 0u; while (v_i < v_num_extra_bits) { v_index_small_dist = (((uint32_t)(v_index_small_dist_base + v_index_small_dist_extra)) & 127u); v_prob = ((uint32_t)(self->private_data.f_probs_small_dist[v_index_small_dist])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_small_dist[v_index_small_dist] = ((uint16_t)(v_prob)); v_index_small_dist_extra = ((uint32_t)(v_index_small_dist_extra << 1u)); v_i += 1u; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_small_dist[v_index_small_dist] = ((uint16_t)(v_prob)); v_index_small_dist_extra = (((uint32_t)(v_index_small_dist_extra << 1u)) | 1u); v_dist_extra_bits |= (((uint32_t)(1u)) << v_i); v_i += 1u; } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_13 = *iop_a_src++; v_c8 = t_13; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_rep += v_dist_extra_bits; } else { v_num_extra_bits = ((v_slot >> 1u) - 1u); v_rep = ((2u | (v_slot & 1u)) << v_num_extra_bits); v_dist_extra_bits = 0u; while (true) { v_range >>= 1u; v_bits -= v_range; v_high_bit_was_on = ((uint32_t)(0u - (v_bits >> 31u))); v_bits += (v_range & v_high_bit_was_on); v_dist_extra_bits = (((uint32_t)(v_dist_extra_bits << 1u)) | (((uint32_t)(v_high_bit_was_on + 1u)) & 1u)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_14 = *iop_a_src++; v_c8 = t_14; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_num_extra_bits -= 1u; if (v_num_extra_bits <= 4u) { break; } } v_dist_extra_bits <<= 4u; v_index_large_dist = 1u; while (true) { v_prob = ((uint32_t)(self->private_data.f_probs_large_dist[v_index_large_dist])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_large_dist[v_index_large_dist] = ((uint16_t)(v_prob)); v_index_large_dist = (15u & ((uint32_t)(v_index_large_dist << 1u))); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_large_dist[v_index_large_dist] = ((uint16_t)(v_prob)); v_index_large_dist = (15u & (((uint32_t)(v_index_large_dist << 1u)) | 1u)); v_dist_extra_bits |= (((uint32_t)(1u)) << (4u - v_num_extra_bits)); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(17); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_15 = *iop_a_src++; v_c8 = t_15; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_num_extra_bits -= 1u; if (v_num_extra_bits <= 0u) { break; } } v_rep += v_dist_extra_bits; } if (v_rep >= 4294967295u) { self->private_impl.f_end_of_chunk = true; goto label__outer__break; } v_rep3 = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_rep; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_MATCH[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao20[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(18); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_16 = *iop_a_src++; v_c8 = t_16; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_ao40[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao40[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(19); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_17 = *iop_a_src++; v_c8 = t_17; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_ao41 = ((v_state << 4u) | ((uint32_t)((v_pos & v_pb_mask)))); v_prob = ((uint32_t)(self->private_data.f_probs_ao41[v_index_ao41])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao41[v_index_ao41] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(20); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_18 = *iop_a_src++; v_c8 = t_18; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_len = 1u; v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_SHORTREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao41[v_index_ao41] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(21); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_19 = *iop_a_src++; v_c8 = t_19; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao40[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(22); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_20 = *iop_a_src++; v_c8 = t_20; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_ao60[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao60[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(23); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_21 = *iop_a_src++; v_c8 = t_21; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao60[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(24); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_22 = *iop_a_src++; v_c8 = t_22; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_ao63[v_state])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_ao63[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(25); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_23 = *iop_a_src++; v_c8 = t_23; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_ao63[v_state] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(26); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_24 = *iop_a_src++; v_c8 = t_24; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_reptmp = v_rep3; v_rep3 = v_rep2; v_rep2 = v_rep1; v_rep1 = v_rep0; v_rep0 = v_reptmp; } } } do { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_low[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(27); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_25 = *iop_a_src++; v_c8 = t_25; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_low[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(28); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_26 = *iop_a_src++; v_c8 = t_26; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 2u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_low[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(29); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_27 = *iop_a_src++; v_c8 = t_27; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_mid[0u][0u])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(30); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_28 = *iop_a_src++; v_c8 = t_28; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_index_len = ((uint32_t)((v_pos & v_pb_mask))); v_tree_node = 1u; while (v_tree_node < 8u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_mid[v_index_len][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(31); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_29 = *iop_a_src++; v_c8 = t_29; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 7u) + 10u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); break; } v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_mid[0u][0u] = ((uint16_t)(v_prob)); if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(32); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_30 = *iop_a_src++; v_c8 = t_30; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } v_tree_node = 1u; while (v_tree_node < 256u) { v_prob = ((uint32_t)(self->private_data.f_probs_longrep_len_high[0u][v_tree_node])); v_threshold = ((uint32_t)((v_range >> 11u) * v_prob)); if (v_bits < v_threshold) { v_range = v_threshold; v_prob += (((uint32_t)(2048u - v_prob)) >> 5u); self->private_data.f_probs_longrep_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = (v_tree_node << 1u); } else { v_bits -= v_threshold; v_range -= v_threshold; v_prob -= (v_prob >> 5u); self->private_data.f_probs_longrep_len_high[0u][v_tree_node] = ((uint16_t)(v_prob)); v_tree_node = ((v_tree_node << 1u) | 1u); } if ((v_range >> 24u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(33); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_31 = *iop_a_src++; v_c8 = t_31; } v_bits = (((uint32_t)(v_bits << 8u)) | ((uint32_t)(v_c8))); v_range <<= 8u; } } v_len = ((v_tree_node & 255u) + 18u); v_state = ((uint32_t)(WUFFS_LZMA__STATE_TRANSITION_LONGREP[v_state])); } while (0); } while (0); v_dist = (v_rep0 + 1u); if ((((uint64_t)(v_dist)) > v_pos) || (((uint64_t)(v_dist)) > ((uint64_t)(self->private_impl.f_dict_size)))) { status = wuffs_base__make_status(wuffs_lzma__error__bad_distance); goto exit; } v_pos += ((uint64_t)(v_len)); while (274u > ((uint64_t)(io2_a_dst - iop_a_dst))) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(34); } if (((uint64_t)(v_dist)) > ((uint64_t)(iop_a_dst - io0_a_dst))) { v_adj_dist = ((uint32_t)((((uint64_t)(v_dist)) - ((uint64_t)(iop_a_dst - io0_a_dst))))); if (v_adj_dist > self->private_impl.f_dict_seen) { status = wuffs_base__make_status(wuffs_lzma__error__bad_distance); goto exit; } v_wb_index = ((uint64_t)(((uint64_t)(self->private_impl.f_dict_workbuf_index)) - ((uint64_t)(v_adj_dist)))); while (v_wb_index >= 9223372036854775808u) { v_wb_index += ((uint64_t)(self->private_impl.f_dict_size)); } if (v_wb_index >= ((uint64_t)(a_workbuf.len))) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } if (v_len < v_adj_dist) { wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,(v_len + 1u), wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_match_byte = ((uint32_t)(iop_a_dst[-1])); iop_a_dst--; if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_prev_byte = iop_a_dst[-1]; continue; } else if (v_len == v_adj_dist) { wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_len, wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); wuffs_private_impl__io_writer__limited_copy_u32_from_history( &iop_a_dst, io0_a_dst, io2_a_dst, 1u, v_dist); if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_match_byte = ((uint32_t)(iop_a_dst[-1])); iop_a_dst--; if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } v_prev_byte = iop_a_dst[-1]; continue; } wuffs_private_impl__io_writer__limited_copy_u32_from_slice( &iop_a_dst, io2_a_dst,v_adj_dist, wuffs_base__slice_u8__subslice_i(a_workbuf, v_wb_index)); v_len -= v_adj_dist; if ((((uint64_t)(v_len)) > ((uint64_t)(io2_a_dst - iop_a_dst))) || (((uint64_t)(v_dist)) > ((uint64_t)(iop_a_dst - io0_a_dst)))) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } } v_match_cusp = wuffs_private_impl__io_writer__limited_copy_u32_from_history_fast_return_cusp( &iop_a_dst, io0_a_dst, io2_a_dst, v_len, v_dist); v_match_byte = (v_match_cusp >> 8u); v_prev_byte = ((uint8_t)(v_match_cusp)); } label__outer__break:; self->private_impl.f_stashed_bytes[0u] = v_prev_byte; self->private_impl.f_stashed_bytes[1u] = ((uint8_t)(v_match_byte)); self->private_impl.f_stashed_bits = v_bits; self->private_impl.f_stashed_range = v_range; self->private_impl.f_stashed_state = v_state; self->private_impl.f_stashed_rep0 = v_rep0; self->private_impl.f_stashed_rep1 = v_rep1; self->private_impl.f_stashed_rep2 = v_rep2; self->private_impl.f_stashed_rep3 = v_rep3; self->private_impl.f_stashed_pos = v_pos; self->private_impl.f_stashed_pos_end = v_pos_end; ok: self->private_impl.p_decode_bitstream_slow = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_bitstream_slow = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_bitstream_slow.v_bits = v_bits; self->private_data.s_decode_bitstream_slow.v_range = v_range; self->private_data.s_decode_bitstream_slow.v_state = v_state; self->private_data.s_decode_bitstream_slow.v_rep0 = v_rep0; self->private_data.s_decode_bitstream_slow.v_rep1 = v_rep1; self->private_data.s_decode_bitstream_slow.v_rep2 = v_rep2; self->private_data.s_decode_bitstream_slow.v_rep3 = v_rep3; self->private_data.s_decode_bitstream_slow.v_rep = v_rep; self->private_data.s_decode_bitstream_slow.v_pos = v_pos; self->private_data.s_decode_bitstream_slow.v_pos_end = v_pos_end; self->private_data.s_decode_bitstream_slow.v_lc = v_lc; self->private_data.s_decode_bitstream_slow.v_lp_mask = v_lp_mask; self->private_data.s_decode_bitstream_slow.v_pb_mask = v_pb_mask; self->private_data.s_decode_bitstream_slow.v_tree_node = v_tree_node; self->private_data.s_decode_bitstream_slow.v_prev_byte = v_prev_byte; self->private_data.s_decode_bitstream_slow.v_match_byte = v_match_byte; self->private_data.s_decode_bitstream_slow.v_len_state = v_len_state; self->private_data.s_decode_bitstream_slow.v_slot = v_slot; self->private_data.s_decode_bitstream_slow.v_len = v_len; self->private_data.s_decode_bitstream_slow.v_lanl_offset = v_lanl_offset; self->private_data.s_decode_bitstream_slow.v_num_extra_bits = v_num_extra_bits; self->private_data.s_decode_bitstream_slow.v_dist_extra_bits = v_dist_extra_bits; self->private_data.s_decode_bitstream_slow.v_i = v_i; self->private_data.s_decode_bitstream_slow.v_index_lit = v_index_lit; self->private_data.s_decode_bitstream_slow.v_index_len = v_index_len; self->private_data.s_decode_bitstream_slow.v_index_small_dist_base = v_index_small_dist_base; self->private_data.s_decode_bitstream_slow.v_index_small_dist_extra = v_index_small_dist_extra; self->private_data.s_decode_bitstream_slow.v_index_large_dist = v_index_large_dist; self->private_data.s_decode_bitstream_slow.v_dist = v_dist; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func lzma.decoder.add_history WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__add_history( wuffs_lzma__decoder* self, wuffs_base__slice_u8 a_hist, wuffs_base__slice_u8 a_workbuf) { uint64_t v_dict_workbuf_index = 0; uint64_t v_dict_size = 0; uint64_t v_hist_length = 0; wuffs_base__slice_u8 v_s = {0}; uint64_t v_n_copied = 0; uint64_t v_n = 0; v_dict_workbuf_index = ((uint64_t)(self->private_impl.f_dict_workbuf_index)); v_dict_size = ((uint64_t)(self->private_impl.f_dict_size)); if (((uint64_t)(a_hist.len)) == 0u) { return wuffs_base__make_status(NULL); } if (((uint64_t)(a_workbuf.len)) < (v_dict_size + 273u)) { return wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); } v_hist_length = ((uint64_t)(a_hist.len)); if (v_hist_length > 4294967295u) { self->private_impl.f_dict_seen = 4294967295u; } else { wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dict_seen, ((uint32_t)(v_hist_length))); } v_s = a_hist; if (((uint64_t)(v_s.len)) >= v_dict_size) { v_s = wuffs_private_impl__slice_u8__suffix(v_s, v_dict_size); wuffs_private_impl__slice_u8__copy_from_slice(a_workbuf, v_s); self->private_impl.f_dict_workbuf_index = 0u; } else if (v_dict_workbuf_index > v_dict_size) { return wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); } else { v_n_copied = wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__slice_u8__subslice_ij(a_workbuf, v_dict_workbuf_index, v_dict_size), v_s); if (v_n_copied < ((uint64_t)(v_s.len))) { v_n = wuffs_private_impl__slice_u8__copy_from_slice(a_workbuf, wuffs_base__slice_u8__subslice_i(v_s, v_n_copied)); self->private_impl.f_dict_workbuf_index = ((uint32_t)(v_n)); } else { v_n = ((uint64_t)(v_dict_workbuf_index + v_n_copied)); if (v_n < v_dict_size) { self->private_impl.f_dict_workbuf_index = ((uint32_t)(v_n)); } else { self->private_impl.f_dict_workbuf_index = 0u; } } } if ((273u > v_dict_size) || (v_dict_size > ((uint64_t)(a_workbuf.len)))) { return wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); } wuffs_private_impl__slice_u8__copy_from_slice(wuffs_base__slice_u8__subslice_i(a_workbuf, v_dict_size), wuffs_base__slice_u8__subslice_j(a_workbuf, 273u)); return wuffs_base__make_status(NULL); } // -------- func lzma.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzma__decoder__get_quirk( const wuffs_lzma__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (a_key == 1348001792u) { if (self->private_impl.f_allow_non_zero_initial_byte) { return 1u; } } else if (a_key == 1348001793u) { return ((uint64_t)(self->private_impl.f_format_extension)); } return 0u; } // -------- func lzma.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzma__decoder__set_quirk( wuffs_lzma__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } uint32_t v_v = 0; uint32_t v_n = 0; if (a_key == 1348001792u) { self->private_impl.f_allow_non_zero_initial_byte = (a_value > 0u); } else if (a_key == 1348001793u) { if (a_value == 0u) { self->private_impl.f_format_extension = 0u; return wuffs_base__make_status(NULL); } else if ((a_value & 255u) == 1u) { if ((a_value >> 8u) <= 255u) { self->private_impl.f_format_extension = ((uint32_t)(a_value)); v_v = (self->private_impl.f_format_extension >> 8u); v_n = (((uint32_t)(1u)) << (v_v & 31u)); wuffs_private_impl__u32__sat_sub_indirect(&v_n, ((v_n >> 4u) * ((v_v >> 5u) & 7u))); if ((v_n < 4096u) || (536870912u < v_n)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_dict_size = v_n; return wuffs_base__make_status(NULL); } } else if ((a_value & 255u) == 2u) { if ((a_value >> 8u) <= 40u) { self->private_impl.f_format_extension = ((uint32_t)(a_value)); v_v = (self->private_impl.f_format_extension >> 8u); if (v_v < 40u) { self->private_impl.f_dict_size = ((2u | (v_v & 1u)) << ((v_v >> 1u) + 11u)); } else { self->private_impl.f_dict_size = 4294967295u; } return wuffs_base__make_status(NULL); } } return wuffs_base__make_status(wuffs_base__error__bad_argument); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func lzma.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzma__decoder__dst_history_retain_length( const wuffs_lzma__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func lzma.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzma__decoder__workbuf_len( const wuffs_lzma__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } uint64_t v_m = 0; if (self->private_impl.f_dict_size == 0u) { return wuffs_base__utility__make_range_ii_u64(0u, 0u); } v_m = (((uint64_t)(self->private_impl.f_dict_size)) + 273u); return wuffs_base__utility__make_range_ii_u64(v_m, v_m); } // -------- func lzma.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzma__decoder__transform_io( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_mark = 0; wuffs_base__status v_dti_status = wuffs_base__make_status(NULL); wuffs_base__status v_ah_status = wuffs_base__make_status(NULL); uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { v_mark = ((uint64_t)(iop_a_dst - io0_a_dst)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } wuffs_base__status t_0 = wuffs_lzma__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_dti_status = t_0; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } } if ( ! wuffs_base__status__is_suspension(&v_dti_status)) { status = v_dti_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } else if ((v_dti_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_lzma__error__truncated_input); goto exit; } v_ah_status = wuffs_lzma__decoder__add_history(self, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst), a_workbuf); if (wuffs_base__status__is_error(&v_ah_status)) { status = v_ah_status; goto exit; } status = v_dti_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func lzma.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__do_transform_io( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_header_byte = 0; uint8_t v_c8 = 0; uint32_t v_c32 = 0; uint8_t v_prop_byte = 0; uint32_t v_lc = 0; uint32_t v_lp = 0; uint32_t v_pb = 0; uint32_t v_length = 0; uint32_t v_n_copied = 0; uint64_t v_smark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; if (coro_susp_point) { v_header_byte = self->private_data.s_do_transform_io.v_header_byte; v_length = self->private_data.s_do_transform_io.v_length; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_lzma2_need_prob_reset = true; self->private_impl.f_lzma2_need_properties = true; self->private_impl.f_lzma2_need_dict_reset = true; while (true) { if ((self->private_impl.f_format_extension & 255u) == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_prop_byte = t_0; } if (v_prop_byte >= 225u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_header); goto exit; } v_lc = ((uint32_t)(((uint8_t)(v_prop_byte % 9u)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_prop_byte /= 9u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_lp = ((uint32_t)(((uint8_t)(v_prop_byte % 5u)))); v_pb = ((uint32_t)(((uint8_t)(v_prop_byte / 5u)))); if ((v_lc + v_lp) > 4u) { status = wuffs_base__make_status(wuffs_lzma__error__unsupported_properties); goto exit; } self->private_impl.f_lc = wuffs_base__u32__min(v_lc, 4u); self->private_impl.f_lp = v_lp; self->private_impl.f_pb = v_pb; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_c32 = t_1; } self->private_impl.f_dict_size = wuffs_base__u32__max(v_c32, 4096u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint64_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_2 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 56) { t_2 = ((uint64_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } self->private_impl.f_decoded_length = t_2; } if ((self->private_impl.f_decoded_length >= 9223372036854775808u) && (self->private_impl.f_decoded_length != 18446744073709551615u)) { status = wuffs_base__make_status(wuffs_lzma__error__unsupported_decoded_length); goto exit; } wuffs_lzma__decoder__initialize_probs(self); } else if ((self->private_impl.f_format_extension & 255u) == 1u) { self->private_impl.f_lc = 3u; self->private_impl.f_lp = 0u; self->private_impl.f_pb = 2u; self->private_impl.f_decoded_length = 18446744073709551615u; wuffs_lzma__decoder__initialize_probs(self); } else { while (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); } if (wuffs_base__peek_u8be__no_bounds_check(iop_a_src) == 0u) { iop_a_src += 1u; break; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_header_byte = t_3; } if (v_header_byte < 128u) { if (v_header_byte < 2u) { self->private_impl.f_lzma2_need_prob_reset = true; self->private_impl.f_lzma2_need_properties = true; self->private_impl.f_lzma2_need_dict_reset = false; wuffs_lzma__decoder__initialize_dict(self); } else if ((v_header_byte > 2u) || self->private_impl.f_lzma2_need_dict_reset) { status = wuffs_base__make_status(wuffs_lzma__error__bad_lzma2_header); goto exit; } self->private_impl.f_prev_lzma2_chunk_was_uncompressed = true; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_4); if (num_bits_4 == 8) { t_4 = ((uint32_t)(*scratch >> 48)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)); } } v_c32 = t_4; } v_length = (1u + v_c32); while (true) { v_n_copied = wuffs_private_impl__io_writer__limited_copy_u32_from_reader( &iop_a_dst, io2_a_dst,v_length, &iop_a_src, io2_a_src); wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_stashed_pos, ((uint64_t)(v_n_copied))); if (v_length <= v_n_copied) { break; } v_length -= v_n_copied; if (((uint64_t)(io2_a_dst - iop_a_dst)) == 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); } else { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(11); } } continue; } self->private_impl.f_decoded_length = ((uint64_t)(v_header_byte)); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); uint32_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_5 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_5); if (num_bits_5 == 8) { t_5 = ((uint32_t)(*scratch >> 48)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)); } } v_c32 = t_5; } self->private_impl.f_decoded_length = (((self->private_impl.f_decoded_length & 31u) << 16u) + ((uint64_t)((1u + v_c32)))); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); uint32_t t_6; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_6 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_6 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_6); if (num_bits_6 == 8) { t_6 = ((uint32_t)(*scratch >> 48)); break; } num_bits_6 += 8u; *scratch |= ((uint64_t)(num_bits_6)); } } v_c32 = t_6; } self->private_impl.f_lzma2_encoded_length_want = ((uint64_t)((1u + v_c32))); if (v_header_byte >= 160u) { wuffs_lzma__decoder__initialize_probs(self); self->private_impl.f_lzma2_need_prob_reset = false; } if (v_header_byte >= 192u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_7 = *iop_a_src++; v_prop_byte = t_7; } if (v_prop_byte >= 225u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_lzma2_header); goto exit; } v_lc = ((uint32_t)(((uint8_t)(v_prop_byte % 9u)))); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_prop_byte /= 9u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_lp = ((uint32_t)(((uint8_t)(v_prop_byte % 5u)))); v_pb = ((uint32_t)(((uint8_t)(v_prop_byte / 5u)))); if ((v_lc + v_lp) > 4u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_lzma2_header); goto exit; } self->private_impl.f_lc = wuffs_base__u32__min(v_lc, 4u); self->private_impl.f_lp = v_lp; self->private_impl.f_pb = v_pb; self->private_impl.f_lzma2_need_properties = false; } if (v_header_byte >= 224u) { self->private_impl.f_lzma2_need_dict_reset = false; wuffs_lzma__decoder__initialize_dict(self); } else if (self->private_impl.f_prev_lzma2_chunk_was_uncompressed) { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(17); status = wuffs_lzma__decoder__update_stashed_bytes(self, a_dst, a_workbuf); if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (status.repr) { goto suspend; } } self->private_impl.f_prev_lzma2_chunk_was_uncompressed = false; if (self->private_impl.f_lzma2_need_prob_reset || self->private_impl.f_lzma2_need_properties || self->private_impl.f_lzma2_need_dict_reset) { status = wuffs_base__make_status(wuffs_lzma__error__bad_lzma2_header); goto exit; } } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(18); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; v_c8 = t_8; } if ((v_c8 != 0u) && ! self->private_impl.f_allow_non_zero_initial_byte) { status = wuffs_base__make_status(wuffs_lzma__error__bad_code); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(19); uint32_t t_9; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_9 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(20); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_9 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_9); if (num_bits_9 == 24) { t_9 = ((uint32_t)(*scratch >> 32)); break; } num_bits_9 += 8u; *scratch |= ((uint64_t)(num_bits_9)); } } self->private_impl.f_stashed_bits = t_9; } if (self->private_impl.f_stashed_bits == 4294967295u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_code); goto exit; } self->private_impl.f_stashed_range = 4294967295u; self->private_impl.f_stashed_pos_end = wuffs_base__u64__sat_add(self->private_impl.f_stashed_pos, self->private_impl.f_decoded_length); if ((self->private_impl.f_stashed_pos_end == 18446744073709551615u) && (self->private_impl.f_decoded_length != 18446744073709551615u)) { status = wuffs_base__make_status(wuffs_lzma__error__unsupported_decoded_length); goto exit; } self->private_impl.f_lzma2_encoded_length_have = 5u; while (((uint64_t)(a_workbuf.len)) < (((uint64_t)(self->private_impl.f_dict_size)) + 273u)) { status = wuffs_base__make_status(wuffs_base__suspension__short_workbuf); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(21); } while (true) { v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_10 = wuffs_lzma__decoder__decode_bitstream(self, a_dst, a_src, a_workbuf); v_status = t_10; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_lzma2_encoded_length_have, wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)))); if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(22); } if (self->private_impl.f_decoded_length == 18446744073709551615u) { if (self->private_impl.f_stashed_bits != 0u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_bitstream_trailer); goto exit; } } else if (self->private_impl.f_stashed_pos != self->private_impl.f_stashed_pos_end) { status = wuffs_base__make_status(wuffs_lzma__error__bad_decoded_length); goto exit; } else if (self->private_impl.f_stashed_bits != 0u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(23); status = wuffs_lzma__decoder__decode_optional_end_of_stream(self, a_src, a_workbuf); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_stashed_bits != 0u) { status = wuffs_base__make_status(wuffs_lzma__error__bad_bitstream_trailer); goto exit; } } if ((self->private_impl.f_format_extension & 255u) < 2u) { break; } else if (self->private_impl.f_lzma2_encoded_length_have != self->private_impl.f_lzma2_encoded_length_want) { status = wuffs_base__make_status(wuffs_lzma__error__bad_lzma2_header); goto exit; } } ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_transform_io.v_header_byte = v_header_byte; self->private_data.s_do_transform_io.v_length = v_length; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func lzma.decoder.decode_bitstream WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_bitstream( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_bitstream; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_end_of_chunk = false; while (true) { v_status = wuffs_lzma__decoder__decode_bitstream_fast(self, a_dst, a_src, a_workbuf); if (wuffs_base__status__is_error(&v_status)) { status = v_status; goto exit; } if (self->private_impl.f_end_of_chunk) { break; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_lzma__decoder__decode_bitstream_slow(self, a_dst, a_src, a_workbuf); if (status.repr) { goto suspend; } if (self->private_impl.f_end_of_chunk) { break; } } goto ok; ok: self->private_impl.p_decode_bitstream = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_bitstream = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func lzma.decoder.update_stashed_bytes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__update_stashed_bytes( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_dist = 0; uint32_t v_which = 0; uint32_t v_adj_dist = 0; uint64_t v_wb_index = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } uint32_t coro_susp_point = self->private_impl.p_update_stashed_bytes; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } v_dist = 1u; v_which = 0u; while (v_which < 2u) { if (((uint64_t)(v_dist)) <= ((uint64_t)(iop_a_dst - io0_a_dst))) { wuffs_private_impl__io_writer__limited_copy_u32_from_history( &iop_a_dst, io0_a_dst, io2_a_dst, 1u, v_dist); if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } self->private_impl.f_stashed_bytes[v_which] = iop_a_dst[-1]; iop_a_dst--; } else { v_adj_dist = ((uint32_t)((((uint64_t)(v_dist)) - ((uint64_t)(iop_a_dst - io0_a_dst))))); v_wb_index = ((uint64_t)(((uint64_t)(self->private_impl.f_dict_workbuf_index)) - ((uint64_t)(v_adj_dist)))); while (v_wb_index >= 9223372036854775808u) { v_wb_index += ((uint64_t)(self->private_impl.f_dict_size)); } if (v_wb_index >= ((uint64_t)(a_workbuf.len))) { status = wuffs_base__make_status(wuffs_lzma__error__internal_error_inconsistent_dictionary_state); goto exit; } self->private_impl.f_stashed_bytes[v_which] = a_workbuf.ptr[v_wb_index]; } v_dist = (1u + self->private_impl.f_stashed_rep0); v_which += 1u; } ok: self->private_impl.p_update_stashed_bytes = 0; goto exit; } goto suspend; suspend: self->private_impl.p_update_stashed_bytes = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } return status; } // -------- func lzma.decoder.decode_optional_end_of_stream WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzma__decoder__decode_optional_end_of_stream( wuffs_lzma__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__io_buffer u_w = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_w = &u_w; uint8_t* iop_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io0_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_optional_end_of_stream; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_stashed_pos_end = 18446744073709551615u; while (true) { { wuffs_base__io_buffer* o_0_v_w = v_w; uint8_t* o_0_iop_v_w = iop_v_w; uint8_t* o_0_io0_v_w = io0_v_w; uint8_t* o_0_io1_v_w = io1_v_w; uint8_t* o_0_io2_v_w = io2_v_w; v_w = wuffs_private_impl__io_writer__set( &u_w, &iop_v_w, &io0_v_w, &io1_v_w, &io2_v_w, wuffs_base__utility__empty_slice_u8(), 0u); { wuffs_base__status t_0 = wuffs_lzma__decoder__decode_bitstream_slow(self, v_w, a_src, a_workbuf); v_status = t_0; } v_w = o_0_v_w; iop_v_w = o_0_iop_v_w; io0_v_w = o_0_io0_v_w; io1_v_w = o_0_io1_v_w; io2_v_w = o_0_io2_v_w; } if (wuffs_base__status__is_ok(&v_status)) { break; } else if (v_status.repr == wuffs_base__suspension__short_write) { status = wuffs_base__make_status(wuffs_lzma__error__bad_bitstream_trailer); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } self->private_impl.f_stashed_pos_end = self->private_impl.f_stashed_pos; ok: self->private_impl.p_decode_optional_end_of_stream = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_optional_end_of_stream = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func lzma.decoder.initialize_dict WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzma__decoder__initialize_dict( wuffs_lzma__decoder* self) { self->private_impl.f_dict_workbuf_index = 0u; self->private_impl.f_dict_seen = 0u; self->private_impl.f_stashed_bytes[0u] = 0u; self->private_impl.f_stashed_bytes[1u] = 0u; self->private_impl.f_stashed_pos = 0u; return wuffs_base__make_empty_struct(); } // -------- func lzma.decoder.initialize_probs WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzma__decoder__initialize_probs( wuffs_lzma__decoder* self) { uint32_t v_i = 0; uint32_t v_j = 0; v_i = 0u; while (v_i < 192u) { self->private_data.f_probs_ao00[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 12u) { self->private_data.f_probs_ao20[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 12u) { self->private_data.f_probs_ao40[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 192u) { self->private_data.f_probs_ao41[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 12u) { self->private_data.f_probs_ao60[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 12u) { self->private_data.f_probs_ao63[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 16u) { v_j = 0u; while (v_j < 8u) { self->private_data.f_probs_match_len_low[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 16u) { v_j = 0u; while (v_j < 8u) { self->private_data.f_probs_match_len_mid[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 256u) { self->private_data.f_probs_match_len_high[0u][v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 16u) { v_j = 0u; while (v_j < 8u) { self->private_data.f_probs_longrep_len_low[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 16u) { v_j = 0u; while (v_j < 8u) { self->private_data.f_probs_longrep_len_mid[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 256u) { self->private_data.f_probs_longrep_len_high[0u][v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 4u) { v_j = 0u; while (v_j < 64u) { self->private_data.f_probs_slot[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } v_i = 0u; while (v_i < 128u) { self->private_data.f_probs_small_dist[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 16u) { self->private_data.f_probs_large_dist[v_i] = 1024u; v_i += 1u; } v_i = 0u; while (v_i < 16u) { v_j = 0u; while (v_j < 768u) { self->private_data.f_probs_lit[v_i][v_j] = 1024u; v_j += 1u; } v_i += 1u; } self->private_impl.f_stashed_state = 0u; self->private_impl.f_stashed_rep0 = 0u; self->private_impl.f_stashed_rep1 = 0u; self->private_impl.f_stashed_rep2 = 0u; self->private_impl.f_stashed_rep3 = 0u; return wuffs_base__make_empty_struct(); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZMA) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZIP) // ---------------- Status Codes Implementations const char wuffs_lzip__error__bad_checksum[] = "#lzip: bad checksum"; const char wuffs_lzip__error__bad_footer[] = "#lzip: bad footer"; const char wuffs_lzip__error__bad_header[] = "#lzip: bad header"; const char wuffs_lzip__error__truncated_input[] = "#lzip: truncated input"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzip__decoder__do_transform_io( wuffs_lzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_lzip__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_lzip__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_lzip__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_lzip__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_lzip__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_lzip__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzip__decoder__initialize( wuffs_lzip__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } { wuffs_base__status z = wuffs_crc32__ieee_hasher__initialize( &self->private_data.f_crc32, sizeof(self->private_data.f_crc32), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_lzma__decoder__initialize( &self->private_data.f_lzma, sizeof(self->private_data.f_lzma), WUFFS_VERSION, options); if (z.repr) { return z; } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_lzip__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_lzip__decoder* wuffs_lzip__decoder__alloc(void) { wuffs_lzip__decoder* x = (wuffs_lzip__decoder*)(calloc(1, sizeof(wuffs_lzip__decoder))); if (!x) { return NULL; } if (wuffs_lzip__decoder__initialize( x, sizeof(wuffs_lzip__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_lzip__decoder(void) { return sizeof(wuffs_lzip__decoder); } // ---------------- Function Implementations // -------- func lzip.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzip__decoder__get_quirk( const wuffs_lzip__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if ((a_key == 1u) && self->private_impl.f_ignore_checksum) { return 1u; } return 0u; } // -------- func lzip.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzip__decoder__set_quirk( wuffs_lzip__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func lzip.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzip__decoder__dst_history_retain_length( const wuffs_lzip__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_lzma__decoder__dst_history_retain_length(&self->private_data.f_lzma); } // -------- func lzip.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzip__decoder__workbuf_len( const wuffs_lzip__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_lzma__decoder__workbuf_len(&self->private_data.f_lzma); } // -------- func lzip.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzip__decoder__transform_io( wuffs_lzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_lzip__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_lzip__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func lzip.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzip__decoder__do_transform_io( wuffs_lzip__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_c32 = 0; uint64_t v_c64 = 0; uint64_t v_dmark = 0; uint64_t v_smark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_checksum_want = 0; uint32_t v_checksum_have = 0; uint64_t v_size_want = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 5)) { t_0 = ((uint64_t)(wuffs_base__peek_u40le__no_bounds_check(iop_a_src))); iop_a_src += 5; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 32) { t_0 = ((uint64_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c64 = t_0; } if (v_c64 != 5641951820u) { status = wuffs_base__make_status(wuffs_lzip__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } v_status = wuffs_lzma__decoder__set_quirk(&self->private_data.f_lzma, 1348001793u, (1u | (((uint64_t)(v_c8)) << 8u))); if ( ! wuffs_base__status__is_ok(&v_status)) { if (v_status.repr == wuffs_base__error__bad_argument) { status = wuffs_base__make_status(wuffs_lzip__error__bad_header); goto exit; } status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_ssize_have = 0u; self->private_impl.f_dsize_have = 0u; wuffs_lzma__decoder__set_quirk(&self->private_data.f_lzma, 1348001792u, 1u); while (true) { v_dmark = ((uint64_t)(iop_a_dst - io0_a_dst)); v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_lzma__decoder__transform_io(&self->private_data.f_lzma, a_dst, a_src, a_workbuf); v_status = t_2; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } self->private_impl.f_ssize_have += wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src))); self->private_impl.f_dsize_have += wuffs_private_impl__io__count_since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst))); if ( ! self->private_impl.f_ignore_checksum) { wuffs_crc32__ieee_hasher__update(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } v_checksum_want = t_3; } if ( ! self->private_impl.f_ignore_checksum) { v_checksum_have = wuffs_crc32__ieee_hasher__checksum_u32(&self->private_data.f_crc32); if (v_checksum_have != v_checksum_want) { status = wuffs_base__make_status(wuffs_lzip__error__bad_checksum); goto exit; } } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint64_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_4 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 56) { t_4 = ((uint64_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } v_size_want = t_4; } if (self->private_impl.f_dsize_have != v_size_want) { status = wuffs_base__make_status(wuffs_lzip__error__bad_footer); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); uint64_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_5 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_5; if (num_bits_5 == 56) { t_5 = ((uint64_t)(*scratch)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)) << 56; } } v_size_want = t_5; } if ((v_size_want < 26u) || (2251799813685248u < v_size_want)) { status = wuffs_base__make_status(wuffs_lzip__error__bad_footer); goto exit; } else if (self->private_impl.f_ssize_have != (v_size_want - 26u)) { status = wuffs_base__make_status(wuffs_lzip__error__bad_footer); goto exit; } while (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { if (a_src && a_src->meta.closed) { goto label__outer__break; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(11); } v_c32 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); if (v_c32 != 1346984524u) { break; } wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_private_impl__ignore_status(wuffs_lzma__decoder__initialize(&self->private_data.f_lzma, sizeof (wuffs_lzma__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } label__outer__break:; ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZIP) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZW) // ---------------- Status Codes Implementations const char wuffs_lzw__error__bad_code[] = "#lzw: bad code"; const char wuffs_lzw__error__truncated_input[] = "#lzw: truncated input"; const char wuffs_lzw__error__internal_error_inconsistent_i_o[] = "#lzw: internal error: inconsistent I/O"; // ---------------- Private Consts #define WUFFS_LZW__QUIRKS_BASE 1348378624u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzw__decoder__read_from( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzw__decoder__write_to( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_dst); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_lzw__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_lzw__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_lzw__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_lzw__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_lzw__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_lzw__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_lzw__decoder__initialize( wuffs_lzw__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_lzw__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_lzw__decoder* wuffs_lzw__decoder__alloc(void) { wuffs_lzw__decoder* x = (wuffs_lzw__decoder*)(calloc(1, sizeof(wuffs_lzw__decoder))); if (!x) { return NULL; } if (wuffs_lzw__decoder__initialize( x, sizeof(wuffs_lzw__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_lzw__decoder(void) { return sizeof(wuffs_lzw__decoder); } // ---------------- Function Implementations // -------- func lzw.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_lzw__decoder__get_quirk( const wuffs_lzw__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (a_key == 1348378624u) { return ((uint64_t)(self->private_impl.f_pending_literal_width_plus_one)); } return 0u; } // -------- func lzw.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzw__decoder__set_quirk( wuffs_lzw__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1348378624u) { if (a_value > 9u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_pending_literal_width_plus_one = ((uint32_t)(a_value)); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func lzw.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_lzw__decoder__dst_history_retain_length( const wuffs_lzw__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func lzw.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_lzw__decoder__workbuf_len( const wuffs_lzw__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } // -------- func lzw.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_lzw__decoder__transform_io( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_i = 0; uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_literal_width = 8u; if (self->private_impl.f_pending_literal_width_plus_one > 0u) { self->private_impl.f_literal_width = (self->private_impl.f_pending_literal_width_plus_one - 1u); } self->private_impl.f_clear_code = (((uint32_t)(1u)) << self->private_impl.f_literal_width); self->private_impl.f_end_code = (self->private_impl.f_clear_code + 1u); self->private_impl.f_save_code = self->private_impl.f_end_code; self->private_impl.f_prev_code = self->private_impl.f_end_code; self->private_impl.f_width = (self->private_impl.f_literal_width + 1u); self->private_impl.f_bits = 0u; self->private_impl.f_n_bits = 0u; self->private_impl.f_output_ri = 0u; self->private_impl.f_output_wi = 0u; v_i = 0u; while (v_i < self->private_impl.f_clear_code) { self->private_data.f_lm1s[v_i] = 0u; self->private_data.f_suffixes[v_i][0u] = ((uint8_t)(v_i)); v_i += 1u; } while (true) { wuffs_lzw__decoder__read_from(self, a_src); if (self->private_impl.f_output_wi > 0u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_lzw__decoder__write_to(self, a_dst); if (status.repr) { goto suspend; } } if (self->private_impl.f_read_from_return_value == 0u) { break; } else if (self->private_impl.f_read_from_return_value == 1u) { continue; } else if (self->private_impl.f_read_from_return_value == 2u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } else if (self->private_impl.f_read_from_return_value == 3u) { status = wuffs_base__make_status(wuffs_lzw__error__truncated_input); goto exit; } else if (self->private_impl.f_read_from_return_value == 4u) { status = wuffs_base__make_status(wuffs_lzw__error__bad_code); goto exit; } else { status = wuffs_base__make_status(wuffs_lzw__error__internal_error_inconsistent_i_o); goto exit; } } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func lzw.decoder.read_from WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_lzw__decoder__read_from( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_src) { uint32_t v_clear_code = 0; uint32_t v_end_code = 0; uint32_t v_save_code = 0; uint32_t v_prev_code = 0; uint32_t v_width = 0; uint32_t v_bits = 0; uint32_t v_n_bits = 0; uint32_t v_output_wi = 0; uint32_t v_code = 0; uint32_t v_c = 0; uint32_t v_o = 0; uint32_t v_steps = 0; uint8_t v_first_byte = 0; uint16_t v_lm1_b = 0; uint16_t v_lm1_a = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_clear_code = self->private_impl.f_clear_code; v_end_code = self->private_impl.f_end_code; v_save_code = self->private_impl.f_save_code; v_prev_code = self->private_impl.f_prev_code; v_width = self->private_impl.f_width; v_bits = self->private_impl.f_bits; v_n_bits = self->private_impl.f_n_bits; v_output_wi = self->private_impl.f_output_wi; while (true) { if (v_n_bits < v_width) { if (((uint64_t)(io2_a_src - iop_a_src)) >= 4u) { v_bits |= ((uint32_t)(wuffs_base__peek_u32le__no_bounds_check(iop_a_src) << v_n_bits)); iop_a_src += ((31u - v_n_bits) >> 3u); v_n_bits |= 24u; } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { self->private_impl.f_read_from_return_value = 3u; } else { self->private_impl.f_read_from_return_value = 2u; } break; } else { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; if (v_n_bits >= v_width) { } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { if (a_src && a_src->meta.closed) { self->private_impl.f_read_from_return_value = 3u; } else { self->private_impl.f_read_from_return_value = 2u; } break; } else { v_bits |= (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) << v_n_bits); iop_a_src += 1u; v_n_bits += 8u; if (v_n_bits < v_width) { self->private_impl.f_read_from_return_value = 5u; break; } } } } v_code = ((v_bits) & WUFFS_PRIVATE_IMPL__LOW_BITS_MASK__U32(v_width)); v_bits >>= v_width; v_n_bits -= v_width; if (v_code < v_clear_code) { self->private_data.f_output[v_output_wi] = ((uint8_t)(v_code)); v_output_wi = ((v_output_wi + 1u) & 8191u); if (v_save_code <= 4095u) { v_lm1_a = ((uint16_t)(((uint16_t)(self->private_data.f_lm1s[v_prev_code] + 1u)) & 4095u)); self->private_data.f_lm1s[v_save_code] = v_lm1_a; if (((uint16_t)(v_lm1_a % 8u)) != 0u) { self->private_impl.f_prefixes[v_save_code] = self->private_impl.f_prefixes[v_prev_code]; memcpy(self->private_data.f_suffixes[v_save_code],self->private_data.f_suffixes[v_prev_code], sizeof(self->private_data.f_suffixes[v_save_code])); self->private_data.f_suffixes[v_save_code][((uint16_t)(v_lm1_a % 8u))] = ((uint8_t)(v_code)); } else { self->private_impl.f_prefixes[v_save_code] = ((uint16_t)(v_prev_code)); self->private_data.f_suffixes[v_save_code][0u] = ((uint8_t)(v_code)); } v_save_code += 1u; if (v_width < 12u) { v_width += (1u & (v_save_code >> v_width)); } v_prev_code = v_code; } } else if (v_code <= v_end_code) { if (v_code == v_end_code) { self->private_impl.f_read_from_return_value = 0u; break; } v_save_code = v_end_code; v_prev_code = v_end_code; v_width = (self->private_impl.f_literal_width + 1u); } else if (v_code <= v_save_code) { v_c = v_code; if (v_code == v_save_code) { v_c = v_prev_code; } v_o = ((v_output_wi + (((uint32_t)(self->private_data.f_lm1s[v_c])) & 4294967288u)) & 8191u); v_output_wi = ((v_output_wi + 1u + ((uint32_t)(self->private_data.f_lm1s[v_c]))) & 8191u); v_steps = (((uint32_t)(self->private_data.f_lm1s[v_c])) >> 3u); while (true) { memcpy((self->private_data.f_output)+(v_o), (self->private_data.f_suffixes[v_c]), 8u); if (v_steps <= 0u) { break; } v_steps -= 1u; v_o = (((uint32_t)(v_o - 8u)) & 8191u); v_c = ((uint32_t)(self->private_impl.f_prefixes[v_c])); } v_first_byte = self->private_data.f_suffixes[v_c][0u]; if (v_code == v_save_code) { self->private_data.f_output[v_output_wi] = v_first_byte; v_output_wi = ((v_output_wi + 1u) & 8191u); } if (v_save_code <= 4095u) { v_lm1_b = ((uint16_t)(((uint16_t)(self->private_data.f_lm1s[v_prev_code] + 1u)) & 4095u)); self->private_data.f_lm1s[v_save_code] = v_lm1_b; if (((uint16_t)(v_lm1_b % 8u)) != 0u) { self->private_impl.f_prefixes[v_save_code] = self->private_impl.f_prefixes[v_prev_code]; memcpy(self->private_data.f_suffixes[v_save_code],self->private_data.f_suffixes[v_prev_code], sizeof(self->private_data.f_suffixes[v_save_code])); self->private_data.f_suffixes[v_save_code][((uint16_t)(v_lm1_b % 8u))] = v_first_byte; } else { self->private_impl.f_prefixes[v_save_code] = ((uint16_t)(v_prev_code)); self->private_data.f_suffixes[v_save_code][0u] = ((uint8_t)(v_first_byte)); } v_save_code += 1u; if (v_width < 12u) { v_width += (1u & (v_save_code >> v_width)); } v_prev_code = v_code; } } else { self->private_impl.f_read_from_return_value = 4u; break; } if (v_output_wi > 4095u) { self->private_impl.f_read_from_return_value = 1u; break; } } if (self->private_impl.f_read_from_return_value != 2u) { while (v_n_bits >= 8u) { v_n_bits -= 8u; if (iop_a_src > io1_a_src) { iop_a_src--; } else { self->private_impl.f_read_from_return_value = 5u; break; } } } self->private_impl.f_save_code = v_save_code; self->private_impl.f_prev_code = v_prev_code; self->private_impl.f_width = v_width; self->private_impl.f_bits = v_bits; self->private_impl.f_n_bits = v_n_bits; self->private_impl.f_output_wi = v_output_wi; if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return wuffs_base__make_empty_struct(); } // -------- func lzw.decoder.write_to WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_lzw__decoder__write_to( wuffs_lzw__decoder* self, wuffs_base__io_buffer* a_dst) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__slice_u8 v_s = {0}; uint64_t v_n = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } uint32_t coro_susp_point = self->private_impl.p_write_to; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (self->private_impl.f_output_wi > 0u) { if (self->private_impl.f_output_ri > self->private_impl.f_output_wi) { status = wuffs_base__make_status(wuffs_lzw__error__internal_error_inconsistent_i_o); goto exit; } v_s = wuffs_base__make_slice_u8_ij(self->private_data.f_output, self->private_impl.f_output_ri, self->private_impl.f_output_wi); v_n = wuffs_private_impl__io_writer__copy_from_slice(&iop_a_dst, io2_a_dst,v_s); if (v_n == ((uint64_t)(v_s.len))) { self->private_impl.f_output_ri = 0u; self->private_impl.f_output_wi = 0u; status = wuffs_base__make_status(NULL); goto ok; } self->private_impl.f_output_ri = (((uint32_t)(self->private_impl.f_output_ri + ((uint32_t)(v_n)))) & 8191u); status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_write_to = 0; goto exit; } goto suspend; suspend: self->private_impl.p_write_to = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } return status; } // -------- func lzw.decoder.flush WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__slice_u8 wuffs_lzw__decoder__flush( wuffs_lzw__decoder* self) { if (!self) { return wuffs_base__empty_slice_u8(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__empty_slice_u8(); } uint32_t v_ri = 0; uint32_t v_wi = 0; v_ri = self->private_impl.f_output_ri; v_wi = self->private_impl.f_output_wi; self->private_impl.f_output_ri = 0u; self->private_impl.f_output_wi = 0u; if (v_ri <= v_wi) { return wuffs_base__make_slice_u8_ij(self->private_data.f_output, v_ri, v_wi); } return wuffs_base__make_slice_u8(self->private_data.f_output, 0); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__LZW) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NETPBM) // ---------------- Status Codes Implementations const char wuffs_netpbm__error__bad_header[] = "#netpbm: bad header"; const char wuffs_netpbm__error__truncated_input[] = "#netpbm: truncated input"; const char wuffs_netpbm__error__unsupported_netpbm_file[] = "#netpbm: unsupported Netpbm file"; const char wuffs_netpbm__note__internal_note_short_read[] = "@netpbm: internal note: short read"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_image_config( wuffs_netpbm__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_frame_config( wuffs_netpbm__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_frame( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__swizzle( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_netpbm__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_netpbm__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_netpbm__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_netpbm__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_netpbm__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_netpbm__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_netpbm__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_netpbm__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_netpbm__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_netpbm__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_netpbm__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_netpbm__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_netpbm__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_netpbm__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_netpbm__decoder__initialize( wuffs_netpbm__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_netpbm__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_netpbm__decoder* wuffs_netpbm__decoder__alloc(void) { wuffs_netpbm__decoder* x = (wuffs_netpbm__decoder*)(calloc(1, sizeof(wuffs_netpbm__decoder))); if (!x) { return NULL; } if (wuffs_netpbm__decoder__initialize( x, sizeof(wuffs_netpbm__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_netpbm__decoder(void) { return sizeof(wuffs_netpbm__decoder); } // ---------------- Function Implementations // -------- func netpbm.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__get_quirk( const wuffs_netpbm__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func netpbm.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__set_quirk( wuffs_netpbm__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func netpbm.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_image_config( wuffs_netpbm__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_netpbm__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_netpbm__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func netpbm.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_image_config( wuffs_netpbm__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_n = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 80u) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if ((v_c8 < 49u) || (55u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } else if (v_c8 == 53u) { self->private_impl.f_pixfmt = 536870920u; } else if (v_c8 == 54u) { self->private_impl.f_pixfmt = 2684356744u; } else { status = wuffs_base__make_status(wuffs_netpbm__error__unsupported_netpbm_file); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_c8 != 10u) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if ((v_c8 == 32u) || (v_c8 == 9u)) { continue; } else if (v_c8 == 35u) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if (v_c8 == 10u) { break; } } continue; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } self->private_impl.f_width = ((uint32_t)(((uint8_t)(v_c8 - 48u)))); break; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } if ((v_c8 == 32u) || (v_c8 == 9u)) { break; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } v_n = ((10u * self->private_impl.f_width) + ((uint32_t)(((uint8_t)(v_c8 - 48u))))); if (v_n > 16777215u) { status = wuffs_base__make_status(wuffs_netpbm__error__unsupported_netpbm_file); goto exit; } self->private_impl.f_width = v_n; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if ((v_c8 == 32u) || (v_c8 == 9u)) { continue; } else if (v_c8 == 35u) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_7 = *iop_a_src++; v_c8 = t_7; } if (v_c8 == 10u) { break; } } continue; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } self->private_impl.f_height = ((uint32_t)(((uint8_t)(v_c8 - 48u)))); break; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; v_c8 = t_8; } if ((v_c8 == 32u) || (v_c8 == 9u) || (v_c8 == 13u)) { continue; } else if (v_c8 == 10u) { break; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } v_n = ((10u * self->private_impl.f_height) + ((uint32_t)(((uint8_t)(v_c8 - 48u))))); if (v_n > 16777215u) { status = wuffs_base__make_status(wuffs_netpbm__error__unsupported_netpbm_file); goto exit; } self->private_impl.f_height = v_n; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_9 = *iop_a_src++; v_c8 = t_9; } if ((v_c8 == 32u) || (v_c8 == 9u)) { continue; } else if (v_c8 == 35u) { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_10 = *iop_a_src++; v_c8 = t_10; } if (v_c8 == 10u) { break; } } continue; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } self->private_impl.f_max_value = ((uint32_t)(((uint8_t)(v_c8 - 48u)))); break; } while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_11 = *iop_a_src++; v_c8 = t_11; } if ((v_c8 == 32u) || (v_c8 == 9u) || (v_c8 == 13u)) { continue; } else if (v_c8 == 10u) { break; } else if ((v_c8 < 48u) || (57u < v_c8)) { status = wuffs_base__make_status(wuffs_netpbm__error__bad_header); goto exit; } v_n = ((10u * self->private_impl.f_max_value) + ((uint32_t)(((uint8_t)(v_c8 - 48u))))); if (v_n > 16777215u) { status = wuffs_base__make_status(wuffs_netpbm__error__unsupported_netpbm_file); goto exit; } self->private_impl.f_max_value = v_n; } if (self->private_impl.f_max_value != 255u) { status = wuffs_base__make_status(wuffs_netpbm__error__unsupported_netpbm_file); goto exit; } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, false); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func netpbm.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_frame_config( wuffs_netpbm__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_netpbm__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_netpbm__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func netpbm.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_frame_config( wuffs_netpbm__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_netpbm__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, false, false, 0u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func netpbm.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__decode_frame( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_netpbm__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_netpbm__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func netpbm.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__do_decode_frame( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_netpbm__decoder__do_decode_frame_config(self, NULL, a_src); if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y = 0u; v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette(a_dst), wuffs_base__utility__make_pixel_format(self->private_impl.f_pixfmt), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } while (true) { v_status = wuffs_netpbm__decoder__swizzle(self, a_dst, a_src); if (wuffs_base__status__is_ok(&v_status)) { break; } else if (v_status.repr != wuffs_netpbm__note__internal_note_short_read) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func netpbm.decoder.swizzle WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_netpbm__decoder__swizzle( wuffs_netpbm__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; uint32_t v_src_bytes_per_pixel = 0; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_j = 0; uint64_t v_n = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); while (true) { if (self->private_impl.f_dst_x == self->private_impl.f_width) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += 1u; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { break; } } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i >= ((uint64_t)(v_dst.len))) { v_src_bytes_per_pixel = 1u; if (self->private_impl.f_pixfmt == 2684356744u) { v_src_bytes_per_pixel = 3u; } v_n = (((uint64_t)(io2_a_src - iop_a_src)) / ((uint64_t)(v_src_bytes_per_pixel))); v_n = wuffs_base__u64__min(v_n, ((uint64_t)(((uint32_t)(self->private_impl.f_width - self->private_impl.f_dst_x))))); v_j = v_n; while (v_j >= 8u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 8u)))) { iop_a_src += (v_src_bytes_per_pixel * 8u); } v_j -= 8u; } while (v_j > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 1u)))) { iop_a_src += (v_src_bytes_per_pixel * 1u); } v_j -= 1u; } } else { v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_reader( &self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), wuffs_base__pixel_buffer__palette(a_dst), &iop_a_src, io2_a_src); } if (v_n == 0u) { status = wuffs_base__make_status(wuffs_netpbm__note__internal_note_short_read); goto ok; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); } status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func netpbm.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_netpbm__decoder__frame_dirty_rect( const wuffs_netpbm__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func netpbm.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_netpbm__decoder__num_animation_loops( const wuffs_netpbm__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func netpbm.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__num_decoded_frame_configs( const wuffs_netpbm__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func netpbm.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_netpbm__decoder__num_decoded_frames( const wuffs_netpbm__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func netpbm.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__restart_frame( wuffs_netpbm__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if ((a_index != 0u) || (a_io_position != self->private_impl.f_frame_config_io_position)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; return wuffs_base__make_status(NULL); } // -------- func netpbm.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_netpbm__decoder__set_report_metadata( wuffs_netpbm__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func netpbm.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_netpbm__decoder__tell_me_more( wuffs_netpbm__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func netpbm.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_netpbm__decoder__workbuf_len( const wuffs_netpbm__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NETPBM) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NIE) // ---------------- Status Codes Implementations const char wuffs_nie__error__bad_header[] = "#nie: bad header"; const char wuffs_nie__error__truncated_input[] = "#nie: truncated input"; const char wuffs_nie__error__unsupported_nie_file[] = "#nie: unsupported NIE file"; const char wuffs_nie__note__internal_note_short_read[] = "@nie: internal note: short read"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_image_config( wuffs_nie__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_frame_config( wuffs_nie__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_frame( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__swizzle( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_nie__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_nie__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_nie__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_nie__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_nie__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_nie__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_nie__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_nie__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_nie__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_nie__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_nie__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_nie__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_nie__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_nie__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_nie__decoder__initialize( wuffs_nie__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_nie__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_nie__decoder* wuffs_nie__decoder__alloc(void) { wuffs_nie__decoder* x = (wuffs_nie__decoder*)(calloc(1, sizeof(wuffs_nie__decoder))); if (!x) { return NULL; } if (wuffs_nie__decoder__initialize( x, sizeof(wuffs_nie__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_nie__decoder(void) { return sizeof(wuffs_nie__decoder); } // ---------------- Function Implementations // -------- func nie.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__get_quirk( const wuffs_nie__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func nie.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__set_quirk( wuffs_nie__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func nie.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_image_config( wuffs_nie__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_nie__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_nie__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func nie.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_image_config( wuffs_nie__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_a = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_a = t_0; } if (v_a != 1169146734u) { status = wuffs_base__make_status(wuffs_nie__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_a = t_1; } if (v_a == 879649535u) { self->private_impl.f_pixfmt = 2164295816u; } else if (v_a == 946758399u) { self->private_impl.f_pixfmt = 2164308923u; } else if (v_a == 879780607u) { status = wuffs_base__make_status(wuffs_nie__error__unsupported_nie_file); goto exit; } else if (v_a == 946889471u) { status = wuffs_base__make_status(wuffs_nie__error__unsupported_nie_file); goto exit; } else { status = wuffs_base__make_status(wuffs_nie__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } v_a = t_2; } if (v_a > 2147483647u) { status = wuffs_base__make_status(wuffs_nie__error__bad_header); goto exit; } else if (v_a > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_width = v_a; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } v_a = t_3; } if (v_a > 2147483647u) { status = wuffs_base__make_status(wuffs_nie__error__bad_header); goto exit; } else if (v_a > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_height = v_a; if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, 16u, false); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func nie.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_frame_config( wuffs_nie__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_nie__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_nie__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func nie.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_frame_config( wuffs_nie__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_nie__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (16u != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, 16u, 0u, false, false, 0u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func nie.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__decode_frame( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_nie__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_nie__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func nie.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__do_decode_frame( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_nie__decoder__do_decode_frame_config(self, NULL, a_src); if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y = 0u; v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette(a_dst), wuffs_base__utility__make_pixel_format(self->private_impl.f_pixfmt), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } while (true) { v_status = wuffs_nie__decoder__swizzle(self, a_dst, a_src); if (wuffs_base__status__is_ok(&v_status)) { break; } else if (v_status.repr != wuffs_nie__note__internal_note_short_read) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func nie.decoder.swizzle WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_nie__decoder__swizzle( wuffs_nie__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; uint32_t v_src_bytes_per_pixel = 0; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_i = 0; uint64_t v_j = 0; uint64_t v_n = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); while (true) { if (self->private_impl.f_dst_x == self->private_impl.f_width) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += 1u; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { break; } } v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); if (v_i >= ((uint64_t)(v_dst.len))) { v_src_bytes_per_pixel = 4u; if (self->private_impl.f_pixfmt == 2164308923u) { v_src_bytes_per_pixel = 8u; } v_n = (((uint64_t)(io2_a_src - iop_a_src)) / ((uint64_t)(v_src_bytes_per_pixel))); v_n = wuffs_base__u64__min(v_n, ((uint64_t)(((uint32_t)(self->private_impl.f_width - self->private_impl.f_dst_x))))); v_j = v_n; while (v_j >= 8u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 8u)))) { iop_a_src += (v_src_bytes_per_pixel * 8u); } v_j -= 8u; } while (v_j > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) >= ((uint64_t)((v_src_bytes_per_pixel * 1u)))) { iop_a_src += (v_src_bytes_per_pixel * 1u); } v_j -= 1u; } } else { v_n = wuffs_base__pixel_swizzler__swizzle_interleaved_from_reader( &self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), wuffs_base__pixel_buffer__palette(a_dst), &iop_a_src, io2_a_src); } if (v_n == 0u) { status = wuffs_base__make_status(wuffs_nie__note__internal_note_short_read); goto ok; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_dst_x, ((uint32_t)(v_n))); } status = wuffs_base__make_status(NULL); goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func nie.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_nie__decoder__frame_dirty_rect( const wuffs_nie__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func nie.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_nie__decoder__num_animation_loops( const wuffs_nie__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func nie.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__num_decoded_frame_configs( const wuffs_nie__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func nie.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_nie__decoder__num_decoded_frames( const wuffs_nie__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func nie.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__restart_frame( wuffs_nie__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if ((a_index != 0u) || (a_io_position != 16u)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; return wuffs_base__make_status(NULL); } // -------- func nie.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_nie__decoder__set_report_metadata( wuffs_nie__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func nie.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_nie__decoder__tell_me_more( wuffs_nie__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func nie.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_nie__decoder__workbuf_len( const wuffs_nie__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NIE) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ZLIB) // ---------------- Status Codes Implementations const char wuffs_zlib__note__dictionary_required[] = "@zlib: dictionary required"; const char wuffs_zlib__error__bad_checksum[] = "#zlib: bad checksum"; const char wuffs_zlib__error__bad_compression_method[] = "#zlib: bad compression method"; const char wuffs_zlib__error__bad_compression_window_size[] = "#zlib: bad compression window size"; const char wuffs_zlib__error__bad_parity_check[] = "#zlib: bad parity check"; const char wuffs_zlib__error__incorrect_dictionary[] = "#zlib: incorrect dictionary"; const char wuffs_zlib__error__truncated_input[] = "#zlib: truncated input"; // ---------------- Private Consts #define WUFFS_ZLIB__QUIRKS_BASE 2113790976u #define WUFFS_ZLIB__QUIRKS_COUNT 1u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_zlib__decoder__do_transform_io( wuffs_zlib__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_zlib__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_zlib__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_zlib__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_zlib__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_zlib__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_zlib__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_zlib__decoder__initialize( wuffs_zlib__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } { wuffs_base__status z = wuffs_adler32__hasher__initialize( &self->private_data.f_checksum, sizeof(self->private_data.f_checksum), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_adler32__hasher__initialize( &self->private_data.f_dict_id_hasher, sizeof(self->private_data.f_dict_id_hasher), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_deflate__decoder__initialize( &self->private_data.f_flate, sizeof(self->private_data.f_flate), WUFFS_VERSION, options); if (z.repr) { return z; } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_zlib__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_zlib__decoder* wuffs_zlib__decoder__alloc(void) { wuffs_zlib__decoder* x = (wuffs_zlib__decoder*)(calloc(1, sizeof(wuffs_zlib__decoder))); if (!x) { return NULL; } if (wuffs_zlib__decoder__initialize( x, sizeof(wuffs_zlib__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_zlib__decoder(void) { return sizeof(wuffs_zlib__decoder); } // ---------------- Function Implementations // -------- func zlib.decoder.dictionary_id WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_zlib__decoder__dictionary_id( const wuffs_zlib__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_dict_id_want; } // -------- func zlib.decoder.add_dictionary WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_zlib__decoder__add_dictionary( wuffs_zlib__decoder* self, wuffs_base__slice_u8 a_dict) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if (self->private_impl.f_header_complete) { self->private_impl.f_bad_call_sequence = true; } else { self->private_impl.f_dict_id_have = wuffs_adler32__hasher__update_u32(&self->private_data.f_dict_id_hasher, a_dict); wuffs_deflate__decoder__add_history(&self->private_data.f_flate, a_dict); } self->private_impl.f_got_dictionary = true; return wuffs_base__make_empty_struct(); } // -------- func zlib.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_zlib__decoder__get_quirk( const wuffs_zlib__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } uint32_t v_key = 0; if ((a_key == 1u) && self->private_impl.f_ignore_checksum) { return 1u; } else if (a_key >= 2113790976u) { v_key = (a_key - 2113790976u); if (v_key < 1u) { if (self->private_impl.f_quirks[v_key]) { return 1u; } } } return 0u; } // -------- func zlib.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_zlib__decoder__set_quirk( wuffs_zlib__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_header_complete) { self->private_impl.f_bad_call_sequence = true; return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } else if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); return wuffs_base__make_status(NULL); } else if (a_key >= 2113790976u) { a_key -= 2113790976u; if (a_key < 1u) { self->private_impl.f_quirks[a_key] = (a_value > 0u); return wuffs_base__make_status(NULL); } } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func zlib.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_zlib__decoder__dst_history_retain_length( const wuffs_zlib__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_base__utility__make_optional_u63(true, 0u); } // -------- func zlib.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_zlib__decoder__workbuf_len( const wuffs_zlib__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(1u, 1u); } // -------- func zlib.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_zlib__decoder__transform_io( wuffs_zlib__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_zlib__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_zlib__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func zlib.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_zlib__decoder__do_transform_io( wuffs_zlib__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint16_t v_x = 0; uint32_t v_checksum_have = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_checksum_want = 0; uint64_t v_mark = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; if (coro_susp_point) { v_checksum_have = self->private_data.s_do_transform_io.v_checksum_have; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_bad_call_sequence) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if (self->private_impl.f_quirks[0u]) { } else if ( ! self->private_impl.f_want_dictionary) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint16_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = wuffs_base__peek_u16be__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 8) { t_0 = ((uint16_t)(*scratch >> 48)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_x = t_0; } if (((uint16_t)(((uint16_t)(v_x >> 8u)) & 15u)) != 8u) { status = wuffs_base__make_status(wuffs_zlib__error__bad_compression_method); goto exit; } if (((uint16_t)(v_x >> 12u)) > 7u) { status = wuffs_base__make_status(wuffs_zlib__error__bad_compression_window_size); goto exit; } if (((uint16_t)(v_x % 31u)) != 0u) { status = wuffs_base__make_status(wuffs_zlib__error__bad_parity_check); goto exit; } self->private_impl.f_want_dictionary = (((uint16_t)(v_x & 32u)) != 0u); if (self->private_impl.f_want_dictionary) { self->private_impl.f_dict_id_have = 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } self->private_impl.f_dict_id_want = t_1; } status = wuffs_base__make_status(wuffs_zlib__note__dictionary_required); goto ok; } else if (self->private_impl.f_got_dictionary) { status = wuffs_base__make_status(wuffs_zlib__error__incorrect_dictionary); goto exit; } } else if (self->private_impl.f_dict_id_have != self->private_impl.f_dict_id_want) { if (self->private_impl.f_got_dictionary) { status = wuffs_base__make_status(wuffs_zlib__error__incorrect_dictionary); goto exit; } status = wuffs_base__make_status(wuffs_zlib__note__dictionary_required); goto ok; } self->private_impl.f_header_complete = true; while (true) { v_mark = ((uint64_t)(iop_a_dst - io0_a_dst)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_deflate__decoder__transform_io(&self->private_data.f_flate, a_dst, a_src, a_workbuf); v_status = t_2; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum && ! self->private_impl.f_quirks[0u]) { v_checksum_have = wuffs_adler32__hasher__update_u32(&self->private_data.f_checksum, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } if ( ! self->private_impl.f_quirks[0u]) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_3); if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch >> 32)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)); } } v_checksum_want = t_3; } if ( ! self->private_impl.f_ignore_checksum && (v_checksum_have != v_checksum_want)) { status = wuffs_base__make_status(wuffs_zlib__error__bad_checksum); goto exit; } } ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_transform_io.v_checksum_have = v_checksum_have; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__ZLIB) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__PNG) // ---------------- Status Codes Implementations const char wuffs_png__error__bad_animation_sequence_number[] = "#png: bad animation sequence number"; const char wuffs_png__error__bad_checksum[] = "#png: bad checksum"; const char wuffs_png__error__bad_chunk[] = "#png: bad chunk"; const char wuffs_png__error__bad_filter[] = "#png: bad filter"; const char wuffs_png__error__bad_header[] = "#png: bad header"; const char wuffs_png__error__bad_text_chunk_not_latin_1[] = "#png: bad text chunk (not Latin-1)"; const char wuffs_png__error__missing_palette[] = "#png: missing palette"; const char wuffs_png__error__truncated_input[] = "#png: truncated input"; const char wuffs_png__error__unsupported_cgbi_extension[] = "#png: unsupported CgBI extension"; const char wuffs_png__error__unsupported_png_compression_method[] = "#png: unsupported PNG compression method"; const char wuffs_png__error__unsupported_png_file[] = "#png: unsupported PNG file"; const char wuffs_png__error__internal_error_inconsistent_i_o[] = "#png: internal error: inconsistent I/O"; const char wuffs_png__error__internal_error_inconsistent_chunk_type[] = "#png: internal error: inconsistent chunk type"; const char wuffs_png__error__internal_error_inconsistent_workbuf_length[] = "#png: internal error: inconsistent workbuf length"; const char wuffs_png__error__internal_error_zlib_decoder_did_not_exhaust_its_input[] = "#png: internal error: zlib decoder did not exhaust its input"; // ---------------- Private Consts #define WUFFS_PNG__ANCILLARY_BIT 32u static const uint8_t WUFFS_PNG__INTERLACING[8][6] WUFFS_BASE__POTENTIALLY_UNUSED = { { 0u, 0u, 0u, 0u, 0u, 0u, }, { 3u, 7u, 0u, 3u, 7u, 0u, }, { 3u, 3u, 4u, 3u, 7u, 0u, }, { 2u, 3u, 0u, 3u, 3u, 4u, }, { 2u, 1u, 2u, 2u, 3u, 0u, }, { 1u, 1u, 0u, 2u, 1u, 2u, }, { 1u, 0u, 1u, 1u, 1u, 0u, }, { 0u, 0u, 0u, 1u, 0u, 1u, }, }; static const uint8_t WUFFS_PNG__LOW_BIT_DEPTH_MULTIPLIERS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 255u, 85u, 0u, 17u, 0u, 0u, 0u, }; static const uint8_t WUFFS_PNG__LOW_BIT_DEPTH_NUM_PACKS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 8u, 4u, 0u, 2u, 0u, 0u, 0u, }; static const uint8_t WUFFS_PNG__NUM_CHANNELS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 1u, 0u, 3u, 1u, 2u, 0u, 4u, 0u, }; static const uint16_t WUFFS_PNG__LATIN_1[256] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 32u, 33u, 34u, 35u, 36u, 37u, 38u, 39u, 40u, 41u, 42u, 43u, 44u, 45u, 46u, 47u, 48u, 49u, 50u, 51u, 52u, 53u, 54u, 55u, 56u, 57u, 58u, 59u, 60u, 61u, 62u, 63u, 64u, 65u, 66u, 67u, 68u, 69u, 70u, 71u, 72u, 73u, 74u, 75u, 76u, 77u, 78u, 79u, 80u, 81u, 82u, 83u, 84u, 85u, 86u, 87u, 88u, 89u, 90u, 91u, 92u, 93u, 94u, 95u, 96u, 97u, 98u, 99u, 100u, 101u, 102u, 103u, 104u, 105u, 106u, 107u, 108u, 109u, 110u, 111u, 112u, 113u, 114u, 115u, 116u, 117u, 118u, 119u, 120u, 121u, 122u, 123u, 124u, 125u, 126u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 41410u, 41666u, 41922u, 42178u, 42434u, 42690u, 42946u, 43202u, 43458u, 43714u, 43970u, 44226u, 44482u, 44738u, 44994u, 45250u, 45506u, 45762u, 46018u, 46274u, 46530u, 46786u, 47042u, 47298u, 47554u, 47810u, 48066u, 48322u, 48578u, 48834u, 49090u, 32963u, 33219u, 33475u, 33731u, 33987u, 34243u, 34499u, 34755u, 35011u, 35267u, 35523u, 35779u, 36035u, 36291u, 36547u, 36803u, 37059u, 37315u, 37571u, 37827u, 38083u, 38339u, 38595u, 38851u, 39107u, 39363u, 39619u, 39875u, 40131u, 40387u, 40643u, 40899u, 41155u, 41411u, 41667u, 41923u, 42179u, 42435u, 42691u, 42947u, 43203u, 43459u, 43715u, 43971u, 44227u, 44483u, 44739u, 44995u, 45251u, 45507u, 45763u, 46019u, 46275u, 46531u, 46787u, 47043u, 47299u, 47555u, 47811u, 48067u, 48323u, 48579u, 48835u, 49091u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_2( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev); #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_image_config( wuffs_png__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_ihdr( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__assign_filter_distance( wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE static uint64_t wuffs_png__decoder__calculate_bytes_per_row( const wuffs_png__decoder* self, uint32_t a_width); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__choose_filter_implementations( wuffs_png__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_other_chunk( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src, bool a_framy); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_actl( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_chrm( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_exif( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_fctl( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_gama( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_iccp( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_plte( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_srgb( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_trns( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_frame_config( wuffs_png__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__skip_frame( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_frame( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_pass( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_tell_me_more( wuffs_png__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle__choosy_default( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle_tricky( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_png__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_png__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_png__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_png__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_png__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_png__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_png__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_png__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_png__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_png__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_png__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_png__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_png__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_png__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_png__decoder__initialize( wuffs_png__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_filter_1 = &wuffs_png__decoder__filter_1__choosy_default; self->private_impl.choosy_filter_3 = &wuffs_png__decoder__filter_3__choosy_default; self->private_impl.choosy_filter_4 = &wuffs_png__decoder__filter_4__choosy_default; self->private_impl.choosy_filter_and_swizzle = &wuffs_png__decoder__filter_and_swizzle__choosy_default; { wuffs_base__status z = wuffs_crc32__ieee_hasher__initialize( &self->private_data.f_crc32, sizeof(self->private_data.f_crc32), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_zlib__decoder__initialize( &self->private_data.f_zlib, sizeof(self->private_data.f_zlib), WUFFS_VERSION, options); if (z.repr) { return z; } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_png__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_png__decoder* wuffs_png__decoder__alloc(void) { wuffs_png__decoder* x = (wuffs_png__decoder*)(calloc(1, sizeof(wuffs_png__decoder))); if (!x) { return NULL; } if (wuffs_png__decoder__initialize( x, sizeof(wuffs_png__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_png__decoder(void) { return sizeof(wuffs_png__decoder); } // ---------------- Function Implementations // ‼ WUFFS MULTI-FILE SECTION +arm_neon // -------- func png.decoder.filter_1_distance_4_arm_neon #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { wuffs_base__slice_u8 v_curr = {0}; uint8x8_t v_fa = {0}; uint8x8_t v_fx = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, v_fa); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, v_fa); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; } v_curr.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, v_fa); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; } v_curr.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) // ‼ WUFFS MULTI-FILE SECTION -arm_neon // ‼ WUFFS MULTI-FILE SECTION +arm_neon // -------- func png.decoder.filter_3_distance_4_arm_neon #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint8x8_t v_fa = {0}; uint8x8_t v_fb = {0}; uint8x8_t v_fx = {0}; if (((uint64_t)(a_prev.len)) == 0u) { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; } v_curr.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; } v_curr.len = 0; } } else { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fx = vadd_u8(v_fx, vhadd_u8(v_fa, v_fb)); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) // ‼ WUFFS MULTI-FILE SECTION -arm_neon // ‼ WUFFS MULTI-FILE SECTION +arm_neon // -------- func png.decoder.filter_4_distance_3_arm_neon #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint8x8_t v_fa = {0}; uint8x8_t v_fb = {0}; uint8x8_t v_fc = {0}; uint8x8_t v_fx = {0}; uint16x8_t v_fafb = {0}; uint16x8_t v_fcfc = {0}; uint16x8_t v_pa = {0}; uint16x8_t v_pb = {0}; uint16x8_t v_pc = {0}; uint16x8_t v_cmpab = {0}; uint16x8_t v_cmpac = {0}; uint8x8_t v_picka = {0}; uint8x8_t v_pickb = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, wuffs_private_impl__iterate_total_advance((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)), 7, 6)); while (v_curr.ptr < i_end0_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 3; v_prev.ptr += 3; v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, wuffs_private_impl__iterate_total_advance((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)), 4, 3)); while (v_curr.ptr < i_end1_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 3; v_prev.len = 3; const uint8_t* i_end2_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end2_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u24le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u24le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) // ‼ WUFFS MULTI-FILE SECTION -arm_neon // ‼ WUFFS MULTI-FILE SECTION +arm_neon // -------- func png.decoder.filter_4_distance_4_arm_neon #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_arm_neon( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint8x8_t v_fa = {0}; uint8x8_t v_fb = {0}; uint8x8_t v_fc = {0}; uint8x8_t v_fx = {0}; uint16x8_t v_fafb = {0}; uint16x8_t v_fcfc = {0}; uint16x8_t v_pa = {0}; uint16x8_t v_pb = {0}; uint16x8_t v_pc = {0}; uint16x8_t v_cmpab = {0}; uint16x8_t v_cmpac = {0}; uint8x8_t v_picka = {0}; uint8x8_t v_pickb = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_fb = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_fx = vreinterpret_u8_u32(vdup_n_u32(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_fafb = vaddl_u8(v_fa, v_fb); v_fcfc = vaddl_u8(v_fc, v_fc); v_pa = vabdl_u8(v_fb, v_fc); v_pb = vabdl_u8(v_fa, v_fc); v_pc = vabdq_u16(v_fafb, v_fcfc); v_cmpab = vcleq_u16(v_pa, v_pb); v_cmpac = vcleq_u16(v_pa, v_pc); v_picka = vmovn_u16(vandq_u16(v_cmpab, v_cmpac)); v_pickb = vmovn_u16(vcleq_u16(v_pb, v_pc)); v_fx = vadd_u8(v_fx, vbsl_u8(v_picka, v_fa, vbsl_u8(v_pickb, v_fb, v_fc))); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, vget_lane_u32(vreinterpret_u32_u8(v_fx), 0u)); v_fc = v_fb; v_fa = v_fx; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) // ‼ WUFFS MULTI-FILE SECTION -arm_neon // -------- func png.decoder.filter_1 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { return (*self->private_impl.choosy_filter_1)(self, a_curr); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { uint64_t v_filter_distance = 0; uint8_t v_fa = 0; uint64_t v_i_start = 0; uint64_t v_i = 0; v_filter_distance = ((uint64_t)(self->private_impl.f_filter_distance)); v_i_start = 0u; while (v_i_start < v_filter_distance) { v_fa = 0u; v_i = v_i_start; while (v_i < ((uint64_t)(a_curr.len))) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + v_fa)); v_fa = a_curr.ptr[v_i]; v_i += v_filter_distance; } v_i_start += 1u; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_1_distance_3_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { wuffs_base__slice_u8 v_curr = {0}; uint8_t v_fa0 = 0; uint8_t v_fa1 = 0; uint8_t v_fa2 = 0; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 3; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 6) * 6)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(v_fa0 + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(v_fa1 + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(v_fa2 + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; v_fa0 = ((uint8_t)(v_fa0 + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(v_fa1 + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(v_fa2 + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; } v_curr.len = 3; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end1_curr) { v_fa0 = ((uint8_t)(v_fa0 + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(v_fa1 + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(v_fa2 + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; } v_curr.len = 0; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_1_distance_4_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { wuffs_base__slice_u8 v_curr = {0}; uint8_t v_fa0 = 0; uint8_t v_fa1 = 0; uint8_t v_fa2 = 0; uint8_t v_fa3 = 0; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(v_fa0 + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(v_fa1 + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(v_fa2 + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_fa3 = ((uint8_t)(v_fa3 + v_curr.ptr[3u])); v_curr.ptr[3u] = v_fa3; v_curr.ptr += 4; } v_curr.len = 0; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_2 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_2( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { uint64_t v_n = 0; uint64_t v_i = 0; v_n = wuffs_base__u64__min(((uint64_t)(a_curr.len)), ((uint64_t)(a_prev.len))); v_i = 0u; while (v_i < v_n) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + a_prev.ptr[v_i])); v_i += 1u; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_3 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { return (*self->private_impl.choosy_filter_3)(self, a_curr, a_prev); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { uint64_t v_filter_distance = 0; uint64_t v_n = 0; uint64_t v_i = 0; v_filter_distance = ((uint64_t)(self->private_impl.f_filter_distance)); if (((uint64_t)(a_prev.len)) == 0u) { v_i = v_filter_distance; while (v_i < ((uint64_t)(a_curr.len))) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + ((uint8_t)(a_curr.ptr[(v_i - v_filter_distance)] / 2u)))); v_i += 1u; } } else { v_n = wuffs_base__u64__min(((uint64_t)(a_curr.len)), ((uint64_t)(a_prev.len))); v_i = 0u; while ((v_i < v_n) && (v_i < v_filter_distance)) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + ((uint8_t)(a_prev.ptr[v_i] / 2u)))); v_i += 1u; } v_i = v_filter_distance; while (v_i < v_n) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + ((uint8_t)(((((uint32_t)(a_curr.ptr[(v_i - v_filter_distance)])) + ((uint32_t)(a_prev.ptr[v_i]))) / 2u))))); v_i += 1u; } } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_3_distance_3_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint8_t v_fa0 = 0; uint8_t v_fa1 = 0; uint8_t v_fa2 = 0; if (((uint64_t)(a_prev.len)) == 0u) { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 3; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 6) * 6)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(((uint8_t)(v_fa0 / 2u)) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(v_fa1 / 2u)) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(v_fa2 / 2u)) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; v_fa0 = ((uint8_t)(((uint8_t)(v_fa0 / 2u)) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(v_fa1 / 2u)) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(v_fa2 / 2u)) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; } v_curr.len = 3; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end1_curr) { v_fa0 = ((uint8_t)(((uint8_t)(v_fa0 / 2u)) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(v_fa1 / 2u)) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(v_fa2 / 2u)) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; } v_curr.len = 0; } } else { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 3; v_prev.len = 3; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 6) * 6)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa0)) + ((uint32_t)(v_prev.ptr[0u]))) / 2u))) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa1)) + ((uint32_t)(v_prev.ptr[1u]))) / 2u))) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa2)) + ((uint32_t)(v_prev.ptr[2u]))) / 2u))) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; v_prev.ptr += 3; v_fa0 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa0)) + ((uint32_t)(v_prev.ptr[0u]))) / 2u))) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa1)) + ((uint32_t)(v_prev.ptr[1u]))) / 2u))) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa2)) + ((uint32_t)(v_prev.ptr[2u]))) / 2u))) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 3; v_prev.len = 3; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end1_curr) { v_fa0 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa0)) + ((uint32_t)(v_prev.ptr[0u]))) / 2u))) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa1)) + ((uint32_t)(v_prev.ptr[1u]))) / 2u))) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa2)) + ((uint32_t)(v_prev.ptr[2u]))) / 2u))) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 0; v_prev.len = 0; } } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_3_distance_4_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint8_t v_fa0 = 0; uint8_t v_fa1 = 0; uint8_t v_fa2 = 0; uint8_t v_fa3 = 0; if (((uint64_t)(a_prev.len)) == 0u) { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(((uint8_t)(v_fa0 / 2u)) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(v_fa1 / 2u)) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(v_fa2 / 2u)) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_fa3 = ((uint8_t)(((uint8_t)(v_fa3 / 2u)) + v_curr.ptr[3u])); v_curr.ptr[3u] = v_fa3; v_curr.ptr += 4; } v_curr.len = 0; } } else { { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end0_curr) { v_fa0 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa0)) + ((uint32_t)(v_prev.ptr[0u]))) / 2u))) + v_curr.ptr[0u])); v_curr.ptr[0u] = v_fa0; v_fa1 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa1)) + ((uint32_t)(v_prev.ptr[1u]))) / 2u))) + v_curr.ptr[1u])); v_curr.ptr[1u] = v_fa1; v_fa2 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa2)) + ((uint32_t)(v_prev.ptr[2u]))) / 2u))) + v_curr.ptr[2u])); v_curr.ptr[2u] = v_fa2; v_fa3 = ((uint8_t)(((uint8_t)(((((uint32_t)(v_fa3)) + ((uint32_t)(v_prev.ptr[3u]))) / 2u))) + v_curr.ptr[3u])); v_curr.ptr[3u] = v_fa3; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_4 WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { return (*self->private_impl.choosy_filter_4)(self, a_curr, a_prev); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4__choosy_default( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { uint64_t v_filter_distance = 0; uint64_t v_n = 0; uint64_t v_i = 0; uint32_t v_fa = 0; uint32_t v_fb = 0; uint32_t v_fc = 0; uint32_t v_pp = 0; uint32_t v_pa = 0; uint32_t v_pb = 0; uint32_t v_pc = 0; v_filter_distance = ((uint64_t)(self->private_impl.f_filter_distance)); v_n = wuffs_base__u64__min(((uint64_t)(a_curr.len)), ((uint64_t)(a_prev.len))); v_i = 0u; while ((v_i < v_n) && (v_i < v_filter_distance)) { a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + a_prev.ptr[v_i])); v_i += 1u; } v_i = v_filter_distance; while (v_i < v_n) { v_fa = ((uint32_t)(a_curr.ptr[(v_i - v_filter_distance)])); v_fb = ((uint32_t)(a_prev.ptr[v_i])); v_fc = ((uint32_t)(a_prev.ptr[(v_i - v_filter_distance)])); v_pp = ((uint32_t)(((uint32_t)(v_fa + v_fb)) - v_fc)); v_pa = ((uint32_t)(v_pp - v_fa)); if (v_pa >= 2147483648u) { v_pa = ((uint32_t)(0u - v_pa)); } v_pb = ((uint32_t)(v_pp - v_fb)); if (v_pb >= 2147483648u) { v_pb = ((uint32_t)(0u - v_pb)); } v_pc = ((uint32_t)(v_pp - v_fc)); if (v_pc >= 2147483648u) { v_pc = ((uint32_t)(0u - v_pc)); } if ((v_pa <= v_pb) && (v_pa <= v_pc)) { } else if (v_pb <= v_pc) { v_fa = v_fb; } else { v_fa = v_fc; } a_curr.ptr[v_i] = ((uint8_t)(a_curr.ptr[v_i] + ((uint8_t)(v_fa)))); v_i += 1u; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_4_distance_3_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint32_t v_fa0 = 0; uint32_t v_fa1 = 0; uint32_t v_fa2 = 0; uint32_t v_fb0 = 0; uint32_t v_fb1 = 0; uint32_t v_fb2 = 0; uint32_t v_fc0 = 0; uint32_t v_fc1 = 0; uint32_t v_fc2 = 0; uint32_t v_pp0 = 0; uint32_t v_pp1 = 0; uint32_t v_pp2 = 0; uint32_t v_pa0 = 0; uint32_t v_pa1 = 0; uint32_t v_pa2 = 0; uint32_t v_pb0 = 0; uint32_t v_pb1 = 0; uint32_t v_pb2 = 0; uint32_t v_pc0 = 0; uint32_t v_pc1 = 0; uint32_t v_pc2 = 0; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 3; v_prev.len = 3; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end0_curr) { v_fb0 = ((uint32_t)(v_prev.ptr[0u])); v_pp0 = ((uint32_t)(((uint32_t)(v_fa0 + v_fb0)) - v_fc0)); v_pa0 = ((uint32_t)(v_pp0 - v_fa0)); if (v_pa0 >= 2147483648u) { v_pa0 = ((uint32_t)(0u - v_pa0)); } v_pb0 = ((uint32_t)(v_pp0 - v_fb0)); if (v_pb0 >= 2147483648u) { v_pb0 = ((uint32_t)(0u - v_pb0)); } v_pc0 = ((uint32_t)(v_pp0 - v_fc0)); if (v_pc0 >= 2147483648u) { v_pc0 = ((uint32_t)(0u - v_pc0)); } if ((v_pa0 <= v_pb0) && (v_pa0 <= v_pc0)) { } else if (v_pb0 <= v_pc0) { v_fa0 = v_fb0; } else { v_fa0 = v_fc0; } v_curr.ptr[0u] = ((uint8_t)(v_curr.ptr[0u] + ((uint8_t)(v_fa0)))); v_fa0 = ((uint32_t)(v_curr.ptr[0u])); v_fc0 = v_fb0; v_fb1 = ((uint32_t)(v_prev.ptr[1u])); v_pp1 = ((uint32_t)(((uint32_t)(v_fa1 + v_fb1)) - v_fc1)); v_pa1 = ((uint32_t)(v_pp1 - v_fa1)); if (v_pa1 >= 2147483648u) { v_pa1 = ((uint32_t)(0u - v_pa1)); } v_pb1 = ((uint32_t)(v_pp1 - v_fb1)); if (v_pb1 >= 2147483648u) { v_pb1 = ((uint32_t)(0u - v_pb1)); } v_pc1 = ((uint32_t)(v_pp1 - v_fc1)); if (v_pc1 >= 2147483648u) { v_pc1 = ((uint32_t)(0u - v_pc1)); } if ((v_pa1 <= v_pb1) && (v_pa1 <= v_pc1)) { } else if (v_pb1 <= v_pc1) { v_fa1 = v_fb1; } else { v_fa1 = v_fc1; } v_curr.ptr[1u] = ((uint8_t)(v_curr.ptr[1u] + ((uint8_t)(v_fa1)))); v_fa1 = ((uint32_t)(v_curr.ptr[1u])); v_fc1 = v_fb1; v_fb2 = ((uint32_t)(v_prev.ptr[2u])); v_pp2 = ((uint32_t)(((uint32_t)(v_fa2 + v_fb2)) - v_fc2)); v_pa2 = ((uint32_t)(v_pp2 - v_fa2)); if (v_pa2 >= 2147483648u) { v_pa2 = ((uint32_t)(0u - v_pa2)); } v_pb2 = ((uint32_t)(v_pp2 - v_fb2)); if (v_pb2 >= 2147483648u) { v_pb2 = ((uint32_t)(0u - v_pb2)); } v_pc2 = ((uint32_t)(v_pp2 - v_fc2)); if (v_pc2 >= 2147483648u) { v_pc2 = ((uint32_t)(0u - v_pc2)); } if ((v_pa2 <= v_pb2) && (v_pa2 <= v_pc2)) { } else if (v_pb2 <= v_pc2) { v_fa2 = v_fb2; } else { v_fa2 = v_fc2; } v_curr.ptr[2u] = ((uint8_t)(v_curr.ptr[2u] + ((uint8_t)(v_fa2)))); v_fa2 = ((uint32_t)(v_curr.ptr[2u])); v_fc2 = v_fb2; v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.filter_4_distance_4_fallback WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_fallback( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; uint32_t v_fa0 = 0; uint32_t v_fa1 = 0; uint32_t v_fa2 = 0; uint32_t v_fa3 = 0; uint32_t v_fb0 = 0; uint32_t v_fb1 = 0; uint32_t v_fb2 = 0; uint32_t v_fb3 = 0; uint32_t v_fc0 = 0; uint32_t v_fc1 = 0; uint32_t v_fc2 = 0; uint32_t v_fc3 = 0; uint32_t v_pp0 = 0; uint32_t v_pp1 = 0; uint32_t v_pp2 = 0; uint32_t v_pp3 = 0; uint32_t v_pa0 = 0; uint32_t v_pa1 = 0; uint32_t v_pa2 = 0; uint32_t v_pa3 = 0; uint32_t v_pb0 = 0; uint32_t v_pb1 = 0; uint32_t v_pb2 = 0; uint32_t v_pb3 = 0; uint32_t v_pc0 = 0; uint32_t v_pc1 = 0; uint32_t v_pc2 = 0; uint32_t v_pc3 = 0; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end0_curr) { v_fb0 = ((uint32_t)(v_prev.ptr[0u])); v_pp0 = ((uint32_t)(((uint32_t)(v_fa0 + v_fb0)) - v_fc0)); v_pa0 = ((uint32_t)(v_pp0 - v_fa0)); if (v_pa0 >= 2147483648u) { v_pa0 = ((uint32_t)(0u - v_pa0)); } v_pb0 = ((uint32_t)(v_pp0 - v_fb0)); if (v_pb0 >= 2147483648u) { v_pb0 = ((uint32_t)(0u - v_pb0)); } v_pc0 = ((uint32_t)(v_pp0 - v_fc0)); if (v_pc0 >= 2147483648u) { v_pc0 = ((uint32_t)(0u - v_pc0)); } if ((v_pa0 <= v_pb0) && (v_pa0 <= v_pc0)) { } else if (v_pb0 <= v_pc0) { v_fa0 = v_fb0; } else { v_fa0 = v_fc0; } v_curr.ptr[0u] = ((uint8_t)(v_curr.ptr[0u] + ((uint8_t)(v_fa0)))); v_fa0 = ((uint32_t)(v_curr.ptr[0u])); v_fc0 = v_fb0; v_fb1 = ((uint32_t)(v_prev.ptr[1u])); v_pp1 = ((uint32_t)(((uint32_t)(v_fa1 + v_fb1)) - v_fc1)); v_pa1 = ((uint32_t)(v_pp1 - v_fa1)); if (v_pa1 >= 2147483648u) { v_pa1 = ((uint32_t)(0u - v_pa1)); } v_pb1 = ((uint32_t)(v_pp1 - v_fb1)); if (v_pb1 >= 2147483648u) { v_pb1 = ((uint32_t)(0u - v_pb1)); } v_pc1 = ((uint32_t)(v_pp1 - v_fc1)); if (v_pc1 >= 2147483648u) { v_pc1 = ((uint32_t)(0u - v_pc1)); } if ((v_pa1 <= v_pb1) && (v_pa1 <= v_pc1)) { } else if (v_pb1 <= v_pc1) { v_fa1 = v_fb1; } else { v_fa1 = v_fc1; } v_curr.ptr[1u] = ((uint8_t)(v_curr.ptr[1u] + ((uint8_t)(v_fa1)))); v_fa1 = ((uint32_t)(v_curr.ptr[1u])); v_fc1 = v_fb1; v_fb2 = ((uint32_t)(v_prev.ptr[2u])); v_pp2 = ((uint32_t)(((uint32_t)(v_fa2 + v_fb2)) - v_fc2)); v_pa2 = ((uint32_t)(v_pp2 - v_fa2)); if (v_pa2 >= 2147483648u) { v_pa2 = ((uint32_t)(0u - v_pa2)); } v_pb2 = ((uint32_t)(v_pp2 - v_fb2)); if (v_pb2 >= 2147483648u) { v_pb2 = ((uint32_t)(0u - v_pb2)); } v_pc2 = ((uint32_t)(v_pp2 - v_fc2)); if (v_pc2 >= 2147483648u) { v_pc2 = ((uint32_t)(0u - v_pc2)); } if ((v_pa2 <= v_pb2) && (v_pa2 <= v_pc2)) { } else if (v_pb2 <= v_pc2) { v_fa2 = v_fb2; } else { v_fa2 = v_fc2; } v_curr.ptr[2u] = ((uint8_t)(v_curr.ptr[2u] + ((uint8_t)(v_fa2)))); v_fa2 = ((uint32_t)(v_curr.ptr[2u])); v_fc2 = v_fb2; v_fb3 = ((uint32_t)(v_prev.ptr[3u])); v_pp3 = ((uint32_t)(((uint32_t)(v_fa3 + v_fb3)) - v_fc3)); v_pa3 = ((uint32_t)(v_pp3 - v_fa3)); if (v_pa3 >= 2147483648u) { v_pa3 = ((uint32_t)(0u - v_pa3)); } v_pb3 = ((uint32_t)(v_pp3 - v_fb3)); if (v_pb3 >= 2147483648u) { v_pb3 = ((uint32_t)(0u - v_pb3)); } v_pc3 = ((uint32_t)(v_pp3 - v_fc3)); if (v_pc3 >= 2147483648u) { v_pc3 = ((uint32_t)(0u - v_pc3)); } if ((v_pa3 <= v_pb3) && (v_pa3 <= v_pc3)) { } else if (v_pb3 <= v_pc3) { v_fa3 = v_fb3; } else { v_fa3 = v_fc3; } v_curr.ptr[3u] = ((uint8_t)(v_curr.ptr[3u] + ((uint8_t)(v_fa3)))); v_fa3 = ((uint32_t)(v_curr.ptr[3u])); v_fc3 = v_fb3; v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func png.decoder.filter_1_distance_4_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_1_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr) { wuffs_base__slice_u8 v_curr = {0}; __m128i v_x128 = {0}; __m128i v_a128 = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_a128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_a128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; } v_curr.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_a128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; } v_curr.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func png.decoder.filter_3_distance_4_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_3_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; __m128i v_x128 = {0}; __m128i v_a128 = {0}; __m128i v_b128 = {0}; __m128i v_p128 = {0}; __m128i v_k128 = {0}; if (((uint64_t)(a_prev.len)) == 0u) { v_k128 = _mm_set1_epi8((int8_t)(254u)); { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; v_curr.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_p128 = _mm_avg_epu8(_mm_and_si128(v_a128, v_k128), v_b128); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_p128 = _mm_avg_epu8(_mm_and_si128(v_a128, v_k128), v_b128); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; } v_curr.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_p128 = _mm_avg_epu8(_mm_and_si128(v_a128, v_k128), v_b128); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; } v_curr.len = 0; } } else { v_k128 = _mm_set1_epi8((int8_t)(1u)); { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_p128 = _mm_avg_epu8(v_a128, v_b128); v_p128 = _mm_sub_epi8(v_p128, _mm_and_si128(v_k128, _mm_xor_si128(v_a128, v_b128))); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_p128 = _mm_avg_epu8(v_a128, v_b128); v_p128 = _mm_sub_epi8(v_p128, _mm_and_si128(v_k128, _mm_xor_si128(v_a128, v_b128))); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_p128 = _mm_avg_epu8(v_a128, v_b128); v_p128 = _mm_sub_epi8(v_p128, _mm_and_si128(v_k128, _mm_xor_si128(v_a128, v_b128))); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func png.decoder.filter_4_distance_3_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_3_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; __m128i v_x128 = {0}; __m128i v_a128 = {0}; __m128i v_b128 = {0}; __m128i v_c128 = {0}; __m128i v_p128 = {0}; __m128i v_pa128 = {0}; __m128i v_pb128 = {0}; __m128i v_pc128 = {0}; __m128i v_smallest128 = {0}; __m128i v_z128 = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, wuffs_private_impl__iterate_total_advance((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)), 7, 6)); while (v_curr.ptr < i_end0_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 3; v_prev.ptr += 3; v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, wuffs_private_impl__iterate_total_advance((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)), 4, 3)); while (v_curr.ptr < i_end1_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 3; v_prev.len = 3; const uint8_t* i_end2_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 3) * 3)); while (v_curr.ptr < i_end2_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u24le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u24le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u24le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 3; v_prev.ptr += 3; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 // ‼ WUFFS MULTI-FILE SECTION +x86_sse42 // -------- func png.decoder.filter_4_distance_4_x86_sse42 #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) WUFFS_BASE__MAYBE_ATTRIBUTE_TARGET("pclmul,popcnt,sse4.2") WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__filter_4_distance_4_x86_sse42( wuffs_png__decoder* self, wuffs_base__slice_u8 a_curr, wuffs_base__slice_u8 a_prev) { wuffs_base__slice_u8 v_curr = {0}; wuffs_base__slice_u8 v_prev = {0}; __m128i v_x128 = {0}; __m128i v_a128 = {0}; __m128i v_b128 = {0}; __m128i v_c128 = {0}; __m128i v_p128 = {0}; __m128i v_pa128 = {0}; __m128i v_pb128 = {0}; __m128i v_pc128 = {0}; __m128i v_smallest128 = {0}; __m128i v_z128 = {0}; { wuffs_base__slice_u8 i_slice_curr = a_curr; v_curr.ptr = i_slice_curr.ptr; wuffs_base__slice_u8 i_slice_prev = a_prev; v_prev.ptr = i_slice_prev.ptr; i_slice_curr.len = ((size_t)(wuffs_base__u64__min(i_slice_curr.len, i_slice_prev.len))); v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end0_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 8) * 8)); while (v_curr.ptr < i_end0_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 4; v_prev.len = 4; const uint8_t* i_end1_curr = wuffs_private_impl__ptr_u8_plus_len(v_curr.ptr, (((i_slice_curr.len - (size_t)(v_curr.ptr - i_slice_curr.ptr)) / 4) * 4)); while (v_curr.ptr < i_end1_curr) { v_b128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_prev.ptr))); v_b128 = _mm_unpacklo_epi8(v_b128, v_z128); v_pa128 = _mm_sub_epi16(v_b128, v_c128); v_pb128 = _mm_sub_epi16(v_a128, v_c128); v_pc128 = _mm_add_epi16(v_pa128, v_pb128); v_pa128 = _mm_abs_epi16(v_pa128); v_pb128 = _mm_abs_epi16(v_pb128); v_pc128 = _mm_abs_epi16(v_pc128); v_smallest128 = _mm_min_epi16(v_pc128, _mm_min_epi16(v_pb128, v_pa128)); v_p128 = _mm_blendv_epi8(_mm_blendv_epi8(v_c128, v_b128, _mm_cmpeq_epi16(v_smallest128, v_pb128)), v_a128, _mm_cmpeq_epi16(v_smallest128, v_pa128)); v_x128 = _mm_cvtsi32_si128((int32_t)(wuffs_base__peek_u32le__no_bounds_check(v_curr.ptr))); v_x128 = _mm_unpacklo_epi8(v_x128, v_z128); v_x128 = _mm_add_epi8(v_x128, v_p128); v_a128 = v_x128; v_c128 = v_b128; v_x128 = _mm_packus_epi16(v_x128, v_x128); wuffs_base__poke_u32le__no_bounds_check(v_curr.ptr, ((uint32_t)(_mm_cvtsi128_si32(v_x128)))); v_curr.ptr += 4; v_prev.ptr += 4; } v_curr.len = 0; v_prev.len = 0; } return wuffs_base__make_empty_struct(); } #endif // defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) // ‼ WUFFS MULTI-FILE SECTION -x86_sse42 // -------- func png.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__get_quirk( const wuffs_png__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if ((a_key == 1u) && self->private_impl.f_ignore_checksum) { return 1u; } return 0u; } // -------- func png.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__set_quirk( wuffs_png__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); wuffs_zlib__decoder__set_quirk(&self->private_data.f_zlib, a_key, a_value); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func png.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_image_config( wuffs_png__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_png__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_png__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func png.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_image_config( wuffs_png__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_magic = 0; uint64_t v_mark = 0; uint32_t v_checksum_have = 0; uint32_t v_checksum_want = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; if (coro_susp_point) { v_checksum_have = self->private_data.s_do_decode_image_config.v_checksum_have; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if ( ! self->private_impl.f_seen_ihdr) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_0 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 56) { t_0 = ((uint64_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_magic = t_0; } if (v_magic != 727905341920923785u) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint64_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_1 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 56) { t_1 = ((uint64_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_magic = t_1; } if (v_magic != 5927942488114331648u) { if (v_magic == 5278895250759221248u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_cgbi_extension); goto exit; } status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } self->private_impl.f_chunk_type_array[0u] = 73u; self->private_impl.f_chunk_type_array[1u] = 72u; self->private_impl.f_chunk_type_array[2u] = 68u; self->private_impl.f_chunk_type_array[3u] = 82u; wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__make_slice_u8(self->private_impl.f_chunk_type_array, 4)); while (true) { v_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_png__decoder__decode_ihdr(self, a_src); v_status = t_2; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum) { v_checksum_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_3); if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch >> 32)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)); } } v_checksum_want = t_3; } if ( ! self->private_impl.f_ignore_checksum && (v_checksum_have != v_checksum_want)) { status = wuffs_base__make_status(wuffs_png__error__bad_checksum); goto exit; } self->private_impl.f_seen_ihdr = true; } else if (self->private_impl.f_metadata_fourcc != 0u) { self->private_impl.f_call_sequence = 16u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) < 8u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); continue; } self->private_impl.f_chunk_length = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); self->private_impl.f_chunk_type = ((uint32_t)((wuffs_base__peek_u64le__no_bounds_check(iop_a_src) >> 32u))); if (self->private_impl.f_chunk_type == 1413563465u) { if ( ! self->private_impl.f_seen_actl || self->private_impl.f_seen_fctl) { break; } self->private_impl.f_seen_idat = true; } else if (self->private_impl.f_chunk_type == 1413571686u) { if (self->private_impl.f_seen_idat && self->private_impl.f_seen_fctl) { break; } status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } iop_a_src += 8u; if ( ! self->private_impl.f_ignore_checksum && ((self->private_impl.f_chunk_type & 32u) == 0u)) { self->private_impl.f_chunk_type_array[0u] = ((uint8_t)((self->private_impl.f_chunk_type >> 0u))); self->private_impl.f_chunk_type_array[1u] = ((uint8_t)((self->private_impl.f_chunk_type >> 8u))); self->private_impl.f_chunk_type_array[2u] = ((uint8_t)((self->private_impl.f_chunk_type >> 16u))); self->private_impl.f_chunk_type_array[3u] = ((uint8_t)((self->private_impl.f_chunk_type >> 24u))); wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__make_slice_u8(self->private_impl.f_chunk_type_array, 4)); } while (true) { v_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_4 = wuffs_png__decoder__decode_other_chunk(self, a_src, false); v_status = t_4; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum && ((self->private_impl.f_chunk_type & 32u) == 0u)) { v_checksum_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); } if (self->private_impl.f_metadata_fourcc != 0u) { self->private_impl.f_call_sequence = 16u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); uint32_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_5 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_5); if (num_bits_5 == 24) { t_5 = ((uint32_t)(*scratch >> 32)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)); } } v_checksum_want = t_5; } if ( ! self->private_impl.f_ignore_checksum && ((self->private_impl.f_chunk_type & 32u) == 0u) && (v_checksum_have != v_checksum_want)) { status = wuffs_base__make_status(wuffs_png__error__bad_checksum); goto exit; } } if ((self->private_impl.f_color_type == 3u) && ! self->private_impl.f_seen_plte) { status = wuffs_base__make_status(wuffs_png__error__missing_palette); goto exit; } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); self->private_impl.f_first_config_io_position = self->private_impl.f_frame_config_io_position; if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_dst_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_first_config_io_position, ((self->private_impl.f_color_type <= 3u) && ! self->private_impl.f_seen_trns)); } if ( ! self->private_impl.f_seen_actl) { self->private_impl.f_num_animation_frames_value = 1u; self->private_impl.f_first_rect_x0 = 0u; self->private_impl.f_first_rect_y0 = 0u; self->private_impl.f_first_rect_x1 = self->private_impl.f_width; self->private_impl.f_first_rect_y1 = self->private_impl.f_height; self->private_impl.f_first_duration = 0u; self->private_impl.f_first_disposal = 0u; self->private_impl.f_first_overwrite_instead_of_blend = false; } self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_image_config.v_checksum_have = v_checksum_have; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_ihdr WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_ihdr( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_a32 = 0; uint8_t v_a8 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_ihdr; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_ihdr.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_ihdr.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_a32 = t_0; } if ((v_a32 == 0u) || (v_a32 > 2147483647u)) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } else if (v_a32 > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_width = v_a32; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_ihdr.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_ihdr.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_a32 = t_1; } if ((v_a32 == 0u) || (v_a32 > 2147483647u)) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } else if (v_a32 > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_height = v_a32; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_a8 = t_2; } if (v_a8 > 16u) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } self->private_impl.f_depth = v_a8; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_a8 = t_3; } if ((v_a8 == 1u) || (v_a8 == 5u) || (v_a8 > 6u)) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } self->private_impl.f_color_type = v_a8; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_a8 = t_4; } if (v_a8 != 0u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_compression_method); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_a8 = t_5; } if (v_a8 != 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_a8 = t_6; } if (v_a8 == 0u) { self->private_impl.f_interlace_pass = 0u; } else if (v_a8 == 1u) { self->private_impl.f_interlace_pass = 1u; self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); } else { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } self->private_impl.f_filter_distance = 0u; wuffs_png__decoder__assign_filter_distance(self); if (self->private_impl.f_filter_distance == 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_header); goto exit; } self->private_impl.f_overall_workbuf_length = (((uint64_t)(self->private_impl.f_height)) * (1u + wuffs_png__decoder__calculate_bytes_per_row(self, self->private_impl.f_width))); wuffs_png__decoder__choose_filter_implementations(self); goto ok; ok: self->private_impl.p_decode_ihdr = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_ihdr = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.assign_filter_distance WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__assign_filter_distance( wuffs_png__decoder* self) { if (self->private_impl.f_depth < 8u) { if ((self->private_impl.f_depth != 1u) && (self->private_impl.f_depth != 2u) && (self->private_impl.f_depth != 4u)) { return wuffs_base__make_empty_struct(); } else if (self->private_impl.f_color_type == 0u) { self->private_impl.f_dst_pixfmt = 536870920u; self->private_impl.f_src_pixfmt = 536870920u; } else if (self->private_impl.f_color_type == 3u) { self->private_impl.f_dst_pixfmt = 2198077448u; self->private_impl.f_src_pixfmt = 2198077448u; } else { return wuffs_base__make_empty_struct(); } self->private_impl.f_filter_distance = 1u; self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); } else if (self->private_impl.f_color_type == 0u) { if (self->private_impl.f_depth == 8u) { self->private_impl.f_dst_pixfmt = 536870920u; self->private_impl.f_src_pixfmt = 536870920u; self->private_impl.f_filter_distance = 1u; } else if (self->private_impl.f_depth == 16u) { if (self->private_impl.f_interlace_pass == 0u) { self->private_impl.f_dst_pixfmt = 536870923u; self->private_impl.f_src_pixfmt = 537919499u; } else { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; } self->private_impl.f_filter_distance = 2u; } } else if (self->private_impl.f_color_type == 2u) { if (self->private_impl.f_depth == 8u) { self->private_impl.f_dst_pixfmt = 2147485832u; self->private_impl.f_src_pixfmt = 2684356744u; self->private_impl.f_filter_distance = 3u; } else if (self->private_impl.f_depth == 16u) { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; self->private_impl.f_filter_distance = 6u; self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); } } else if (self->private_impl.f_color_type == 3u) { if (self->private_impl.f_depth == 8u) { self->private_impl.f_dst_pixfmt = 2198077448u; self->private_impl.f_src_pixfmt = 2198077448u; self->private_impl.f_filter_distance = 1u; } } else if (self->private_impl.f_color_type == 4u) { if (self->private_impl.f_depth == 8u) { self->private_impl.f_dst_pixfmt = 553648264u; self->private_impl.f_src_pixfmt = 553648264u; self->private_impl.f_filter_distance = 2u; } else if (self->private_impl.f_depth == 16u) { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; self->private_impl.f_filter_distance = 4u; self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); } } else if (self->private_impl.f_color_type == 6u) { if (self->private_impl.f_depth == 8u) { self->private_impl.f_dst_pixfmt = 2164295816u; self->private_impl.f_src_pixfmt = 2701166728u; self->private_impl.f_filter_distance = 4u; } else if (self->private_impl.f_depth == 16u) { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; self->private_impl.f_filter_distance = 8u; self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); } } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.calculate_bytes_per_row WUFFS_BASE__GENERATED_C_CODE static uint64_t wuffs_png__decoder__calculate_bytes_per_row( const wuffs_png__decoder* self, uint32_t a_width) { uint64_t v_bytes_per_channel = 0; if (self->private_impl.f_depth == 1u) { return ((uint64_t)(((a_width + 7u) / 8u))); } else if (self->private_impl.f_depth == 2u) { return ((uint64_t)(((a_width + 3u) / 4u))); } else if (self->private_impl.f_depth == 4u) { return ((uint64_t)(((a_width + 1u) / 2u))); } v_bytes_per_channel = ((uint64_t)(((uint8_t)(self->private_impl.f_depth >> 3u)))); return (((uint64_t)(a_width)) * v_bytes_per_channel * ((uint64_t)(WUFFS_PNG__NUM_CHANNELS[self->private_impl.f_color_type]))); } // -------- func png.decoder.choose_filter_implementations WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_png__decoder__choose_filter_implementations( wuffs_png__decoder* self) { if (self->private_impl.f_filter_distance == 3u) { self->private_impl.choosy_filter_1 = ( &wuffs_png__decoder__filter_1_distance_3_fallback); self->private_impl.choosy_filter_3 = ( &wuffs_png__decoder__filter_3_distance_3_fallback); self->private_impl.choosy_filter_4 = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) wuffs_base__cpu_arch__have_arm_neon() ? &wuffs_png__decoder__filter_4_distance_3_arm_neon : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_png__decoder__filter_4_distance_3_x86_sse42 : #endif &wuffs_png__decoder__filter_4_distance_3_fallback); } else if (self->private_impl.f_filter_distance == 4u) { self->private_impl.choosy_filter_1 = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) wuffs_base__cpu_arch__have_arm_neon() ? &wuffs_png__decoder__filter_1_distance_4_arm_neon : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_png__decoder__filter_1_distance_4_x86_sse42 : #endif &wuffs_png__decoder__filter_1_distance_4_fallback); self->private_impl.choosy_filter_3 = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) wuffs_base__cpu_arch__have_arm_neon() ? &wuffs_png__decoder__filter_3_distance_4_arm_neon : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_png__decoder__filter_3_distance_4_x86_sse42 : #endif &wuffs_png__decoder__filter_3_distance_4_fallback); self->private_impl.choosy_filter_4 = ( #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__ARM_NEON) wuffs_base__cpu_arch__have_arm_neon() ? &wuffs_png__decoder__filter_4_distance_4_arm_neon : #endif #if defined(WUFFS_PRIVATE_IMPL__CPU_ARCH__X86_64_V2) wuffs_base__cpu_arch__have_x86_sse42() ? &wuffs_png__decoder__filter_4_distance_4_x86_sse42 : #endif &wuffs_png__decoder__filter_4_distance_4_fallback); } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.decode_other_chunk WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_other_chunk( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src, bool a_framy) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_other_chunk; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_chunk_type == 1163152464u) && ! a_framy) { if (self->private_impl.f_seen_plte) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } else if (self->private_impl.f_color_type == 3u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_png__decoder__decode_plte(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if ((self->private_impl.f_color_type == 2u) || (self->private_impl.f_color_type == 6u)) { } else { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_seen_plte = true; } else if ((self->private_impl.f_chunk_type & 32u) == 0u) { if (self->private_impl.f_chunk_type != 1413563465u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } } if (self->private_impl.f_chunk_type == 1716082789u) { if (self->private_impl.f_report_metadata_exif) { if (self->private_impl.f_seen_exif) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_png__decoder__decode_exif(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_exif = true; } } else if ((self->private_impl.f_chunk_type == 1951945833u) || (self->private_impl.f_chunk_type == 1951942004u) || (self->private_impl.f_chunk_type == 1951945850u)) { if (self->private_impl.f_report_metadata_kvp) { self->private_impl.f_metadata_flavor = 4u; self->private_impl.f_metadata_fourcc = 1263947851u; self->private_impl.f_metadata_x = 0u; self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; } } else if ( ! a_framy) { if (self->private_impl.f_chunk_type == 1280598881u) { if (self->private_impl.f_seen_actl) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_png__decoder__decode_actl(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_actl = true; } else if (self->private_impl.f_chunk_type == 1297238115u) { if (self->private_impl.f_report_metadata_chrm) { if (self->private_impl.f_seen_chrm) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_png__decoder__decode_chrm(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_chrm = true; } } else if (self->private_impl.f_chunk_type == 1280598886u) { if (self->private_impl.f_seen_fctl) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); status = wuffs_png__decoder__decode_fctl(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_fctl = true; } else if (self->private_impl.f_chunk_type == 1095582055u) { if (self->private_impl.f_report_metadata_gama) { if (self->private_impl.f_seen_gama) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); status = wuffs_png__decoder__decode_gama(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_gama = true; } } else if (self->private_impl.f_chunk_type == 1346585449u) { if (self->private_impl.f_report_metadata_iccp) { if (self->private_impl.f_seen_iccp) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); status = wuffs_png__decoder__decode_iccp(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_iccp = true; } } else if (self->private_impl.f_chunk_type == 1111970419u) { if (self->private_impl.f_report_metadata_srgb) { if (self->private_impl.f_seen_srgb) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_png__decoder__decode_srgb(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_seen_srgb = true; } } else if (self->private_impl.f_chunk_type == 1397641844u) { if (self->private_impl.f_seen_trns || ((self->private_impl.f_color_type == 3u) && ! self->private_impl.f_seen_plte)) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } else if (self->private_impl.f_color_type > 3u) { } else { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_png__decoder__decode_trns(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } self->private_impl.f_seen_trns = true; } } if (self->private_impl.f_metadata_fourcc == 0u) { self->private_data.s_decode_other_chunk.scratch = self->private_impl.f_chunk_length; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (self->private_data.s_decode_other_chunk.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_decode_other_chunk.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_decode_other_chunk.scratch; } goto ok; ok: self->private_impl.p_decode_other_chunk = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_other_chunk = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_actl WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_actl( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_actl; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_chunk_length != 8u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } else if (self->private_impl.f_interlace_pass > 0u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_file); goto exit; } self->private_impl.f_chunk_length = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_actl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_actl.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } self->private_impl.f_num_animation_frames_value = t_0; } if (self->private_impl.f_num_animation_frames_value == 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_actl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_actl.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } self->private_impl.f_num_animation_loops_value = t_1; } goto ok; ok: self->private_impl.p_decode_actl = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_actl = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_chrm WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_chrm( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_u = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_chrm; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_chunk_length != 32u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; self->private_impl.f_metadata_flavor = 5u; self->private_impl.f_metadata_fourcc = 1128813133u; self->private_impl.f_metadata_x = 0u; self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint64_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_u = t_0; } self->private_impl.f_metadata_x |= ((16777215u & v_u) << 0u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint64_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint64_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_u = t_1; } self->private_impl.f_metadata_x |= ((16777215u & v_u) << 24u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint64_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 24) { t_2 = ((uint64_t)(*scratch >> 32)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } v_u = t_2; } self->private_impl.f_metadata_x |= ((uint64_t)((16777215u & v_u) << 48u)); self->private_impl.f_metadata_y |= ((16777215u & v_u) >> 16u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint64_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_3); if (num_bits_3 == 24) { t_3 = ((uint64_t)(*scratch >> 32)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)); } } v_u = t_3; } self->private_impl.f_metadata_y |= ((16777215u & v_u) << 8u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); uint64_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_4 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_4); if (num_bits_4 == 24) { t_4 = ((uint64_t)(*scratch >> 32)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)); } } v_u = t_4; } self->private_impl.f_metadata_y |= ((16777215u & v_u) << 32u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); uint64_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_5 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_5); if (num_bits_5 == 24) { t_5 = ((uint64_t)(*scratch >> 32)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)); } } v_u = t_5; } self->private_impl.f_metadata_y |= ((uint64_t)((16777215u & v_u) << 56u)); self->private_impl.f_metadata_z |= ((16777215u & v_u) >> 8u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); uint64_t t_6; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_6 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_6 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_6); if (num_bits_6 == 24) { t_6 = ((uint64_t)(*scratch >> 32)); break; } num_bits_6 += 8u; *scratch |= ((uint64_t)(num_bits_6)); } } v_u = t_6; } self->private_impl.f_metadata_z |= ((16777215u & v_u) << 16u); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); uint64_t t_7; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_7 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_chrm.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_chrm.scratch; uint32_t num_bits_7 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_7); if (num_bits_7 == 24) { t_7 = ((uint64_t)(*scratch >> 32)); break; } num_bits_7 += 8u; *scratch |= ((uint64_t)(num_bits_7)); } } v_u = t_7; } self->private_impl.f_metadata_z |= ((16777215u & v_u) << 40u); goto ok; ok: self->private_impl.p_decode_chrm = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_chrm = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_exif WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_exif( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } if (self->private_impl.f_chunk_length < 4u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_metadata_flavor = 3u; self->private_impl.f_metadata_fourcc = 1163413830u; self->private_impl.f_metadata_x = 0u; self->private_impl.f_metadata_y = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); self->private_impl.f_metadata_z = wuffs_base__u64__sat_add(self->private_impl.f_metadata_y, ((uint64_t)(self->private_impl.f_chunk_length))); self->private_impl.f_chunk_length = 0u; goto ok; ok: goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_fctl WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_fctl( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_x0 = 0; uint32_t v_y0 = 0; uint32_t v_x1 = 0; uint32_t v_y1 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_fctl; if (coro_susp_point) { v_x0 = self->private_data.s_decode_fctl.v_x0; v_x1 = self->private_data.s_decode_fctl.v_x1; v_y1 = self->private_data.s_decode_fctl.v_y1; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_chunk_length != 26u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_x0 = t_0; } if (v_x0 != self->private_impl.f_next_animation_seq_num) { status = wuffs_base__make_status(wuffs_png__error__bad_animation_sequence_number); goto exit; } else if (self->private_impl.f_next_animation_seq_num >= 4294967295u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_file); goto exit; } self->private_impl.f_next_animation_seq_num += 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_x1 = t_1; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch >> 32)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } v_y1 = t_2; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_3); if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch >> 32)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)); } } v_x0 = t_3; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_4 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_4); if (num_bits_4 == 24) { t_4 = ((uint32_t)(*scratch >> 32)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)); } } v_y0 = t_4; } v_x1 += v_x0; v_y1 += v_y0; if ((v_x0 >= v_x1) || (v_x0 > self->private_impl.f_width) || (v_x1 > self->private_impl.f_width) || (v_y0 >= v_y1) || (v_y0 > self->private_impl.f_height) || (v_y1 > self->private_impl.f_height)) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_frame_rect_x0 = v_x0; self->private_impl.f_frame_rect_y0 = v_y0; self->private_impl.f_frame_rect_x1 = v_x1; self->private_impl.f_frame_rect_y1 = v_y1; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); uint32_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_5 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_5); if (num_bits_5 == 8) { t_5 = ((uint32_t)(*scratch >> 48)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)); } } v_x0 = t_5; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); uint32_t t_6; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_6 = ((uint32_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_fctl.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_fctl.scratch; uint32_t num_bits_6 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_6); if (num_bits_6 == 8) { t_6 = ((uint32_t)(*scratch >> 48)); break; } num_bits_6 += 8u; *scratch |= ((uint64_t)(num_bits_6)); } } v_x1 = t_6; } if (v_x1 <= 0u) { self->private_impl.f_frame_duration = (((uint64_t)(v_x0)) * 7056000u); } else { self->private_impl.f_frame_duration = ((((uint64_t)(v_x0)) * 705600000u) / ((uint64_t)(v_x1))); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_7 = *iop_a_src++; v_x0 = t_7; } if (v_x0 == 0u) { self->private_impl.f_frame_disposal = 0u; } else if (v_x0 == 1u) { self->private_impl.f_frame_disposal = 1u; } else if (v_x0 == 2u) { self->private_impl.f_frame_disposal = 2u; } else { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_8 = *iop_a_src++; v_x0 = t_8; } if (v_x0 == 0u) { self->private_impl.f_frame_overwrite_instead_of_blend = true; } else if (v_x0 == 1u) { self->private_impl.f_frame_overwrite_instead_of_blend = false; } else { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if (self->private_impl.f_num_decoded_frame_configs_value == 0u) { self->private_impl.f_first_rect_x0 = self->private_impl.f_frame_rect_x0; self->private_impl.f_first_rect_y0 = self->private_impl.f_frame_rect_y0; self->private_impl.f_first_rect_x1 = self->private_impl.f_frame_rect_x1; self->private_impl.f_first_rect_y1 = self->private_impl.f_frame_rect_y1; self->private_impl.f_first_duration = self->private_impl.f_frame_duration; self->private_impl.f_first_disposal = self->private_impl.f_frame_disposal; self->private_impl.f_first_overwrite_instead_of_blend = self->private_impl.f_frame_overwrite_instead_of_blend; } goto ok; ok: self->private_impl.p_decode_fctl = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_fctl = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_fctl.v_x0 = v_x0; self->private_data.s_decode_fctl.v_x1 = v_x1; self->private_data.s_decode_fctl.v_y1 = v_y1; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_gama WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_gama( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_gama; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_chunk_length != 4u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; self->private_impl.f_metadata_flavor = 5u; self->private_impl.f_metadata_fourcc = 1195461953u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = ((uint64_t)(wuffs_base__peek_u32be__no_bounds_check(iop_a_src))); iop_a_src += 4; } else { self->private_data.s_decode_gama.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_gama.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint64_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } self->private_impl.f_metadata_x = t_0; } self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; goto ok; ok: self->private_impl.p_decode_gama = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_gama = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_iccp WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_iccp( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_iccp; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { if (self->private_impl.f_chunk_length <= 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 == 0u) { break; } } if (self->private_impl.f_chunk_length <= 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_compression_method); goto exit; } self->private_impl.f_metadata_is_zlib_compressed = true; self->private_impl.f_metadata_flavor = 4u; self->private_impl.f_metadata_fourcc = 1229144912u; self->private_impl.f_metadata_x = 0u; self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; goto ok; ok: self->private_impl.p_decode_iccp = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_iccp = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_plte WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_plte( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_num_entries = 0; uint32_t v_i = 0; uint32_t v_argb = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_plte; if (coro_susp_point) { v_num_entries = self->private_data.s_decode_plte.v_num_entries; v_i = self->private_data.s_decode_plte.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ((self->private_impl.f_chunk_length > 768u) || ((self->private_impl.f_chunk_length % 3u) != 0u)) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } v_num_entries = (((uint32_t)(self->private_impl.f_chunk_length)) / 3u); self->private_impl.f_chunk_length = 0u; while (v_i < v_num_entries) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 3)) { t_0 = ((uint32_t)(wuffs_base__peek_u24be__no_bounds_check(iop_a_src))); iop_a_src += 3; } else { self->private_data.s_decode_plte.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_plte.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 16) { t_0 = ((uint32_t)(*scratch >> 40)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_argb = t_0; } v_argb |= 4278190080u; self->private_data.f_src_palette[((4u * v_i) + 0u)] = ((uint8_t)((v_argb >> 0u))); self->private_data.f_src_palette[((4u * v_i) + 1u)] = ((uint8_t)((v_argb >> 8u))); self->private_data.f_src_palette[((4u * v_i) + 2u)] = ((uint8_t)((v_argb >> 16u))); self->private_data.f_src_palette[((4u * v_i) + 3u)] = ((uint8_t)((v_argb >> 24u))); v_i += 1u; } while (v_i < 256u) { self->private_data.f_src_palette[((4u * v_i) + 0u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 1u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 2u)] = 0u; self->private_data.f_src_palette[((4u * v_i) + 3u)] = 255u; v_i += 1u; } goto ok; ok: self->private_impl.p_decode_plte = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_plte = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_plte.v_num_entries = v_num_entries; self->private_data.s_decode_plte.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_srgb WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_srgb( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_srgb; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_chunk_length != 1u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; self->private_impl.f_metadata_flavor = 5u; self->private_impl.f_metadata_fourcc = 1397901122u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t t_0 = *iop_a_src++; self->private_impl.f_metadata_x = t_0; } self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; goto ok; ok: self->private_impl.p_decode_srgb = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_srgb = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_trns WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_trns( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_i = 0; uint32_t v_n = 0; uint64_t v_u = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_trns; if (coro_susp_point) { v_i = self->private_data.s_decode_trns.v_i; v_n = self->private_data.s_decode_trns.v_n; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_color_type == 0u) { self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); if (self->private_impl.f_depth <= 8u) { self->private_impl.f_dst_pixfmt = 2164295816u; self->private_impl.f_src_pixfmt = 2164295816u; } else { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; } if (self->private_impl.f_chunk_length != 2u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_0 = ((uint64_t)(wuffs_base__peek_u16be__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_decode_trns.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_trns.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 8) { t_0 = ((uint64_t)(*scratch >> 48)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_u = t_0; } if (self->private_impl.f_depth <= 1u) { self->private_impl.f_remap_transparency = (((v_u & 1u) * 16777215u) | 4278190080u); } else if (self->private_impl.f_depth <= 2u) { self->private_impl.f_remap_transparency = (((v_u & 3u) * 5592405u) | 4278190080u); } else if (self->private_impl.f_depth <= 4u) { self->private_impl.f_remap_transparency = (((v_u & 15u) * 1118481u) | 4278190080u); } else if (self->private_impl.f_depth <= 8u) { self->private_impl.f_remap_transparency = (((v_u & 255u) * 65793u) | 4278190080u); } else { self->private_impl.f_remap_transparency = ((v_u * 4295032833u) | 18446462598732840960u); } } else if (self->private_impl.f_color_type == 2u) { self->private_impl.choosy_filter_and_swizzle = ( &wuffs_png__decoder__filter_and_swizzle_tricky); if (self->private_impl.f_depth <= 8u) { self->private_impl.f_dst_pixfmt = 2164295816u; self->private_impl.f_src_pixfmt = 2164295816u; } else { self->private_impl.f_dst_pixfmt = 2164308923u; self->private_impl.f_src_pixfmt = 2164308923u; } if (self->private_impl.f_chunk_length != 6u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length = 0u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint64_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 6)) { t_1 = ((uint64_t)(wuffs_base__peek_u48be__no_bounds_check(iop_a_src))); iop_a_src += 6; } else { self->private_data.s_decode_trns.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_trns.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 40) { t_1 = ((uint64_t)(*scratch >> 16)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_u = t_1; } if (self->private_impl.f_depth <= 8u) { self->private_impl.f_remap_transparency = ((255u & (v_u >> 0u)) | (65280u & (v_u >> 8u)) | (16711680u & (v_u >> 16u)) | 4278190080u); } else { self->private_impl.f_remap_transparency = (v_u | 18446462598732840960u); } } else if (self->private_impl.f_color_type == 3u) { self->private_impl.f_dst_pixfmt = 2164523016u; self->private_impl.f_src_pixfmt = 2164523016u; if (self->private_impl.f_chunk_length > 256u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } v_n = ((uint32_t)(self->private_impl.f_chunk_length)); self->private_impl.f_chunk_length = 0u; while (v_i < v_n) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; self->private_data.f_src_palette[((4u * v_i) + 3u)] = t_2; } v_i += 1u; } } else { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } goto ok; ok: self->private_impl.p_decode_trns = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_trns = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_trns.v_i = v_i; self->private_data.s_decode_trns.v_n = v_n; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_frame_config( wuffs_png__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_png__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_png__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func png.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_frame_config( wuffs_png__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_checksum_have = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (((uint8_t)(self->private_impl.f_call_sequence & 16u)) != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_png__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_png__decoder__skip_frame(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (self->private_impl.f_metadata_fourcc != 0u) { self->private_impl.f_call_sequence = 48u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } if (self->private_impl.f_num_decoded_frame_configs_value == 0u) { self->private_impl.f_frame_rect_x0 = self->private_impl.f_first_rect_x0; self->private_impl.f_frame_rect_y0 = self->private_impl.f_first_rect_y0; self->private_impl.f_frame_rect_x1 = self->private_impl.f_first_rect_x1; self->private_impl.f_frame_rect_y1 = self->private_impl.f_first_rect_y1; self->private_impl.f_frame_config_io_position = self->private_impl.f_first_config_io_position; self->private_impl.f_frame_duration = self->private_impl.f_first_duration; self->private_impl.f_frame_disposal = self->private_impl.f_first_disposal; self->private_impl.f_frame_overwrite_instead_of_blend = self->private_impl.f_first_overwrite_instead_of_blend; } else { while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_frame_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } self->private_impl.f_chunk_length = t_0; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_frame_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } self->private_impl.f_chunk_type = t_1; } if (self->private_impl.f_chunk_type == 1145980233u) { if (self->private_impl.f_chunk_length != 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_frame_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame_config.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } v_checksum_have = t_2; } if ( ! self->private_impl.f_ignore_checksum && (v_checksum_have != 2187346606u)) { status = wuffs_base__make_status(wuffs_png__error__bad_checksum); goto exit; } self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else if (self->private_impl.f_chunk_type == 1413571686u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } else if (self->private_impl.f_chunk_type == 1280598886u) { self->private_impl.f_frame_config_io_position = ((uint64_t)(wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))) - 8u)); if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_png__decoder__decode_fctl(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_data.s_do_decode_frame_config.scratch = 4u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (self->private_data.s_do_decode_frame_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame_config.scratch; break; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); status = wuffs_png__decoder__decode_other_chunk(self, a_src, true); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_metadata_fourcc != 0u) { self->private_impl.f_call_sequence = 48u; status = wuffs_base__make_status(wuffs_base__note__metadata_reported); goto ok; } self->private_data.s_do_decode_frame_config.scratch = 4u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (self->private_data.s_do_decode_frame_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame_config.scratch; self->private_impl.f_chunk_length = 0u; } } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( self->private_impl.f_frame_rect_x0, self->private_impl.f_frame_rect_y0, self->private_impl.f_frame_rect_x1, self->private_impl.f_frame_rect_y1), ((wuffs_base__flicks)(self->private_impl.f_frame_duration)), ((uint64_t)(self->private_impl.f_num_decoded_frame_configs_value)), self->private_impl.f_frame_config_io_position, self->private_impl.f_frame_disposal, ((self->private_impl.f_color_type <= 3u) && ! self->private_impl.f_seen_trns), self->private_impl.f_frame_overwrite_instead_of_blend, 0u); } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_num_decoded_frame_configs_value, 1u); self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.skip_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__skip_frame( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_seq_num = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_skip_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_chunk_type_array[0u] = 0u; self->private_impl.f_chunk_type_array[1u] = 0u; self->private_impl.f_chunk_type_array[2u] = 0u; self->private_impl.f_chunk_type_array[3u] = 0u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) < 8u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); continue; } self->private_impl.f_chunk_length = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); self->private_impl.f_chunk_type = ((uint32_t)((wuffs_base__peek_u64le__no_bounds_check(iop_a_src) >> 32u))); if (self->private_impl.f_chunk_type == 1413563465u) { if (self->private_impl.f_chunk_type_array[0u] == 102u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_type_array[0u] = 73u; self->private_impl.f_chunk_type_array[1u] = 68u; self->private_impl.f_chunk_type_array[2u] = 65u; self->private_impl.f_chunk_type_array[3u] = 84u; } else if (self->private_impl.f_chunk_type == 1413571686u) { if (self->private_impl.f_chunk_type_array[0u] == 73u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_type_array[0u] = 102u; self->private_impl.f_chunk_type_array[1u] = 100u; self->private_impl.f_chunk_type_array[2u] = 65u; self->private_impl.f_chunk_type_array[3u] = 84u; if (self->private_impl.f_chunk_length < 4u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 4u; iop_a_src += 8u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_skip_frame.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_skip_frame.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_seq_num = t_0; } if (v_seq_num != self->private_impl.f_next_animation_seq_num) { status = wuffs_base__make_status(wuffs_png__error__bad_animation_sequence_number); goto exit; } else if (self->private_impl.f_next_animation_seq_num >= 4294967295u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_file); goto exit; } self->private_impl.f_next_animation_seq_num += 1u; self->private_data.s_skip_frame.scratch = (((uint64_t)(self->private_impl.f_chunk_length)) + 4u); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (self->private_data.s_skip_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_skip_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_skip_frame.scratch; self->private_impl.f_chunk_length = 0u; continue; } else if (self->private_impl.f_chunk_type_array[0u] != 0u) { break; } else if (self->private_impl.f_chunk_type == 1280598886u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_data.s_skip_frame.scratch = (((uint64_t)(self->private_impl.f_chunk_length)) + 12u); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (self->private_data.s_skip_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_skip_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_skip_frame.scratch; self->private_impl.f_chunk_length = 0u; } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_skip_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_skip_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__decode_frame( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_png__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_png__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func png.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_decode_frame( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_seq_num = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_pass_width = 0; uint32_t v_pass_height = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (((uint8_t)(self->private_impl.f_call_sequence & 16u)) != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } else if (self->private_impl.f_call_sequence >= 96u) { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else if (self->private_impl.f_call_sequence != 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_png__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) < 8u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); continue; } self->private_impl.f_chunk_length = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); self->private_impl.f_chunk_type = ((uint32_t)((wuffs_base__peek_u64le__no_bounds_check(iop_a_src) >> 32u))); if (self->private_impl.f_chunk_type == 1413563465u) { self->private_impl.f_chunk_type_array[0u] = 73u; self->private_impl.f_chunk_type_array[1u] = 68u; self->private_impl.f_chunk_type_array[2u] = 65u; self->private_impl.f_chunk_type_array[3u] = 84u; iop_a_src += 8u; if ( ! self->private_impl.f_ignore_checksum) { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__make_slice_u8(self->private_impl.f_chunk_type_array, 4)); } break; } else if (self->private_impl.f_chunk_type == 1413571686u) { self->private_impl.f_chunk_type_array[0u] = 102u; self->private_impl.f_chunk_type_array[1u] = 100u; self->private_impl.f_chunk_type_array[2u] = 65u; self->private_impl.f_chunk_type_array[3u] = 84u; if (self->private_impl.f_chunk_length < 4u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 4u; iop_a_src += 8u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_frame.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch >> 32)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_seq_num = t_0; } if (v_seq_num != self->private_impl.f_next_animation_seq_num) { status = wuffs_base__make_status(wuffs_png__error__bad_animation_sequence_number); goto exit; } else if (self->private_impl.f_next_animation_seq_num >= 4294967295u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_file); goto exit; } self->private_impl.f_next_animation_seq_num += 1u; break; } else if (self->private_impl.f_chunk_type == 1280598886u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_data.s_do_decode_frame.scratch = (((uint64_t)(self->private_impl.f_chunk_length)) + 12u); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (self->private_data.s_do_decode_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame.scratch; self->private_impl.f_chunk_length = 0u; } if (self->private_impl.f_zlib_is_dirty) { wuffs_private_impl__ignore_status(wuffs_zlib__decoder__initialize(&self->private_data.f_zlib, sizeof (wuffs_zlib__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); if (self->private_impl.f_ignore_checksum) { wuffs_zlib__decoder__set_quirk(&self->private_data.f_zlib, 1u, 1u); } } self->private_impl.f_zlib_is_dirty = true; v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), wuffs_base__utility__make_pixel_format(self->private_impl.f_src_pixfmt), wuffs_base__make_slice_u8(self->private_data.f_src_palette, 1024), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_workbuf_hist_pos_base = 0u; while (true) { if (self->private_impl.f_chunk_type_array[0u] == 73u) { v_pass_width = (16777215u & ((((uint32_t)(WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][1u])) + self->private_impl.f_width) >> WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][0u])); v_pass_height = (16777215u & ((((uint32_t)(WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][4u])) + self->private_impl.f_height) >> WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][3u])); } else { v_pass_width = (16777215u & ((uint32_t)(self->private_impl.f_frame_rect_x1 - self->private_impl.f_frame_rect_x0))); v_pass_height = (16777215u & ((uint32_t)(self->private_impl.f_frame_rect_y1 - self->private_impl.f_frame_rect_y0))); } if ((v_pass_width > 0u) && (v_pass_height > 0u)) { self->private_impl.f_pass_bytes_per_row = wuffs_png__decoder__calculate_bytes_per_row(self, v_pass_width); self->private_impl.f_pass_workbuf_length = (((uint64_t)(v_pass_height)) * (1u + self->private_impl.f_pass_bytes_per_row)); while (true) { { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_1 = wuffs_png__decoder__decode_pass(self, a_src, a_workbuf); v_status = t_1; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_ok(&v_status)) { break; } else if (wuffs_base__status__is_error(&v_status) || ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed))) { if (self->private_impl.f_workbuf_wi <= ((uint64_t)(a_workbuf.len))) { wuffs_png__decoder__filter_and_swizzle(self, a_dst, wuffs_base__slice_u8__subslice_j(a_workbuf, self->private_impl.f_workbuf_wi)); } if (v_status.repr == wuffs_base__suspension__short_read) { status = wuffs_base__make_status(wuffs_png__error__truncated_input); goto exit; } } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); } v_status = wuffs_png__decoder__filter_and_swizzle(self, a_dst, a_workbuf); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_workbuf_hist_pos_base += self->private_impl.f_pass_workbuf_length; } if ((self->private_impl.f_interlace_pass == 0u) || (self->private_impl.f_interlace_pass >= 7u)) { break; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_interlace_pass += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } wuffs_private_impl__u32__sat_add_indirect(&self->private_impl.f_num_decoded_frames_value, 1u); self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.decode_pass WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__decode_pass( wuffs_png__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__io_buffer u_w = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_w = &u_w; uint8_t* iop_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io0_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint64_t v_w_mark = 0; uint64_t v_r_mark = 0; wuffs_base__status v_zlib_status = wuffs_base__make_status(NULL); uint32_t v_checksum_have = 0; uint32_t v_checksum_want = 0; uint32_t v_seq_num = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_pass; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; self->private_impl.f_workbuf_wi = 0u; while (true) { if ((self->private_impl.f_workbuf_wi > self->private_impl.f_pass_workbuf_length) || (self->private_impl.f_pass_workbuf_length > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } { wuffs_base__io_buffer* o_0_v_w = v_w; uint8_t* o_0_iop_v_w = iop_v_w; uint8_t* o_0_io0_v_w = io0_v_w; uint8_t* o_0_io1_v_w = io1_v_w; uint8_t* o_0_io2_v_w = io2_v_w; v_w = wuffs_private_impl__io_writer__set( &u_w, &iop_v_w, &io0_v_w, &io1_v_w, &io2_v_w, wuffs_base__slice_u8__subslice_ij(a_workbuf, self->private_impl.f_workbuf_wi, self->private_impl.f_pass_workbuf_length), ((uint64_t)(self->private_impl.f_workbuf_hist_pos_base + self->private_impl.f_workbuf_wi))); { const bool o_1_closed_a_src = a_src->meta.closed; const uint8_t* o_1_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_w_mark = ((uint64_t)(iop_v_w - io0_v_w)); v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { u_w.meta.wi = ((size_t)(iop_v_w - u_w.data.ptr)); if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_0 = wuffs_zlib__decoder__transform_io(&self->private_data.f_zlib, v_w, a_src, wuffs_base__utility__empty_slice_u8()); v_zlib_status = t_0; iop_v_w = u_w.data.ptr + u_w.meta.wi; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum) { wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_workbuf_wi, wuffs_private_impl__io__count_since(v_w_mark, ((uint64_t)(iop_v_w - io0_v_w)))); io2_a_src = o_1_io2_a_src; if (a_src) { a_src->meta.closed = o_1_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } v_w = o_0_v_w; iop_v_w = o_0_iop_v_w; io0_v_w = o_0_io0_v_w; io1_v_w = o_0_io1_v_w; io2_v_w = o_0_io2_v_w; } if (wuffs_base__status__is_ok(&v_zlib_status)) { if (self->private_impl.f_chunk_length > 0u) { status = wuffs_base__make_status(wuffs_base__error__too_much_data); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_pass.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_pass.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_checksum_want = t_1; } if ( ! self->private_impl.f_ignore_checksum && (self->private_impl.f_chunk_type_array[0u] == 73u)) { v_checksum_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__utility__empty_slice_u8()); if (v_checksum_have != v_checksum_want) { status = wuffs_base__make_status(wuffs_png__error__bad_checksum); goto exit; } } break; } else if (v_zlib_status.repr == wuffs_base__suspension__short_write) { if ((1u <= self->private_impl.f_interlace_pass) && (self->private_impl.f_interlace_pass <= 6u)) { break; } status = wuffs_base__make_status(wuffs_base__error__too_much_data); goto exit; } else if (v_zlib_status.repr != wuffs_base__suspension__short_read) { status = v_zlib_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } else if (self->private_impl.f_chunk_length == 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_pass.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_pass.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch >> 32)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } v_checksum_want = t_2; } if ( ! self->private_impl.f_ignore_checksum && (self->private_impl.f_chunk_type_array[0u] == 73u)) { v_checksum_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__utility__empty_slice_u8()); if (v_checksum_have != v_checksum_want) { status = wuffs_base__make_status(wuffs_png__error__bad_checksum); goto exit; } } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_pass.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_pass.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_3); if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch >> 32)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)); } } self->private_impl.f_chunk_length = t_3; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_4 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_pass.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_pass.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 24) { t_4 = ((uint32_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } self->private_impl.f_chunk_type = t_4; } if (self->private_impl.f_chunk_type_array[0u] == 73u) { if (self->private_impl.f_chunk_type != 1413563465u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } if ( ! self->private_impl.f_ignore_checksum) { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_base__make_slice_u8(self->private_impl.f_chunk_type_array, 4)); } } else { if ((self->private_impl.f_chunk_type != 1413571686u) || (self->private_impl.f_chunk_length < 4u)) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 4u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); uint32_t t_5; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_5 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_pass.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_pass.scratch; uint32_t num_bits_5 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_5); if (num_bits_5 == 24) { t_5 = ((uint32_t)(*scratch >> 32)); break; } num_bits_5 += 8u; *scratch |= ((uint64_t)(num_bits_5)); } } v_seq_num = t_5; } if (v_seq_num != self->private_impl.f_next_animation_seq_num) { status = wuffs_base__make_status(wuffs_png__error__bad_animation_sequence_number); goto exit; } else if (self->private_impl.f_next_animation_seq_num >= 4294967295u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_file); goto exit; } self->private_impl.f_next_animation_seq_num += 1u; } continue; } else if (((uint64_t)(io2_a_src - iop_a_src)) > 0u) { status = wuffs_base__make_status(wuffs_png__error__internal_error_zlib_decoder_did_not_exhaust_its_input); goto exit; } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(11); } if (self->private_impl.f_workbuf_wi != self->private_impl.f_pass_workbuf_length) { status = wuffs_base__make_status(wuffs_base__error__not_enough_data); goto exit; } else if (0u < ((uint64_t)(a_workbuf.len))) { if (a_workbuf.ptr[0u] == 4u) { a_workbuf.ptr[0u] = 1u; } } ok: self->private_impl.p_decode_pass = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_pass = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_png__decoder__frame_dirty_rect( const wuffs_png__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( self->private_impl.f_frame_rect_x0, self->private_impl.f_frame_rect_y0, self->private_impl.f_frame_rect_x1, self->private_impl.f_frame_rect_y1); } // -------- func png.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_png__decoder__num_animation_loops( const wuffs_png__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return self->private_impl.f_num_animation_loops_value; } // -------- func png.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__num_decoded_frame_configs( const wuffs_png__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return ((uint64_t)(self->private_impl.f_num_decoded_frame_configs_value)); } // -------- func png.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_png__decoder__num_decoded_frames( const wuffs_png__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return ((uint64_t)(self->private_impl.f_num_decoded_frames_value)); } // -------- func png.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__restart_frame( wuffs_png__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } else if ((a_index >= ((uint64_t)(self->private_impl.f_num_animation_frames_value))) || ((a_index == 0u) && (a_io_position != self->private_impl.f_first_config_io_position))) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; if (self->private_impl.f_interlace_pass >= 1u) { self->private_impl.f_interlace_pass = 1u; } self->private_impl.f_frame_config_io_position = a_io_position; self->private_impl.f_num_decoded_frame_configs_value = ((uint32_t)(a_index)); self->private_impl.f_num_decoded_frames_value = self->private_impl.f_num_decoded_frame_configs_value; return wuffs_base__make_status(NULL); } // -------- func png.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_png__decoder__set_report_metadata( wuffs_png__decoder* self, uint32_t a_fourcc, bool a_report) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if (a_fourcc == 1128813133u) { self->private_impl.f_report_metadata_chrm = a_report; } else if (a_fourcc == 1163413830u) { self->private_impl.f_report_metadata_exif = a_report; } else if (a_fourcc == 1195461953u) { self->private_impl.f_report_metadata_gama = a_report; } else if (a_fourcc == 1229144912u) { self->private_impl.f_report_metadata_iccp = a_report; } else if (a_fourcc == 1263947808u) { self->private_impl.f_report_metadata_kvp = a_report; } else if (a_fourcc == 1397901122u) { self->private_impl.f_report_metadata_srgb = a_report; } return wuffs_base__make_empty_struct(); } // -------- func png.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_png__decoder__tell_me_more( wuffs_png__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_tell_me_more; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_png__decoder__do_tell_me_more(self, a_dst, a_minfo, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_png__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_tell_me_more = 0; goto exit; } goto suspend; suspend: self->private_impl.p_tell_me_more = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 4 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func png.decoder.do_tell_me_more WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__do_tell_me_more( wuffs_png__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint16_t v_c16 = 0; wuffs_base__io_buffer u_w = wuffs_base__empty_io_buffer(); wuffs_base__io_buffer* v_w = &u_w; uint8_t* iop_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io0_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_v_w WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint64_t v_num_written = 0; uint64_t v_w_mark = 0; uint64_t v_r_mark = 0; wuffs_base__status v_zlib_status = wuffs_base__make_status(NULL); uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_tell_me_more; if (coro_susp_point) { v_zlib_status = self->private_data.s_do_tell_me_more.v_zlib_status; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (((uint8_t)(self->private_impl.f_call_sequence & 16u)) == 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } if (self->private_impl.f_metadata_fourcc == 0u) { status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; } do { if (self->private_impl.f_metadata_flavor == 3u) { while (true) { if (wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))) != self->private_impl.f_metadata_y) { status = wuffs_base__make_status(wuffs_base__error__bad_i_o_position); goto exit; } else if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, self->private_impl.f_metadata_flavor, self->private_impl.f_metadata_fourcc, self->private_impl.f_metadata_x, self->private_impl.f_metadata_y, self->private_impl.f_metadata_z); } if (self->private_impl.f_metadata_y >= self->private_impl.f_metadata_z) { goto label__goto_done__break; } self->private_impl.f_metadata_y = self->private_impl.f_metadata_z; status = wuffs_base__make_status(wuffs_base__suspension__even_more_information); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } } if (self->private_impl.f_metadata_is_zlib_compressed) { if (self->private_impl.f_zlib_is_dirty) { wuffs_private_impl__ignore_status(wuffs_zlib__decoder__initialize(&self->private_data.f_zlib, sizeof (wuffs_zlib__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); if (self->private_impl.f_ignore_checksum) { wuffs_zlib__decoder__set_quirk(&self->private_data.f_zlib, 1u, 1u); } } self->private_impl.f_zlib_is_dirty = true; self->private_impl.f_ztxt_hist_pos = 0u; } label__loop__continue:; while (true) { if (a_minfo != NULL) { wuffs_base__more_information__set(a_minfo, self->private_impl.f_metadata_flavor, self->private_impl.f_metadata_fourcc, self->private_impl.f_metadata_x, self->private_impl.f_metadata_y, self->private_impl.f_metadata_z); } if (self->private_impl.f_metadata_flavor != 4u) { break; } if (self->private_impl.f_metadata_is_zlib_compressed) { if (self->private_impl.f_chunk_type == 1346585449u) { { const bool o_0_closed_a_src = a_src->meta.closed; const uint8_t* o_0_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_0 = wuffs_zlib__decoder__transform_io(&self->private_data.f_zlib, a_dst, a_src, wuffs_base__utility__empty_slice_u8()); v_zlib_status = t_0; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); io2_a_src = o_0_io2_a_src; if (a_src) { a_src->meta.closed = o_0_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } if (wuffs_base__status__is_ok(&v_zlib_status)) { self->private_impl.f_metadata_is_zlib_compressed = false; break; } else if ( ! wuffs_base__status__is_suspension(&v_zlib_status)) { status = v_zlib_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } status = v_zlib_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } else if (self->private_impl.f_chunk_type == 1951945833u) { { const bool o_1_closed_a_src = a_src->meta.closed; const uint8_t* o_1_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_1 = wuffs_zlib__decoder__transform_io(&self->private_data.f_zlib, a_dst, a_src, wuffs_base__utility__empty_slice_u8()); v_zlib_status = t_1; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); io2_a_src = o_1_io2_a_src; if (a_src) { a_src->meta.closed = o_1_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } if (wuffs_base__status__is_ok(&v_zlib_status)) { self->private_impl.f_metadata_is_zlib_compressed = false; break; } else if ( ! wuffs_base__status__is_suspension(&v_zlib_status)) { status = v_zlib_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } status = v_zlib_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); } else if (self->private_impl.f_chunk_type == 1951945850u) { if (self->private_impl.f_ztxt_ri == self->private_impl.f_ztxt_wi) { { wuffs_base__io_buffer* o_2_v_w = v_w; uint8_t* o_2_iop_v_w = iop_v_w; uint8_t* o_2_io0_v_w = io0_v_w; uint8_t* o_2_io1_v_w = io1_v_w; uint8_t* o_2_io2_v_w = io2_v_w; v_w = wuffs_private_impl__io_writer__set( &u_w, &iop_v_w, &io0_v_w, &io1_v_w, &io2_v_w, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024), self->private_impl.f_ztxt_hist_pos); { const bool o_3_closed_a_src = a_src->meta.closed; const uint8_t* o_3_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_w_mark = ((uint64_t)(iop_v_w - io0_v_w)); v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { u_w.meta.wi = ((size_t)(iop_v_w - u_w.data.ptr)); if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_zlib__decoder__transform_io(&self->private_data.f_zlib, v_w, a_src, wuffs_base__utility__empty_slice_u8()); v_zlib_status = t_2; iop_v_w = u_w.data.ptr + u_w.meta.wi; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); v_num_written = wuffs_private_impl__io__count_since(v_w_mark, ((uint64_t)(iop_v_w - io0_v_w))); io2_a_src = o_3_io2_a_src; if (a_src) { a_src->meta.closed = o_3_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } v_w = o_2_v_w; iop_v_w = o_2_iop_v_w; io0_v_w = o_2_io0_v_w; io1_v_w = o_2_io1_v_w; io2_v_w = o_2_io2_v_w; } if (v_num_written > 1024u) { status = wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_i_o); goto exit; } self->private_impl.f_ztxt_ri = 0u; self->private_impl.f_ztxt_wi = ((uint32_t)(v_num_written)); wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_ztxt_hist_pos, v_num_written); } while (self->private_impl.f_ztxt_ri < self->private_impl.f_ztxt_wi) { v_c16 = WUFFS_PNG__LATIN_1[self->private_data.f_dst_palette[self->private_impl.f_ztxt_ri]]; if (v_c16 == 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_text_chunk_not_latin_1); goto exit; } else if (v_c16 <= 127u) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); goto label__loop__continue; } self->private_impl.f_ztxt_ri += 1u; (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)(v_c16))), iop_a_dst += 1); } else { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); goto label__loop__continue; } self->private_impl.f_ztxt_ri += 1u; (wuffs_base__poke_u16le__no_bounds_check(iop_a_dst, v_c16), iop_a_dst += 2); } } if (wuffs_base__status__is_ok(&v_zlib_status)) { self->private_impl.f_metadata_is_zlib_compressed = false; break; } else if ( ! wuffs_base__status__is_suspension(&v_zlib_status)) { status = v_zlib_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } else if (v_zlib_status.repr != wuffs_base__suspension__short_write) { status = v_zlib_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); } } else { status = wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_chunk_type); goto exit; } } else if ((self->private_impl.f_chunk_type == 1951945833u) && (self->private_impl.f_metadata_fourcc == 1263947862u)) { while (true) { if (self->private_impl.f_chunk_length <= 0u) { goto label__loop__break; } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); goto label__loop__continue; } else if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); goto label__loop__continue; } self->private_impl.f_chunk_length -= 1u; v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, v_c8), iop_a_dst += 1); } } else { while (true) { if (self->private_impl.f_chunk_length <= 0u) { if (self->private_impl.f_metadata_fourcc == 1263947851u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } goto label__loop__break; } else if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); goto label__loop__continue; } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); if (v_c8 == 0u) { self->private_impl.f_chunk_length -= 1u; iop_a_src += 1u; goto label__loop__break; } v_c16 = WUFFS_PNG__LATIN_1[v_c8]; if (v_c16 == 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_text_chunk_not_latin_1); goto exit; } else if (v_c16 <= 127u) { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); goto label__loop__continue; } self->private_impl.f_chunk_length -= 1u; iop_a_src += 1u; (wuffs_base__poke_u8be__no_bounds_check(iop_a_dst, ((uint8_t)(v_c16))), iop_a_dst += 1); } else { if (((uint64_t)(io2_a_dst - iop_a_dst)) <= 1u) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(11); goto label__loop__continue; } self->private_impl.f_chunk_length -= 1u; iop_a_src += 1u; (wuffs_base__poke_u16le__no_bounds_check(iop_a_dst, v_c16), iop_a_dst += 2); } } } } label__loop__break:; if (self->private_impl.f_metadata_fourcc == 1263947851u) { self->private_impl.f_metadata_fourcc = 1263947862u; if (self->private_impl.f_chunk_type == 1951945833u) { if (self->private_impl.f_chunk_length <= 1u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 2u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (v_c8 == 0u) { self->private_impl.f_metadata_is_zlib_compressed = false; } else if (v_c8 == 1u) { self->private_impl.f_metadata_is_zlib_compressed = true; } else { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if ((v_c8 != 0u) && self->private_impl.f_metadata_is_zlib_compressed) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_compression_method); goto exit; } self->private_impl.f_metadata_fourcc -= 2u; while (self->private_impl.f_metadata_fourcc != 1263947862u) { self->private_impl.f_metadata_fourcc += 1u; while (true) { if (self->private_impl.f_chunk_length <= 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } if (v_c8 == 0u) { break; } } } } else if (self->private_impl.f_chunk_type == 1951945850u) { if (self->private_impl.f_chunk_length <= 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_impl.f_chunk_length -= 1u; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_png__error__unsupported_png_compression_method); goto exit; } self->private_impl.f_metadata_is_zlib_compressed = true; } self->private_impl.f_call_sequence &= 239u; status = wuffs_base__make_status(NULL); goto ok; } } while (0); label__goto_done__break:; if (self->private_impl.f_chunk_length != 0u) { status = wuffs_base__make_status(wuffs_png__error__bad_chunk); goto exit; } self->private_data.s_do_tell_me_more.scratch = 4u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); if (self->private_data.s_do_tell_me_more.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_tell_me_more.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_tell_me_more.scratch; self->private_impl.f_metadata_flavor = 0u; self->private_impl.f_metadata_fourcc = 0u; self->private_impl.f_metadata_x = 0u; self->private_impl.f_metadata_y = 0u; self->private_impl.f_metadata_z = 0u; self->private_impl.f_call_sequence &= 239u; status = wuffs_base__make_status(NULL); goto ok; ok: self->private_impl.p_do_tell_me_more = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_tell_me_more = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_tell_me_more.v_zlib_status = v_zlib_status; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func png.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_png__decoder__workbuf_len( const wuffs_png__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(self->private_impl.f_overall_workbuf_length, self->private_impl.f_overall_workbuf_length); } // -------- func png.decoder.filter_and_swizzle WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf) { return (*self->private_impl.choosy_filter_and_swizzle)(self, a_dst, a_workbuf); } WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle__choosy_default( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf) { wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint64_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row0 = 0; uint64_t v_dst_bytes_per_row1 = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; uint32_t v_y = 0; wuffs_base__slice_u8 v_dst = {0}; uint8_t v_filter = 0; wuffs_base__slice_u8 v_curr_row = {0}; wuffs_base__slice_u8 v_prev_row = {0}; v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_dst_bytes_per_pixel = ((uint64_t)((v_dst_bits_per_pixel / 8u))); v_dst_bytes_per_row0 = (((uint64_t)(self->private_impl.f_frame_rect_x0)) * v_dst_bytes_per_pixel); v_dst_bytes_per_row1 = (((uint64_t)(self->private_impl.f_frame_rect_x1)) * v_dst_bytes_per_pixel); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); if (v_dst_bytes_per_row1 < ((uint64_t)(v_tab.width))) { v_tab = wuffs_base__table_u8__subtable_ij(v_tab, 0u, 0u, v_dst_bytes_per_row1, ((uint64_t)(v_tab.height))); } if (v_dst_bytes_per_row0 < ((uint64_t)(v_tab.width))) { v_tab = wuffs_base__table_u8__subtable_ij(v_tab, v_dst_bytes_per_row0, 0u, ((uint64_t)(v_tab.width)), ((uint64_t)(v_tab.height))); } else { v_tab = wuffs_base__table_u8__subtable_ij(v_tab, 0u, 0u, 0u, 0u); } v_y = self->private_impl.f_frame_rect_y0; while (v_y < self->private_impl.f_frame_rect_y1) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_y); if (1u > ((uint64_t)(a_workbuf.len))) { return wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_workbuf_length); } v_filter = a_workbuf.ptr[0u]; a_workbuf = wuffs_base__slice_u8__subslice_i(a_workbuf, 1u); if (self->private_impl.f_pass_bytes_per_row > ((uint64_t)(a_workbuf.len))) { return wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_workbuf_length); } v_curr_row = wuffs_base__slice_u8__subslice_j(a_workbuf, self->private_impl.f_pass_bytes_per_row); a_workbuf = wuffs_base__slice_u8__subslice_i(a_workbuf, self->private_impl.f_pass_bytes_per_row); if (v_filter == 0u) { } else if (v_filter == 1u) { wuffs_png__decoder__filter_1(self, v_curr_row); } else if (v_filter == 2u) { wuffs_png__decoder__filter_2(self, v_curr_row, v_prev_row); } else if (v_filter == 3u) { wuffs_png__decoder__filter_3(self, v_curr_row, v_prev_row); } else if (v_filter == 4u) { wuffs_png__decoder__filter_4(self, v_curr_row, v_prev_row); } else { return wuffs_base__make_status(wuffs_png__error__bad_filter); } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, v_curr_row); v_prev_row = v_curr_row; v_y += 1u; } return wuffs_base__make_status(NULL); } // -------- func png.decoder.filter_and_swizzle_tricky WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_png__decoder__filter_and_swizzle_tricky( wuffs_png__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_workbuf) { wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint64_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row1 = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; uint64_t v_src_bytes_per_pixel = 0; uint32_t v_x = 0; uint32_t v_y = 0; uint64_t v_i = 0; wuffs_base__slice_u8 v_dst = {0}; uint8_t v_filter = 0; wuffs_base__slice_u8 v_s = {0}; wuffs_base__slice_u8 v_curr_row = {0}; wuffs_base__slice_u8 v_prev_row = {0}; uint8_t v_bits_unpacked[8] = {0}; uint8_t v_bits_packed = 0; uint8_t v_packs_remaining = 0; uint8_t v_multiplier = 0; uint8_t v_shift = 0; v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_dst_bytes_per_pixel = ((uint64_t)((v_dst_bits_per_pixel / 8u))); v_dst_bytes_per_row1 = (((uint64_t)(self->private_impl.f_frame_rect_x1)) * v_dst_bytes_per_pixel); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_src_bytes_per_pixel = 1u; if (self->private_impl.f_depth >= 8u) { v_src_bytes_per_pixel = (((uint64_t)(WUFFS_PNG__NUM_CHANNELS[self->private_impl.f_color_type])) * ((uint64_t)(((uint8_t)(self->private_impl.f_depth >> 3u))))); } if (self->private_impl.f_chunk_type_array[0u] == 73u) { v_y = ((uint32_t)(WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][5u])); } else { v_y = self->private_impl.f_frame_rect_y0; } while (v_y < self->private_impl.f_frame_rect_y1) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_y); if (v_dst_bytes_per_row1 < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row1); } if (1u > ((uint64_t)(a_workbuf.len))) { return wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_workbuf_length); } v_filter = a_workbuf.ptr[0u]; a_workbuf = wuffs_base__slice_u8__subslice_i(a_workbuf, 1u); if (self->private_impl.f_pass_bytes_per_row > ((uint64_t)(a_workbuf.len))) { return wuffs_base__make_status(wuffs_png__error__internal_error_inconsistent_workbuf_length); } v_curr_row = wuffs_base__slice_u8__subslice_j(a_workbuf, self->private_impl.f_pass_bytes_per_row); a_workbuf = wuffs_base__slice_u8__subslice_i(a_workbuf, self->private_impl.f_pass_bytes_per_row); if (v_filter == 0u) { } else if (v_filter == 1u) { wuffs_png__decoder__filter_1(self, v_curr_row); } else if (v_filter == 2u) { wuffs_png__decoder__filter_2(self, v_curr_row, v_prev_row); } else if (v_filter == 3u) { wuffs_png__decoder__filter_3(self, v_curr_row, v_prev_row); } else if (v_filter == 4u) { wuffs_png__decoder__filter_4(self, v_curr_row, v_prev_row); } else { return wuffs_base__make_status(wuffs_png__error__bad_filter); } v_s = v_curr_row; if (self->private_impl.f_chunk_type_array[0u] == 73u) { v_x = ((uint32_t)(WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][2u])); } else { v_x = self->private_impl.f_frame_rect_x0; } if (self->private_impl.f_depth == 8u) { while (v_x < self->private_impl.f_frame_rect_x1) { v_i = (((uint64_t)(v_x)) * v_dst_bytes_per_pixel); if (v_i <= ((uint64_t)(v_dst.len))) { if (((uint32_t)(self->private_impl.f_remap_transparency)) != 0u) { if (self->private_impl.f_color_type == 0u) { if (1u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[0u]; v_bits_unpacked[1u] = v_s.ptr[0u]; v_bits_unpacked[2u] = v_s.ptr[0u]; v_bits_unpacked[3u] = 255u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 1u); if (((uint32_t)(self->private_impl.f_remap_transparency)) == ((((uint32_t)(v_bits_unpacked[0u])) << 0u) | (((uint32_t)(v_bits_unpacked[1u])) << 8u) | (((uint32_t)(v_bits_unpacked[2u])) << 16u) | (((uint32_t)(v_bits_unpacked[3u])) << 24u))) { v_bits_unpacked[0u] = 0u; v_bits_unpacked[1u] = 0u; v_bits_unpacked[2u] = 0u; v_bits_unpacked[3u] = 0u; } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(v_bits_unpacked, 4)); } } else { if (3u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[2u]; v_bits_unpacked[1u] = v_s.ptr[1u]; v_bits_unpacked[2u] = v_s.ptr[0u]; v_bits_unpacked[3u] = 255u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 3u); if (((uint32_t)(self->private_impl.f_remap_transparency)) == ((((uint32_t)(v_bits_unpacked[0u])) << 0u) | (((uint32_t)(v_bits_unpacked[1u])) << 8u) | (((uint32_t)(v_bits_unpacked[2u])) << 16u) | (((uint32_t)(v_bits_unpacked[3u])) << 24u))) { v_bits_unpacked[0u] = 0u; v_bits_unpacked[1u] = 0u; v_bits_unpacked[2u] = 0u; v_bits_unpacked[3u] = 0u; } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(v_bits_unpacked, 4)); } } } else if (v_src_bytes_per_pixel <= ((uint64_t)(v_s.len))) { wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__slice_u8__subslice_j(v_s, v_src_bytes_per_pixel)); v_s = wuffs_base__slice_u8__subslice_i(v_s, v_src_bytes_per_pixel); } } v_x += (((uint32_t)(1u)) << WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][0u]); } } else if (self->private_impl.f_depth < 8u) { v_multiplier = 1u; if (self->private_impl.f_color_type == 0u) { v_multiplier = WUFFS_PNG__LOW_BIT_DEPTH_MULTIPLIERS[self->private_impl.f_depth]; } v_shift = ((uint8_t)(((uint8_t)(8u - self->private_impl.f_depth)) & 7u)); v_packs_remaining = 0u; while (v_x < self->private_impl.f_frame_rect_x1) { v_i = (((uint64_t)(v_x)) * v_dst_bytes_per_pixel); if (v_i <= ((uint64_t)(v_dst.len))) { if ((v_packs_remaining == 0u) && (1u <= ((uint64_t)(v_s.len)))) { v_packs_remaining = WUFFS_PNG__LOW_BIT_DEPTH_NUM_PACKS[self->private_impl.f_depth]; v_bits_packed = v_s.ptr[0u]; v_s = wuffs_base__slice_u8__subslice_i(v_s, 1u); } v_bits_unpacked[0u] = ((uint8_t)(((uint8_t)(v_bits_packed >> v_shift)) * v_multiplier)); v_bits_packed = ((uint8_t)(v_bits_packed << self->private_impl.f_depth)); v_packs_remaining = ((uint8_t)(v_packs_remaining - 1u)); if (((uint32_t)(self->private_impl.f_remap_transparency)) != 0u) { v_bits_unpacked[1u] = v_bits_unpacked[0u]; v_bits_unpacked[2u] = v_bits_unpacked[0u]; v_bits_unpacked[3u] = 255u; if (((uint32_t)(self->private_impl.f_remap_transparency)) == ((((uint32_t)(v_bits_unpacked[0u])) << 0u) | (((uint32_t)(v_bits_unpacked[1u])) << 8u) | (((uint32_t)(v_bits_unpacked[2u])) << 16u) | (((uint32_t)(v_bits_unpacked[3u])) << 24u))) { v_bits_unpacked[0u] = 0u; v_bits_unpacked[1u] = 0u; v_bits_unpacked[2u] = 0u; v_bits_unpacked[3u] = 0u; } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(v_bits_unpacked, 4)); } else { wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(v_bits_unpacked, 1)); } } v_x += (((uint32_t)(1u)) << WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][0u]); } } else { while (v_x < self->private_impl.f_frame_rect_x1) { v_i = (((uint64_t)(v_x)) * v_dst_bytes_per_pixel); if (v_i <= ((uint64_t)(v_dst.len))) { if (self->private_impl.f_color_type == 0u) { if (2u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[1u]; v_bits_unpacked[1u] = v_s.ptr[0u]; v_bits_unpacked[2u] = v_s.ptr[1u]; v_bits_unpacked[3u] = v_s.ptr[0u]; v_bits_unpacked[4u] = v_s.ptr[1u]; v_bits_unpacked[5u] = v_s.ptr[0u]; v_bits_unpacked[6u] = 255u; v_bits_unpacked[7u] = 255u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 2u); if (self->private_impl.f_remap_transparency == ((((uint64_t)(v_bits_unpacked[0u])) << 0u) | (((uint64_t)(v_bits_unpacked[1u])) << 8u) | (((uint64_t)(v_bits_unpacked[2u])) << 16u) | (((uint64_t)(v_bits_unpacked[3u])) << 24u) | (((uint64_t)(v_bits_unpacked[4u])) << 32u) | (((uint64_t)(v_bits_unpacked[5u])) << 40u) | (((uint64_t)(v_bits_unpacked[6u])) << 48u) | (((uint64_t)(v_bits_unpacked[7u])) << 56u))) { v_bits_unpacked[0u] = 0u; v_bits_unpacked[1u] = 0u; v_bits_unpacked[2u] = 0u; v_bits_unpacked[3u] = 0u; v_bits_unpacked[4u] = 0u; v_bits_unpacked[5u] = 0u; v_bits_unpacked[6u] = 0u; v_bits_unpacked[7u] = 0u; } } } else if (self->private_impl.f_color_type == 2u) { if (6u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[5u]; v_bits_unpacked[1u] = v_s.ptr[4u]; v_bits_unpacked[2u] = v_s.ptr[3u]; v_bits_unpacked[3u] = v_s.ptr[2u]; v_bits_unpacked[4u] = v_s.ptr[1u]; v_bits_unpacked[5u] = v_s.ptr[0u]; v_bits_unpacked[6u] = 255u; v_bits_unpacked[7u] = 255u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 6u); if (self->private_impl.f_remap_transparency == ((((uint64_t)(v_bits_unpacked[0u])) << 0u) | (((uint64_t)(v_bits_unpacked[1u])) << 8u) | (((uint64_t)(v_bits_unpacked[2u])) << 16u) | (((uint64_t)(v_bits_unpacked[3u])) << 24u) | (((uint64_t)(v_bits_unpacked[4u])) << 32u) | (((uint64_t)(v_bits_unpacked[5u])) << 40u) | (((uint64_t)(v_bits_unpacked[6u])) << 48u) | (((uint64_t)(v_bits_unpacked[7u])) << 56u))) { v_bits_unpacked[0u] = 0u; v_bits_unpacked[1u] = 0u; v_bits_unpacked[2u] = 0u; v_bits_unpacked[3u] = 0u; v_bits_unpacked[4u] = 0u; v_bits_unpacked[5u] = 0u; v_bits_unpacked[6u] = 0u; v_bits_unpacked[7u] = 0u; } } } else if (self->private_impl.f_color_type == 4u) { if (4u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[1u]; v_bits_unpacked[1u] = v_s.ptr[0u]; v_bits_unpacked[2u] = v_s.ptr[1u]; v_bits_unpacked[3u] = v_s.ptr[0u]; v_bits_unpacked[4u] = v_s.ptr[1u]; v_bits_unpacked[5u] = v_s.ptr[0u]; v_bits_unpacked[6u] = v_s.ptr[3u]; v_bits_unpacked[7u] = v_s.ptr[2u]; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } } else { if (8u <= ((uint64_t)(v_s.len))) { v_bits_unpacked[0u] = v_s.ptr[5u]; v_bits_unpacked[1u] = v_s.ptr[4u]; v_bits_unpacked[2u] = v_s.ptr[3u]; v_bits_unpacked[3u] = v_s.ptr[2u]; v_bits_unpacked[4u] = v_s.ptr[1u]; v_bits_unpacked[5u] = v_s.ptr[0u]; v_bits_unpacked[6u] = v_s.ptr[7u]; v_bits_unpacked[7u] = v_s.ptr[6u]; v_s = wuffs_base__slice_u8__subslice_i(v_s, 8u); } } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), v_dst_palette, wuffs_base__make_slice_u8(v_bits_unpacked, 8)); } v_x += (((uint32_t)(1u)) << WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][0u]); } } v_prev_row = v_curr_row; v_y += (((uint32_t)(1u)) << WUFFS_PNG__INTERLACING[self->private_impl.f_interlace_pass][3u]); } return wuffs_base__make_status(NULL); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__PNG) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__QOI) // ---------------- Status Codes Implementations const char wuffs_qoi__error__bad_footer[] = "#qoi: bad footer"; const char wuffs_qoi__error__bad_header[] = "#qoi: bad header"; const char wuffs_qoi__error__truncated_input[] = "#qoi: truncated input"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_image_config( wuffs_qoi__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_frame_config( wuffs_qoi__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_frame( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__from_src_to_buffer( wuffs_qoi__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__from_buffer_to_dst( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_qoi__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_qoi__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_qoi__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_qoi__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_qoi__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_qoi__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_qoi__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_qoi__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_qoi__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_qoi__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_qoi__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_qoi__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_qoi__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_qoi__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_qoi__decoder__initialize( wuffs_qoi__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_qoi__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_qoi__decoder* wuffs_qoi__decoder__alloc(void) { wuffs_qoi__decoder* x = (wuffs_qoi__decoder*)(calloc(1, sizeof(wuffs_qoi__decoder))); if (!x) { return NULL; } if (wuffs_qoi__decoder__initialize( x, sizeof(wuffs_qoi__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_qoi__decoder(void) { return sizeof(wuffs_qoi__decoder); } // ---------------- Function Implementations // -------- func qoi.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__get_quirk( const wuffs_qoi__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func qoi.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__set_quirk( wuffs_qoi__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func qoi.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_image_config( wuffs_qoi__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_qoi__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_qoi__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func qoi.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_image_config( wuffs_qoi__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_a = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_a = t_0; } if (v_a != 1718185841u) { status = wuffs_base__make_status(wuffs_qoi__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_1); if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch >> 32)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)); } } v_a = t_1; } if (v_a > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_width = v_a; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32be__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_2); if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch >> 32)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)); } } v_a = t_2; } if (v_a > 16777215u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } self->private_impl.f_height = v_a; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_3 = *iop_a_src++; v_a = t_3; } if (v_a == 3u) { self->private_impl.f_pixfmt = 2415954056u; } else if (v_a == 4u) { self->private_impl.f_pixfmt = 2164295816u; } else { status = wuffs_base__make_status(wuffs_qoi__error__bad_header); goto exit; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src++; if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, 14u, (self->private_impl.f_pixfmt == 2415954056u)); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func qoi.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_frame_config( wuffs_qoi__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_qoi__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_qoi__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func qoi.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_frame_config( wuffs_qoi__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_qoi__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (16u != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, 14u, 0u, (self->private_impl.f_pixfmt == 2415954056u), false, 0u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func qoi.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__decode_frame( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_qoi__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_qoi__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func qoi.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__do_decode_frame( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint64_t v_c64 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_qoi__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette(a_dst), wuffs_base__utility__make_pixel_format(self->private_impl.f_pixfmt), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y = 0u; self->private_data.f_pixel[0u] = 0u; self->private_data.f_pixel[1u] = 0u; self->private_data.f_pixel[2u] = 0u; self->private_data.f_pixel[3u] = 255u; wuffs_private_impl__bulk_memset(&self->private_data.f_cache[0], 256u, 0u); self->private_impl.f_remaining_pixels_times_4 = (((uint64_t)(self->private_impl.f_width)) * ((uint64_t)(self->private_impl.f_height)) * 4u); while (self->private_impl.f_remaining_pixels_times_4 > 0u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_qoi__decoder__from_src_to_buffer(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (self->private_impl.f_remaining_pixels_times_4 < ((uint64_t)(self->private_impl.f_buffer_index))) { status = wuffs_base__make_status(wuffs_base__error__too_much_data); goto exit; } self->private_impl.f_remaining_pixels_times_4 -= ((uint64_t)(self->private_impl.f_buffer_index)); v_status = wuffs_qoi__decoder__from_buffer_to_dst(self, a_dst); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_0 = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_decode_frame.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_frame.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_0); if (num_bits_0 == 56) { t_0 = ((uint64_t)(*scratch >> 0)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)); } } v_c64 = t_0; } if (v_c64 != 1u) { status = wuffs_base__make_status(wuffs_qoi__error__bad_footer); goto exit; } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func qoi.decoder.from_src_to_buffer WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__from_src_to_buffer( wuffs_qoi__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint8_t v_dg = 0; uint32_t v_bi = 0; uint32_t v_bj = 0; uint32_t v_bk = 0; uint32_t v_ci = 0; uint32_t v_hash4 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_from_src_to_buffer; if (coro_susp_point) { v_dg = self->private_data.s_from_src_to_buffer.v_dg; v_bi = self->private_data.s_from_src_to_buffer.v_bi; v_bk = self->private_data.s_from_src_to_buffer.v_bk; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_bk = 7936u; if (self->private_impl.f_remaining_pixels_times_4 < 7936u) { v_bk = ((uint32_t)(self->private_impl.f_remaining_pixels_times_4)); } while (v_bi < v_bk) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 == 254u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; self->private_data.f_pixel[2u] = t_1; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; self->private_data.f_pixel[1u] = t_2; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; self->private_data.f_pixel[0u] = t_3; } } else if (v_c8 == 255u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; self->private_data.f_pixel[2u] = t_4; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; self->private_data.f_pixel[1u] = t_5; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; self->private_data.f_pixel[0u] = t_6; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_7 = *iop_a_src++; self->private_data.f_pixel[3u] = t_7; } } else if (((uint8_t)(v_c8 >> 6u)) == 0u) { v_ci = (4u * ((uint32_t)(((uint8_t)(v_c8 & 63u))))); self->private_data.f_pixel[0u] = self->private_data.f_cache[(v_ci + 0u)]; self->private_data.f_pixel[1u] = self->private_data.f_cache[(v_ci + 1u)]; self->private_data.f_pixel[2u] = self->private_data.f_cache[(v_ci + 2u)]; self->private_data.f_pixel[3u] = self->private_data.f_cache[(v_ci + 3u)]; self->private_data.f_buffer[(v_bi + 0u)] = self->private_data.f_pixel[0u]; self->private_data.f_buffer[(v_bi + 1u)] = self->private_data.f_pixel[1u]; self->private_data.f_buffer[(v_bi + 2u)] = self->private_data.f_pixel[2u]; self->private_data.f_buffer[(v_bi + 3u)] = self->private_data.f_pixel[3u]; v_bi += 4u; continue; } else if (((uint8_t)(v_c8 >> 6u)) == 1u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_pixel[2u] += ((uint8_t)(((uint8_t)(((uint8_t)(v_c8 >> 4u)) & 3u)) + 254u)); self->private_data.f_pixel[1u] += ((uint8_t)(((uint8_t)(((uint8_t)(v_c8 >> 2u)) & 3u)) + 254u)); self->private_data.f_pixel[0u] += ((uint8_t)(((uint8_t)(((uint8_t)(v_c8 >> 0u)) & 3u)) + 254u)); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (((uint8_t)(v_c8 >> 6u)) == 2u) { v_dg = ((uint8_t)(((uint8_t)(v_c8 & 63u)) + 224u)); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; v_c8 = t_8; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_data.f_pixel[2u] += ((uint8_t)(((uint8_t)(v_dg + 248u)) + ((uint8_t)(15u & ((uint8_t)(v_c8 >> 4u)))))); self->private_data.f_pixel[1u] += v_dg; self->private_data.f_pixel[0u] += ((uint8_t)(((uint8_t)(v_dg + 248u)) + ((uint8_t)(15u & ((uint8_t)(v_c8 >> 0u)))))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { v_bj = (v_bi + (4u * (63u & (1u + ((uint32_t)(v_c8)))))); while (v_bi < v_bj) { self->private_data.f_buffer[(v_bi + 0u)] = self->private_data.f_pixel[0u]; self->private_data.f_buffer[(v_bi + 1u)] = self->private_data.f_pixel[1u]; self->private_data.f_buffer[(v_bi + 2u)] = self->private_data.f_pixel[2u]; self->private_data.f_buffer[(v_bi + 3u)] = self->private_data.f_pixel[3u]; v_bi += 4u; } continue; } v_hash4 = (4u * (63u & ((((uint32_t)(self->private_data.f_pixel[2u])) * 3u) + (((uint32_t)(self->private_data.f_pixel[1u])) * 5u) + (((uint32_t)(self->private_data.f_pixel[0u])) * 7u) + (((uint32_t)(self->private_data.f_pixel[3u])) * 11u)))); self->private_data.f_cache[(v_hash4 + 0u)] = self->private_data.f_pixel[0u]; self->private_data.f_cache[(v_hash4 + 1u)] = self->private_data.f_pixel[1u]; self->private_data.f_cache[(v_hash4 + 2u)] = self->private_data.f_pixel[2u]; self->private_data.f_cache[(v_hash4 + 3u)] = self->private_data.f_pixel[3u]; self->private_data.f_buffer[(v_bi + 0u)] = self->private_data.f_pixel[0u]; self->private_data.f_buffer[(v_bi + 1u)] = self->private_data.f_pixel[1u]; self->private_data.f_buffer[(v_bi + 2u)] = self->private_data.f_pixel[2u]; self->private_data.f_buffer[(v_bi + 3u)] = self->private_data.f_pixel[3u]; v_bi += 4u; } self->private_impl.f_buffer_index = v_bi; goto ok; ok: self->private_impl.p_from_src_to_buffer = 0; goto exit; } goto suspend; suspend: self->private_impl.p_from_src_to_buffer = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_from_src_to_buffer.v_dg = v_dg; self->private_data.s_from_src_to_buffer.v_bi = v_bi; self->private_data.s_from_src_to_buffer.v_bk = v_bk; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func qoi.decoder.from_buffer_to_dst WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_qoi__decoder__from_buffer_to_dst( wuffs_qoi__decoder* self, wuffs_base__pixel_buffer* a_dst) { wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; wuffs_base__table_u8 v_tab = {0}; uint32_t v_bi = 0; uint32_t v_rem_x = 0; wuffs_base__slice_u8 v_dst = {0}; wuffs_base__slice_u8 v_src = {0}; uint32_t v_src_length = 0; uint64_t v_i = 0; v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); while (v_bi < self->private_impl.f_buffer_index) { if (self->private_impl.f_width <= self->private_impl.f_dst_x) { self->private_impl.f_dst_x = 0u; self->private_impl.f_dst_y += 1u; if (self->private_impl.f_dst_y >= self->private_impl.f_height) { break; } v_rem_x = self->private_impl.f_width; } else { v_rem_x = (self->private_impl.f_width - self->private_impl.f_dst_x); } v_src = wuffs_base__make_slice_u8_ij(self->private_data.f_buffer, v_bi, self->private_impl.f_buffer_index); if (((uint64_t)((4u * v_rem_x))) < ((uint64_t)(v_src.len))) { v_src = wuffs_base__slice_u8__subslice_j(v_src, ((uint64_t)((4u * v_rem_x)))); } v_src_length = ((uint32_t)(((uint64_t)(v_src.len)))); v_bi += v_src_length; v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, self->private_impl.f_dst_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } v_i = (((uint64_t)(self->private_impl.f_dst_x)) * ((uint64_t)(v_dst_bytes_per_pixel))); self->private_impl.f_dst_x += (v_src_length / 4u); if (v_i < ((uint64_t)(v_dst.len))) { wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, wuffs_base__slice_u8__subslice_i(v_dst, v_i), wuffs_base__pixel_buffer__palette(a_dst), v_src); } } return wuffs_base__make_status(NULL); } // -------- func qoi.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_qoi__decoder__frame_dirty_rect( const wuffs_qoi__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func qoi.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_qoi__decoder__num_animation_loops( const wuffs_qoi__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func qoi.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__num_decoded_frame_configs( const wuffs_qoi__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func qoi.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_qoi__decoder__num_decoded_frames( const wuffs_qoi__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func qoi.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__restart_frame( wuffs_qoi__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if ((a_index != 0u) || (a_io_position != 14u)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; return wuffs_base__make_status(NULL); } // -------- func qoi.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_qoi__decoder__set_report_metadata( wuffs_qoi__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func qoi.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_qoi__decoder__tell_me_more( wuffs_qoi__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func qoi.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_qoi__decoder__workbuf_len( const wuffs_qoi__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__QOI) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__SHA256) // ---------------- Status Codes Implementations // ---------------- Private Consts static const uint32_t WUFFS_SHA256__INITIAL_SHA256_H[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 1779033703u, 3144134277u, 1013904242u, 2773480762u, 1359893119u, 2600822924u, 528734635u, 1541459225u, }; static const uint32_t WUFFS_SHA256__K[64] WUFFS_BASE__POTENTIALLY_UNUSED = { 1116352408u, 1899447441u, 3049323471u, 3921009573u, 961987163u, 1508970993u, 2453635748u, 2870763221u, 3624381080u, 310598401u, 607225278u, 1426881987u, 1925078388u, 2162078206u, 2614888103u, 3248222580u, 3835390401u, 4022224774u, 264347078u, 604807628u, 770255983u, 1249150122u, 1555081692u, 1996064986u, 2554220882u, 2821834349u, 2952996808u, 3210313671u, 3336571891u, 3584528711u, 113926993u, 338241895u, 666307205u, 773529912u, 1294757372u, 1396182291u, 1695183700u, 1986661051u, 2177026350u, 2456956037u, 2730485921u, 2820302411u, 3259730800u, 3345764771u, 3516065817u, 3600352804u, 4094571909u, 275423344u, 430227734u, 506948616u, 659060556u, 883997877u, 958139571u, 1322822218u, 1537002063u, 1747873779u, 1955562222u, 2024104815u, 2227730452u, 2361852424u, 2428436474u, 2756734187u, 3204031479u, 3329325298u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_sha256__hasher__up( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x); // ---------------- VTables const wuffs_base__hasher_bitvec256__func_ptrs wuffs_sha256__hasher__func_ptrs_for__wuffs_base__hasher_bitvec256 = { (wuffs_base__bitvec256(*)(const void*))(&wuffs_sha256__hasher__checksum_bitvec256), (uint64_t(*)(const void*, uint32_t))(&wuffs_sha256__hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_sha256__hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_sha256__hasher__update), (wuffs_base__bitvec256(*)(void*, wuffs_base__slice_u8))(&wuffs_sha256__hasher__update_bitvec256), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_sha256__hasher__initialize( wuffs_sha256__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_bitvec256.vtable_name = wuffs_base__hasher_bitvec256__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_bitvec256.function_pointers = (const void*)(&wuffs_sha256__hasher__func_ptrs_for__wuffs_base__hasher_bitvec256); return wuffs_base__make_status(NULL); } wuffs_sha256__hasher* wuffs_sha256__hasher__alloc(void) { wuffs_sha256__hasher* x = (wuffs_sha256__hasher*)(calloc(1, sizeof(wuffs_sha256__hasher))); if (!x) { return NULL; } if (wuffs_sha256__hasher__initialize( x, sizeof(wuffs_sha256__hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_sha256__hasher(void) { return sizeof(wuffs_sha256__hasher); } // ---------------- Function Implementations // -------- func sha256.hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_sha256__hasher__get_quirk( const wuffs_sha256__hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func sha256.hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_sha256__hasher__set_quirk( wuffs_sha256__hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func sha256.hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_sha256__hasher__update( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } uint64_t v_new_lmu = 0; if ((self->private_impl.f_length_modulo_u64 == 0u) && ! self->private_impl.f_length_overflows_u64) { self->private_impl.f_h0 = WUFFS_SHA256__INITIAL_SHA256_H[0u]; self->private_impl.f_h1 = WUFFS_SHA256__INITIAL_SHA256_H[1u]; self->private_impl.f_h2 = WUFFS_SHA256__INITIAL_SHA256_H[2u]; self->private_impl.f_h3 = WUFFS_SHA256__INITIAL_SHA256_H[3u]; self->private_impl.f_h4 = WUFFS_SHA256__INITIAL_SHA256_H[4u]; self->private_impl.f_h5 = WUFFS_SHA256__INITIAL_SHA256_H[5u]; self->private_impl.f_h6 = WUFFS_SHA256__INITIAL_SHA256_H[6u]; self->private_impl.f_h7 = WUFFS_SHA256__INITIAL_SHA256_H[7u]; } v_new_lmu = ((uint64_t)(self->private_impl.f_length_modulo_u64 + ((uint64_t)(a_x.len)))); self->private_impl.f_length_overflows_u64 = ((v_new_lmu < self->private_impl.f_length_modulo_u64) || self->private_impl.f_length_overflows_u64); self->private_impl.f_length_modulo_u64 = v_new_lmu; if (self->private_impl.f_buf_len != 0u) { while (self->private_impl.f_buf_len < 64u) { if (((uint64_t)(a_x.len)) <= 0u) { return wuffs_base__make_empty_struct(); } self->private_impl.f_buf_data[self->private_impl.f_buf_len] = a_x.ptr[0u]; self->private_impl.f_buf_len += 1u; a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } self->private_impl.f_buf_len = 0u; wuffs_sha256__hasher__up(self, wuffs_base__make_slice_u8(self->private_impl.f_buf_data, 64)); } wuffs_sha256__hasher__up(self, a_x); return wuffs_base__make_empty_struct(); } // -------- func sha256.hasher.update_bitvec256 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_sha256__hasher__update_bitvec256( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } wuffs_sha256__hasher__update(self, a_x); return wuffs_sha256__hasher__checksum_bitvec256(self); } // -------- func sha256.hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_sha256__hasher__up( wuffs_sha256__hasher* self, wuffs_base__slice_u8 a_x) { wuffs_base__slice_u8 v_p = {0}; uint32_t v_w[64] = {0}; uint32_t v_w2 = 0; uint32_t v_w15 = 0; uint32_t v_s0 = 0; uint32_t v_s1 = 0; uint32_t v_t1 = 0; uint32_t v_t2 = 0; uint32_t v_a = 0; uint32_t v_b = 0; uint32_t v_c = 0; uint32_t v_d = 0; uint32_t v_e = 0; uint32_t v_f = 0; uint32_t v_g = 0; uint32_t v_h = 0; uint32_t v_i = 0; uint32_t v_buf_len = 0; v_a = self->private_impl.f_h0; v_b = self->private_impl.f_h1; v_c = self->private_impl.f_h2; v_d = self->private_impl.f_h3; v_e = self->private_impl.f_h4; v_f = self->private_impl.f_h5; v_g = self->private_impl.f_h6; v_h = self->private_impl.f_h7; { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 64; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 64) * 64)); while (v_p.ptr < i_end0_p) { v_w[0u] = ((((uint32_t)(v_p.ptr[0u])) << 24u) | (((uint32_t)(v_p.ptr[1u])) << 16u) | (((uint32_t)(v_p.ptr[2u])) << 8u) | ((uint32_t)(v_p.ptr[3u]))); v_w[1u] = ((((uint32_t)(v_p.ptr[4u])) << 24u) | (((uint32_t)(v_p.ptr[5u])) << 16u) | (((uint32_t)(v_p.ptr[6u])) << 8u) | ((uint32_t)(v_p.ptr[7u]))); v_w[2u] = ((((uint32_t)(v_p.ptr[8u])) << 24u) | (((uint32_t)(v_p.ptr[9u])) << 16u) | (((uint32_t)(v_p.ptr[10u])) << 8u) | ((uint32_t)(v_p.ptr[11u]))); v_w[3u] = ((((uint32_t)(v_p.ptr[12u])) << 24u) | (((uint32_t)(v_p.ptr[13u])) << 16u) | (((uint32_t)(v_p.ptr[14u])) << 8u) | ((uint32_t)(v_p.ptr[15u]))); v_w[4u] = ((((uint32_t)(v_p.ptr[16u])) << 24u) | (((uint32_t)(v_p.ptr[17u])) << 16u) | (((uint32_t)(v_p.ptr[18u])) << 8u) | ((uint32_t)(v_p.ptr[19u]))); v_w[5u] = ((((uint32_t)(v_p.ptr[20u])) << 24u) | (((uint32_t)(v_p.ptr[21u])) << 16u) | (((uint32_t)(v_p.ptr[22u])) << 8u) | ((uint32_t)(v_p.ptr[23u]))); v_w[6u] = ((((uint32_t)(v_p.ptr[24u])) << 24u) | (((uint32_t)(v_p.ptr[25u])) << 16u) | (((uint32_t)(v_p.ptr[26u])) << 8u) | ((uint32_t)(v_p.ptr[27u]))); v_w[7u] = ((((uint32_t)(v_p.ptr[28u])) << 24u) | (((uint32_t)(v_p.ptr[29u])) << 16u) | (((uint32_t)(v_p.ptr[30u])) << 8u) | ((uint32_t)(v_p.ptr[31u]))); v_w[8u] = ((((uint32_t)(v_p.ptr[32u])) << 24u) | (((uint32_t)(v_p.ptr[33u])) << 16u) | (((uint32_t)(v_p.ptr[34u])) << 8u) | ((uint32_t)(v_p.ptr[35u]))); v_w[9u] = ((((uint32_t)(v_p.ptr[36u])) << 24u) | (((uint32_t)(v_p.ptr[37u])) << 16u) | (((uint32_t)(v_p.ptr[38u])) << 8u) | ((uint32_t)(v_p.ptr[39u]))); v_w[10u] = ((((uint32_t)(v_p.ptr[40u])) << 24u) | (((uint32_t)(v_p.ptr[41u])) << 16u) | (((uint32_t)(v_p.ptr[42u])) << 8u) | ((uint32_t)(v_p.ptr[43u]))); v_w[11u] = ((((uint32_t)(v_p.ptr[44u])) << 24u) | (((uint32_t)(v_p.ptr[45u])) << 16u) | (((uint32_t)(v_p.ptr[46u])) << 8u) | ((uint32_t)(v_p.ptr[47u]))); v_w[12u] = ((((uint32_t)(v_p.ptr[48u])) << 24u) | (((uint32_t)(v_p.ptr[49u])) << 16u) | (((uint32_t)(v_p.ptr[50u])) << 8u) | ((uint32_t)(v_p.ptr[51u]))); v_w[13u] = ((((uint32_t)(v_p.ptr[52u])) << 24u) | (((uint32_t)(v_p.ptr[53u])) << 16u) | (((uint32_t)(v_p.ptr[54u])) << 8u) | ((uint32_t)(v_p.ptr[55u]))); v_w[14u] = ((((uint32_t)(v_p.ptr[56u])) << 24u) | (((uint32_t)(v_p.ptr[57u])) << 16u) | (((uint32_t)(v_p.ptr[58u])) << 8u) | ((uint32_t)(v_p.ptr[59u]))); v_w[15u] = ((((uint32_t)(v_p.ptr[60u])) << 24u) | (((uint32_t)(v_p.ptr[61u])) << 16u) | (((uint32_t)(v_p.ptr[62u])) << 8u) | ((uint32_t)(v_p.ptr[63u]))); v_i = 16u; while (v_i < 64u) { v_w2 = v_w[(v_i - 2u)]; v_s1 = ((v_w2 >> 10u) ^ (((uint32_t)(v_w2 << 15u)) | (v_w2 >> 17u)) ^ (((uint32_t)(v_w2 << 13u)) | (v_w2 >> 19u))); v_w15 = v_w[(v_i - 15u)]; v_s0 = ((v_w15 >> 3u) ^ (((uint32_t)(v_w15 << 25u)) | (v_w15 >> 7u)) ^ (((uint32_t)(v_w15 << 14u)) | (v_w15 >> 18u))); v_w[v_i] = ((uint32_t)(((uint32_t)(((uint32_t)(v_s1 + v_w[(v_i - 7u)])) + v_s0)) + v_w[(v_i - 16u)])); v_i += 1u; } v_i = 0u; while (v_i < 64u) { v_t1 = v_h; v_t1 += ((((uint32_t)(v_e << 26u)) | (v_e >> 6u)) ^ (((uint32_t)(v_e << 21u)) | (v_e >> 11u)) ^ (((uint32_t)(v_e << 7u)) | (v_e >> 25u))); v_t1 += ((v_e & v_f) ^ ((4294967295u ^ v_e) & v_g)); v_t1 += WUFFS_SHA256__K[v_i]; v_t1 += v_w[v_i]; v_t2 = ((((uint32_t)(v_a << 30u)) | (v_a >> 2u)) ^ (((uint32_t)(v_a << 19u)) | (v_a >> 13u)) ^ (((uint32_t)(v_a << 10u)) | (v_a >> 22u))); v_t2 += ((v_a & v_b) ^ (v_a & v_c) ^ (v_b & v_c)); v_h = v_g; v_g = v_f; v_f = v_e; v_e = ((uint32_t)(v_d + v_t1)); v_d = v_c; v_c = v_b; v_b = v_a; v_a = ((uint32_t)(v_t1 + v_t2)); v_i += 1u; } v_a += self->private_impl.f_h0; self->private_impl.f_h0 = v_a; v_b += self->private_impl.f_h1; self->private_impl.f_h1 = v_b; v_c += self->private_impl.f_h2; self->private_impl.f_h2 = v_c; v_d += self->private_impl.f_h3; self->private_impl.f_h3 = v_d; v_e += self->private_impl.f_h4; self->private_impl.f_h4 = v_e; v_f += self->private_impl.f_h5; self->private_impl.f_h5 = v_f; v_g += self->private_impl.f_h6; self->private_impl.f_h6 = v_g; v_h += self->private_impl.f_h7; self->private_impl.f_h7 = v_h; v_p.ptr += 64; } v_p.len = 1; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end1_p) { self->private_impl.f_buf_data[v_buf_len] = v_p.ptr[0u]; v_buf_len = ((v_buf_len + 1u) & 63u); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_buf_len = ((uint32_t)((((uint64_t)(a_x.len)) & 63u))); return wuffs_base__make_empty_struct(); } // -------- func sha256.hasher.checksum_bitvec256 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__bitvec256 wuffs_sha256__hasher__checksum_bitvec256( const wuffs_sha256__hasher* self) { if (!self) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_bitvec256(0u, 0u, 0u, 0u); } uint32_t v_buf_len = 0; uint8_t v_buf_data[64] = {0}; uint64_t v_length_in_bits = 0; uint32_t v_w[64] = {0}; uint32_t v_w2 = 0; uint32_t v_w15 = 0; uint32_t v_s0 = 0; uint32_t v_s1 = 0; uint32_t v_t1 = 0; uint32_t v_t2 = 0; uint32_t v_h0 = 0; uint32_t v_h1 = 0; uint32_t v_h2 = 0; uint32_t v_h3 = 0; uint32_t v_h4 = 0; uint32_t v_h5 = 0; uint32_t v_h6 = 0; uint32_t v_h7 = 0; uint32_t v_a = 0; uint32_t v_b = 0; uint32_t v_c = 0; uint32_t v_d = 0; uint32_t v_e = 0; uint32_t v_f = 0; uint32_t v_g = 0; uint32_t v_h = 0; uint32_t v_i = 0; bool v_final_block = false; v_i = 0u; while (v_i < 64u) { v_buf_data[v_i] = self->private_impl.f_buf_data[v_i]; v_i += 1u; } v_buf_len = (self->private_impl.f_buf_len & 63u); if (v_buf_len < 56u) { v_buf_data[v_buf_len] = 128u; v_buf_len += 1u; while (v_buf_len < 56u) { v_buf_data[v_buf_len] = 0u; v_buf_len += 1u; } v_final_block = true; } else { v_buf_data[v_buf_len] = 128u; v_buf_len += 1u; while (v_buf_len < 64u) { v_buf_data[v_buf_len] = 0u; v_buf_len += 1u; } } v_h0 = self->private_impl.f_h0; v_a = v_h0; v_h1 = self->private_impl.f_h1; v_b = v_h1; v_h2 = self->private_impl.f_h2; v_c = v_h2; v_h3 = self->private_impl.f_h3; v_d = v_h3; v_h4 = self->private_impl.f_h4; v_e = v_h4; v_h5 = self->private_impl.f_h5; v_f = v_h5; v_h6 = self->private_impl.f_h6; v_g = v_h6; v_h7 = self->private_impl.f_h7; v_h = v_h7; while (true) { if (v_final_block) { v_length_in_bits = ((uint64_t)(self->private_impl.f_length_modulo_u64 * 8u)); v_buf_data[56u] = ((uint8_t)((v_length_in_bits >> 56u))); v_buf_data[57u] = ((uint8_t)((v_length_in_bits >> 48u))); v_buf_data[58u] = ((uint8_t)((v_length_in_bits >> 40u))); v_buf_data[59u] = ((uint8_t)((v_length_in_bits >> 32u))); v_buf_data[60u] = ((uint8_t)((v_length_in_bits >> 24u))); v_buf_data[61u] = ((uint8_t)((v_length_in_bits >> 16u))); v_buf_data[62u] = ((uint8_t)((v_length_in_bits >> 8u))); v_buf_data[63u] = ((uint8_t)(v_length_in_bits)); } v_w[0u] = ((((uint32_t)(v_buf_data[0u])) << 24u) | (((uint32_t)(v_buf_data[1u])) << 16u) | (((uint32_t)(v_buf_data[2u])) << 8u) | ((uint32_t)(v_buf_data[3u]))); v_w[1u] = ((((uint32_t)(v_buf_data[4u])) << 24u) | (((uint32_t)(v_buf_data[5u])) << 16u) | (((uint32_t)(v_buf_data[6u])) << 8u) | ((uint32_t)(v_buf_data[7u]))); v_w[2u] = ((((uint32_t)(v_buf_data[8u])) << 24u) | (((uint32_t)(v_buf_data[9u])) << 16u) | (((uint32_t)(v_buf_data[10u])) << 8u) | ((uint32_t)(v_buf_data[11u]))); v_w[3u] = ((((uint32_t)(v_buf_data[12u])) << 24u) | (((uint32_t)(v_buf_data[13u])) << 16u) | (((uint32_t)(v_buf_data[14u])) << 8u) | ((uint32_t)(v_buf_data[15u]))); v_w[4u] = ((((uint32_t)(v_buf_data[16u])) << 24u) | (((uint32_t)(v_buf_data[17u])) << 16u) | (((uint32_t)(v_buf_data[18u])) << 8u) | ((uint32_t)(v_buf_data[19u]))); v_w[5u] = ((((uint32_t)(v_buf_data[20u])) << 24u) | (((uint32_t)(v_buf_data[21u])) << 16u) | (((uint32_t)(v_buf_data[22u])) << 8u) | ((uint32_t)(v_buf_data[23u]))); v_w[6u] = ((((uint32_t)(v_buf_data[24u])) << 24u) | (((uint32_t)(v_buf_data[25u])) << 16u) | (((uint32_t)(v_buf_data[26u])) << 8u) | ((uint32_t)(v_buf_data[27u]))); v_w[7u] = ((((uint32_t)(v_buf_data[28u])) << 24u) | (((uint32_t)(v_buf_data[29u])) << 16u) | (((uint32_t)(v_buf_data[30u])) << 8u) | ((uint32_t)(v_buf_data[31u]))); v_w[8u] = ((((uint32_t)(v_buf_data[32u])) << 24u) | (((uint32_t)(v_buf_data[33u])) << 16u) | (((uint32_t)(v_buf_data[34u])) << 8u) | ((uint32_t)(v_buf_data[35u]))); v_w[9u] = ((((uint32_t)(v_buf_data[36u])) << 24u) | (((uint32_t)(v_buf_data[37u])) << 16u) | (((uint32_t)(v_buf_data[38u])) << 8u) | ((uint32_t)(v_buf_data[39u]))); v_w[10u] = ((((uint32_t)(v_buf_data[40u])) << 24u) | (((uint32_t)(v_buf_data[41u])) << 16u) | (((uint32_t)(v_buf_data[42u])) << 8u) | ((uint32_t)(v_buf_data[43u]))); v_w[11u] = ((((uint32_t)(v_buf_data[44u])) << 24u) | (((uint32_t)(v_buf_data[45u])) << 16u) | (((uint32_t)(v_buf_data[46u])) << 8u) | ((uint32_t)(v_buf_data[47u]))); v_w[12u] = ((((uint32_t)(v_buf_data[48u])) << 24u) | (((uint32_t)(v_buf_data[49u])) << 16u) | (((uint32_t)(v_buf_data[50u])) << 8u) | ((uint32_t)(v_buf_data[51u]))); v_w[13u] = ((((uint32_t)(v_buf_data[52u])) << 24u) | (((uint32_t)(v_buf_data[53u])) << 16u) | (((uint32_t)(v_buf_data[54u])) << 8u) | ((uint32_t)(v_buf_data[55u]))); v_w[14u] = ((((uint32_t)(v_buf_data[56u])) << 24u) | (((uint32_t)(v_buf_data[57u])) << 16u) | (((uint32_t)(v_buf_data[58u])) << 8u) | ((uint32_t)(v_buf_data[59u]))); v_w[15u] = ((((uint32_t)(v_buf_data[60u])) << 24u) | (((uint32_t)(v_buf_data[61u])) << 16u) | (((uint32_t)(v_buf_data[62u])) << 8u) | ((uint32_t)(v_buf_data[63u]))); v_i = 16u; while (v_i < 64u) { v_w2 = v_w[(v_i - 2u)]; v_s1 = ((v_w2 >> 10u) ^ (((uint32_t)(v_w2 << 15u)) | (v_w2 >> 17u)) ^ (((uint32_t)(v_w2 << 13u)) | (v_w2 >> 19u))); v_w15 = v_w[(v_i - 15u)]; v_s0 = ((v_w15 >> 3u) ^ (((uint32_t)(v_w15 << 25u)) | (v_w15 >> 7u)) ^ (((uint32_t)(v_w15 << 14u)) | (v_w15 >> 18u))); v_w[v_i] = ((uint32_t)(((uint32_t)(((uint32_t)(v_s1 + v_w[(v_i - 7u)])) + v_s0)) + v_w[(v_i - 16u)])); v_i += 1u; } v_i = 0u; while (v_i < 64u) { v_t1 = v_h; v_t1 += ((((uint32_t)(v_e << 26u)) | (v_e >> 6u)) ^ (((uint32_t)(v_e << 21u)) | (v_e >> 11u)) ^ (((uint32_t)(v_e << 7u)) | (v_e >> 25u))); v_t1 += ((v_e & v_f) ^ ((4294967295u ^ v_e) & v_g)); v_t1 += WUFFS_SHA256__K[v_i]; v_t1 += v_w[v_i]; v_t2 = ((((uint32_t)(v_a << 30u)) | (v_a >> 2u)) ^ (((uint32_t)(v_a << 19u)) | (v_a >> 13u)) ^ (((uint32_t)(v_a << 10u)) | (v_a >> 22u))); v_t2 += ((v_a & v_b) ^ (v_a & v_c) ^ (v_b & v_c)); v_h = v_g; v_g = v_f; v_f = v_e; v_e = ((uint32_t)(v_d + v_t1)); v_d = v_c; v_c = v_b; v_b = v_a; v_a = ((uint32_t)(v_t1 + v_t2)); v_i += 1u; } v_a += v_h0; v_b += v_h1; v_c += v_h2; v_d += v_h3; v_e += v_h4; v_f += v_h5; v_g += v_h6; v_h += v_h7; if (v_final_block) { break; } v_final_block = true; v_h0 = v_a; v_h1 = v_b; v_h2 = v_c; v_h3 = v_d; v_h4 = v_e; v_h5 = v_f; v_h6 = v_g; v_h7 = v_h; v_buf_len = 0u; while (v_buf_len < 56u) { v_buf_data[v_buf_len] = 0u; v_buf_len += 1u; } } return wuffs_base__utility__make_bitvec256( (((uint64_t)(v_h)) | (((uint64_t)(v_g)) << 32u)), (((uint64_t)(v_f)) | (((uint64_t)(v_e)) << 32u)), (((uint64_t)(v_d)) | (((uint64_t)(v_c)) << 32u)), (((uint64_t)(v_b)) | (((uint64_t)(v_a)) << 32u))); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__SHA256) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__TGA) // ---------------- Status Codes Implementations const char wuffs_tga__error__bad_header[] = "#tga: bad header"; const char wuffs_tga__error__bad_run_length_encoding[] = "#tga: bad run length encoding"; const char wuffs_tga__error__truncated_input[] = "#tga: truncated input"; const char wuffs_tga__error__unsupported_tga_file[] = "#tga: unsupported TGA file"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_image_config( wuffs_tga__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_frame_config( wuffs_tga__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_frame( wuffs_tga__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_tga__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_tga__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_tga__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_tga__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_tga__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_tga__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_tga__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_tga__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_tga__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_tga__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_tga__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_tga__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_tga__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_tga__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_tga__decoder__initialize( wuffs_tga__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_tga__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_tga__decoder* wuffs_tga__decoder__alloc(void) { wuffs_tga__decoder* x = (wuffs_tga__decoder*)(calloc(1, sizeof(wuffs_tga__decoder))); if (!x) { return NULL; } if (wuffs_tga__decoder__initialize( x, sizeof(wuffs_tga__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_tga__decoder(void) { return sizeof(wuffs_tga__decoder); } // ---------------- Function Implementations // -------- func tga.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__get_quirk( const wuffs_tga__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func tga.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__set_quirk( wuffs_tga__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func tga.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_image_config( wuffs_tga__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_tga__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_tga__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func tga.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_image_config( wuffs_tga__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; uint32_t v_c5 = 0; uint32_t v_i = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; if (coro_susp_point) { v_i = self->private_data.s_do_decode_image_config.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; self->private_impl.f_header_id_length = t_0; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; self->private_impl.f_header_color_map_type = t_1; } if (self->private_impl.f_header_color_map_type > 1u) { status = wuffs_base__make_status(wuffs_tga__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; self->private_impl.f_header_image_type = t_2; } if ((self->private_impl.f_header_image_type == 1u) || (self->private_impl.f_header_image_type == 2u) || (self->private_impl.f_header_image_type == 3u) || (self->private_impl.f_header_image_type == 9u) || (self->private_impl.f_header_image_type == 10u) || (self->private_impl.f_header_image_type == 11u)) { } else { status = wuffs_base__make_status(wuffs_tga__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); uint16_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_3 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 8) { t_3 = ((uint16_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } self->private_impl.f_header_color_map_first_entry_index = t_3; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); uint16_t t_4; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_4 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_4 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_4; if (num_bits_4 == 8) { t_4 = ((uint16_t)(*scratch)); break; } num_bits_4 += 8u; *scratch |= ((uint64_t)(num_bits_4)) << 56; } } self->private_impl.f_header_color_map_length = t_4; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; self->private_impl.f_header_color_map_entry_size = t_5; } if (self->private_impl.f_header_color_map_type != 0u) { if ((self->private_impl.f_header_color_map_first_entry_index != 0u) || (self->private_impl.f_header_color_map_length > 256u)) { status = wuffs_base__make_status(wuffs_tga__error__unsupported_tga_file); goto exit; } else if ((self->private_impl.f_header_color_map_entry_size != 15u) && (self->private_impl.f_header_color_map_entry_size != 16u) && (self->private_impl.f_header_color_map_entry_size != 24u) && (self->private_impl.f_header_color_map_entry_size != 32u)) { status = wuffs_base__make_status(wuffs_tga__error__bad_header); goto exit; } } else { if ((self->private_impl.f_header_color_map_first_entry_index != 0u) || (self->private_impl.f_header_color_map_length != 0u) || (self->private_impl.f_header_color_map_entry_size != 0u)) { status = wuffs_base__make_status(wuffs_tga__error__bad_header); goto exit; } } self->private_data.s_do_decode_image_config.scratch = 4u; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); uint32_t t_6; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_6 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_6 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_6; if (num_bits_6 == 8) { t_6 = ((uint32_t)(*scratch)); break; } num_bits_6 += 8u; *scratch |= ((uint64_t)(num_bits_6)) << 56; } } self->private_impl.f_width = t_6; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); uint32_t t_7; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_7 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_7 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_7; if (num_bits_7 == 8) { t_7 = ((uint32_t)(*scratch)); break; } num_bits_7 += 8u; *scratch |= ((uint64_t)(num_bits_7)) << 56; } } self->private_impl.f_height = t_7; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; self->private_impl.f_header_pixel_depth = t_8; } if ((self->private_impl.f_header_pixel_depth != 1u) && (self->private_impl.f_header_pixel_depth != 8u) && (self->private_impl.f_header_pixel_depth != 15u) && (self->private_impl.f_header_pixel_depth != 16u) && (self->private_impl.f_header_pixel_depth != 24u) && (self->private_impl.f_header_pixel_depth != 32u)) { status = wuffs_base__make_status(wuffs_tga__error__bad_header); goto exit; } if (((uint8_t)(self->private_impl.f_header_image_type | 8u)) == 9u) { self->private_impl.f_scratch_bytes_per_pixel = 1u; self->private_impl.f_src_bytes_per_pixel = 1u; self->private_impl.f_src_pixfmt = 2164523016u; self->private_impl.f_opaque = ((self->private_impl.f_header_color_map_entry_size == 15u) || (self->private_impl.f_header_color_map_entry_size == 24u)); } else if (((uint8_t)(self->private_impl.f_header_image_type | 8u)) == 10u) { if ((self->private_impl.f_header_pixel_depth == 15u) || (self->private_impl.f_header_pixel_depth == 16u)) { self->private_impl.f_scratch_bytes_per_pixel = 4u; self->private_impl.f_src_bytes_per_pixel = 0u; self->private_impl.f_src_pixfmt = 2164295816u; } else if (self->private_impl.f_header_pixel_depth == 24u) { self->private_impl.f_scratch_bytes_per_pixel = 3u; self->private_impl.f_src_bytes_per_pixel = 3u; self->private_impl.f_src_pixfmt = 2147485832u; self->private_impl.f_opaque = true; } else if (self->private_impl.f_header_pixel_depth == 32u) { self->private_impl.f_scratch_bytes_per_pixel = 4u; self->private_impl.f_src_bytes_per_pixel = 4u; self->private_impl.f_src_pixfmt = 2164295816u; } else { status = wuffs_base__make_status(wuffs_tga__error__unsupported_tga_file); goto exit; } } else { if (self->private_impl.f_header_pixel_depth == 8u) { self->private_impl.f_scratch_bytes_per_pixel = 1u; self->private_impl.f_src_bytes_per_pixel = 1u; self->private_impl.f_src_pixfmt = 536870920u; self->private_impl.f_opaque = true; } else { status = wuffs_base__make_status(wuffs_tga__error__unsupported_tga_file); goto exit; } } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_9 = *iop_a_src++; self->private_impl.f_header_image_descriptor = t_9; } if (((uint8_t)(self->private_impl.f_header_image_descriptor & 16u)) != 0u) { status = wuffs_base__make_status(wuffs_tga__error__unsupported_tga_file); goto exit; } self->private_data.s_do_decode_image_config.scratch = ((uint32_t)(self->private_impl.f_header_id_length)); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); if (self->private_data.s_do_decode_image_config.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_image_config.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_image_config.scratch; if (self->private_impl.f_header_color_map_type != 0u) { while (v_i < ((uint32_t)(self->private_impl.f_header_color_map_length))) { if (self->private_impl.f_header_color_map_entry_size == 24u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(17); uint32_t t_10; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 3)) { t_10 = ((uint32_t)(wuffs_base__peek_u24le__no_bounds_check(iop_a_src))); iop_a_src += 3; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(18); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_10 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_10; if (num_bits_10 == 16) { t_10 = ((uint32_t)(*scratch)); break; } num_bits_10 += 8u; *scratch |= ((uint64_t)(num_bits_10)) << 56; } } v_c32 = t_10; } self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 0u)] = ((uint8_t)((v_c32 >> 0u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 1u)] = ((uint8_t)((v_c32 >> 8u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 2u)] = ((uint8_t)((v_c32 >> 16u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 3u)] = 255u; } else if (self->private_impl.f_header_color_map_entry_size == 32u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(19); uint32_t t_11; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_11 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(20); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_11 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_11; if (num_bits_11 == 24) { t_11 = ((uint32_t)(*scratch)); break; } num_bits_11 += 8u; *scratch |= ((uint64_t)(num_bits_11)) << 56; } } v_c32 = t_11; } self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 0u)] = ((uint8_t)((v_c32 >> 0u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 1u)] = ((uint8_t)((v_c32 >> 8u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 2u)] = ((uint8_t)((v_c32 >> 16u))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 3u)] = ((uint8_t)((v_c32 >> 24u))); } else { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(21); uint32_t t_12; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_12 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(22); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_12 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_12; if (num_bits_12 == 8) { t_12 = ((uint32_t)(*scratch)); break; } num_bits_12 += 8u; *scratch |= ((uint64_t)(num_bits_12)) << 56; } } v_c32 = t_12; } v_c5 = (31u & (v_c32 >> 0u)); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 0u)] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 5u)); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 1u)] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 10u)); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 2u)] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); self->private_data.f_src_palette[(((v_i & 255u) * 4u) + 3u)] = 255u; } v_i += 1u; } while (v_i < 256u) { self->private_data.f_src_palette[((v_i * 4u) + 0u)] = 0u; self->private_data.f_src_palette[((v_i * 4u) + 1u)] = 0u; self->private_data.f_src_palette[((v_i * 4u) + 2u)] = 0u; self->private_data.f_src_palette[((v_i * 4u) + 3u)] = 255u; v_i += 1u; } } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_src_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, self->private_impl.f_opaque); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_image_config.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func tga.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_frame_config( wuffs_tga__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_tga__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_tga__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func tga.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_frame_config( wuffs_tga__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_tga__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, self->private_impl.f_opaque, false, 4278190080u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func tga.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__decode_frame( wuffs_tga__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_tga__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_tga__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func tga.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_tga__decoder__do_decode_frame( wuffs_tga__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint64_t v_dst_bytes_per_pixel = 0; uint32_t v_dst_x = 0; uint32_t v_dst_y = 0; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__slice_u8 v_dst = {0}; uint64_t v_dst_start = 0; wuffs_base__slice_u8 v_src_palette = {0}; uint64_t v_mark = 0; uint64_t v_num_pixels64 = 0; uint32_t v_num_pixels32 = 0; uint32_t v_lit_length = 0; uint32_t v_run_length = 0; uint64_t v_num_dst_bytes = 0; uint32_t v_num_src_bytes = 0; uint32_t v_c32 = 0; uint32_t v_c5 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; if (coro_susp_point) { v_dst_bytes_per_pixel = self->private_data.s_do_decode_frame.v_dst_bytes_per_pixel; v_dst_x = self->private_data.s_do_decode_frame.v_dst_x; v_dst_y = self->private_data.s_do_decode_frame.v_dst_y; v_mark = self->private_data.s_do_decode_frame.v_mark; v_num_pixels32 = self->private_data.s_do_decode_frame.v_num_pixels32; v_lit_length = self->private_data.s_do_decode_frame.v_lit_length; v_run_length = self->private_data.s_do_decode_frame.v_run_length; v_num_dst_bytes = self->private_data.s_do_decode_frame.v_num_dst_bytes; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_tga__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (self->private_impl.f_header_color_map_type != 0u) { v_src_palette = wuffs_base__make_slice_u8(self->private_data.f_src_palette, 1024); } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)), wuffs_base__utility__make_pixel_format(self->private_impl.f_src_pixfmt), v_src_palette, a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = ((uint64_t)((v_dst_bits_per_pixel / 8u))); if (((uint8_t)(self->private_impl.f_header_image_descriptor & 32u)) == 0u) { v_dst_y = ((uint32_t)(self->private_impl.f_height - 1u)); } if (((uint8_t)(self->private_impl.f_header_image_type & 8u)) == 0u) { v_lit_length = self->private_impl.f_width; } label__resume__continue:; while (true) { v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_dst_palette, 1024)); while (v_dst_y < self->private_impl.f_height) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_dst_y); v_dst_start = (((uint64_t)(v_dst_x)) * v_dst_bytes_per_pixel); if (v_dst_start <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_start); } else { v_dst = wuffs_base__utility__empty_slice_u8(); } while (v_dst_x < self->private_impl.f_width) { if (self->private_impl.f_src_bytes_per_pixel > 0u) { if (v_lit_length > 0u) { v_mark = ((uint64_t)(iop_a_src - io0_a_src)); v_num_pixels64 = (((uint64_t)(io2_a_src - iop_a_src)) / ((uint64_t)(self->private_impl.f_src_bytes_per_pixel))); v_num_pixels32 = ((uint32_t)(wuffs_base__u64__min(v_num_pixels64, ((uint64_t)(v_lit_length))))); v_num_dst_bytes = (((uint64_t)(v_num_pixels32)) * v_dst_bytes_per_pixel); v_num_src_bytes = (v_num_pixels32 * self->private_impl.f_src_bytes_per_pixel); self->private_data.s_do_decode_frame.scratch = v_num_src_bytes; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (self->private_data.s_do_decode_frame.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_decode_frame.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_decode_frame.scratch; wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_private_impl__io__since(v_mark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); if (v_num_dst_bytes <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_num_dst_bytes); } else { v_dst = wuffs_base__utility__empty_slice_u8(); } v_dst_x += v_num_pixels32; v_lit_length = (((uint32_t)(v_lit_length - v_num_pixels32)) & 65535u); if (v_lit_length > 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(3); goto label__resume__continue; } } else if (v_run_length > 0u) { v_run_length -= 1u; wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, self->private_impl.f_scratch_bytes_per_pixel)); if (v_dst_bytes_per_pixel <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_bytes_per_pixel); } v_dst_x += 1u; } else { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(4); goto label__resume__continue; } if (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) < 128u) { v_lit_length = (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) + 1u); iop_a_src += 1u; if ((v_lit_length + v_dst_x) > self->private_impl.f_width) { status = wuffs_base__make_status(wuffs_tga__error__bad_run_length_encoding); goto exit; } } else { if (self->private_impl.f_src_bytes_per_pixel == 1u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); goto label__resume__continue; } v_run_length = ((((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) & 127u) + 1u); iop_a_src += 1u; self->private_data.f_scratch[0u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; } else if (self->private_impl.f_src_bytes_per_pixel == 3u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); goto label__resume__continue; } v_run_length = ((((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) & 127u) + 1u); iop_a_src += 1u; self->private_data.f_scratch[0u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; self->private_data.f_scratch[1u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; self->private_data.f_scratch[2u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; } else { if (((uint64_t)(io2_a_src - iop_a_src)) < 5u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); goto label__resume__continue; } v_run_length = ((((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) & 127u) + 1u); iop_a_src += 1u; self->private_data.f_scratch[0u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; self->private_data.f_scratch[1u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; self->private_data.f_scratch[2u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; self->private_data.f_scratch[3u] = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; } if ((v_run_length + v_dst_x) > self->private_impl.f_width) { status = wuffs_base__make_status(wuffs_tga__error__bad_run_length_encoding); goto exit; } } } } else { if (v_lit_length > 0u) { if (((uint64_t)(io2_a_src - iop_a_src)) < 2u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(8); goto label__resume__continue; } v_c32 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2u; v_c5 = (31u & (v_c32 >> 0u)); self->private_data.f_scratch[0u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 5u)); self->private_data.f_scratch[1u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 10u)); self->private_data.f_scratch[2u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); self->private_data.f_scratch[3u] = 255u; wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, 4)); if (v_dst_bytes_per_pixel <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_bytes_per_pixel); } v_dst_x += 1u; v_lit_length -= 1u; } else if (v_run_length > 0u) { v_run_length -= 1u; wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__make_slice_u8(self->private_data.f_scratch, self->private_impl.f_scratch_bytes_per_pixel)); if (v_dst_bytes_per_pixel <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_bytes_per_pixel); } v_dst_x += 1u; } else { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); goto label__resume__continue; } if (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) < 128u) { v_lit_length = (((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) + 1u); iop_a_src += 1u; if ((v_lit_length + v_dst_x) > self->private_impl.f_width) { status = wuffs_base__make_status(wuffs_tga__error__bad_run_length_encoding); goto exit; } } else { if (((uint64_t)(io2_a_src - iop_a_src)) < 3u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); goto label__resume__continue; } v_run_length = ((((uint32_t)(wuffs_base__peek_u8be__no_bounds_check(iop_a_src))) & 127u) + 1u); iop_a_src += 1u; v_c32 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2u; v_c5 = (31u & (v_c32 >> 0u)); self->private_data.f_scratch[0u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 5u)); self->private_data.f_scratch[1u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); v_c5 = (31u & (v_c32 >> 10u)); self->private_data.f_scratch[2u] = ((uint8_t)(((v_c5 << 3u) | (v_c5 >> 2u)))); self->private_data.f_scratch[3u] = 255u; if ((v_run_length + v_dst_x) > self->private_impl.f_width) { status = wuffs_base__make_status(wuffs_tga__error__bad_run_length_encoding); goto exit; } } } } } v_dst_x = 0u; if (((uint8_t)(self->private_impl.f_header_image_descriptor & 32u)) == 0u) { v_dst_y -= 1u; } else { v_dst_y += 1u; } if (((uint8_t)(self->private_impl.f_header_image_type & 8u)) == 0u) { v_lit_length = self->private_impl.f_width; } } break; } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_frame.v_dst_bytes_per_pixel = v_dst_bytes_per_pixel; self->private_data.s_do_decode_frame.v_dst_x = v_dst_x; self->private_data.s_do_decode_frame.v_dst_y = v_dst_y; self->private_data.s_do_decode_frame.v_mark = v_mark; self->private_data.s_do_decode_frame.v_num_pixels32 = v_num_pixels32; self->private_data.s_do_decode_frame.v_lit_length = v_lit_length; self->private_data.s_do_decode_frame.v_run_length = v_run_length; self->private_data.s_do_decode_frame.v_num_dst_bytes = v_num_dst_bytes; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func tga.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_tga__decoder__frame_dirty_rect( const wuffs_tga__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func tga.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_tga__decoder__num_animation_loops( const wuffs_tga__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func tga.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__num_decoded_frame_configs( const wuffs_tga__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func tga.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_tga__decoder__num_decoded_frames( const wuffs_tga__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func tga.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__restart_frame( wuffs_tga__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if (a_index != 0u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; self->private_impl.f_frame_config_io_position = a_io_position; return wuffs_base__make_status(NULL); } // -------- func tga.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_tga__decoder__set_report_metadata( wuffs_tga__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func tga.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_tga__decoder__tell_me_more( wuffs_tga__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func tga.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_tga__decoder__workbuf_len( const wuffs_tga__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__TGA) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__VP8) // ---------------- Status Codes Implementations // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes // ---------------- VTables // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_vp8__placeholder__initialize( wuffs_vp8__placeholder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; return wuffs_base__make_status(NULL); } wuffs_vp8__placeholder* wuffs_vp8__placeholder__alloc(void) { wuffs_vp8__placeholder* x = (wuffs_vp8__placeholder*)(calloc(1, sizeof(wuffs_vp8__placeholder))); if (!x) { return NULL; } if (wuffs_vp8__placeholder__initialize( x, sizeof(wuffs_vp8__placeholder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_vp8__placeholder(void) { return sizeof(wuffs_vp8__placeholder); } // ---------------- Function Implementations #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__VP8) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WBMP) // ---------------- Status Codes Implementations const char wuffs_wbmp__error__bad_header[] = "#wbmp: bad header"; const char wuffs_wbmp__error__truncated_input[] = "#wbmp: truncated input"; // ---------------- Private Consts // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_image_config( wuffs_wbmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_frame_config( wuffs_wbmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_frame( wuffs_wbmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_wbmp__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_wbmp__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_wbmp__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_wbmp__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_wbmp__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_wbmp__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_wbmp__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_wbmp__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_wbmp__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_wbmp__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_wbmp__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_wbmp__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_wbmp__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_wbmp__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_wbmp__decoder__initialize( wuffs_wbmp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_wbmp__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_wbmp__decoder* wuffs_wbmp__decoder__alloc(void) { wuffs_wbmp__decoder* x = (wuffs_wbmp__decoder*)(calloc(1, sizeof(wuffs_wbmp__decoder))); if (!x) { return NULL; } if (wuffs_wbmp__decoder__initialize( x, sizeof(wuffs_wbmp__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_wbmp__decoder(void) { return sizeof(wuffs_wbmp__decoder); } // ---------------- Function Implementations // -------- func wbmp.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__get_quirk( const wuffs_wbmp__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func wbmp.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__set_quirk( wuffs_wbmp__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func wbmp.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_image_config( wuffs_wbmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_wbmp__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_wbmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func wbmp.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_image_config( wuffs_wbmp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_i = 0; uint32_t v_p = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; if (coro_susp_point) { v_i = self->private_data.s_do_decode_image_config.v_i; v_p = self->private_data.s_do_decode_image_config.v_p; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } v_i = 0u; while (v_i < 2u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_wbmp__error__bad_header); goto exit; } v_i += 1u; } v_i = 0u; while (v_i < 2u) { v_p = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } v_p |= ((uint32_t)(((uint8_t)(v_c8 & 127u)))); if (((uint8_t)(v_c8 >> 7u)) == 0u) { break; } else if (v_p > 131071u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_image_dimension); goto exit; } v_p <<= 7u; } if (v_i == 0u) { self->private_impl.f_width = v_p; } else { self->private_impl.f_height = v_p; } v_i += 1u; } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, 2198077448u, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, true); } self->private_impl.f_call_sequence = 32u; goto ok; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_image_config.v_i = v_i; self->private_data.s_do_decode_image_config.v_p = v_p; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func wbmp.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_frame_config( wuffs_wbmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_wbmp__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_wbmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func wbmp.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_frame_config( wuffs_wbmp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_wbmp__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, true, false, 4278190080u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func wbmp.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__decode_frame( wuffs_wbmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_wbmp__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_wbmp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func wbmp.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_wbmp__decoder__do_decode_frame( wuffs_wbmp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint64_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_x_in_bytes = 0; uint32_t v_dst_x = 0; uint32_t v_dst_y = 0; wuffs_base__table_u8 v_tab = {0}; wuffs_base__slice_u8 v_dst = {0}; uint8_t v_src[1] = {0}; uint8_t v_c8 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; if (coro_susp_point) { v_dst_bytes_per_pixel = self->private_data.s_do_decode_frame.v_dst_bytes_per_pixel; v_dst_x = self->private_data.s_do_decode_frame.v_dst_x; v_dst_y = self->private_data.s_do_decode_frame.v_dst_y; memcpy(v_src, self->private_data.s_do_decode_frame.v_src, sizeof(v_src)); v_c8 = self->private_data.s_do_decode_frame.v_c8; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_wbmp__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette(a_dst), wuffs_base__utility__make_pixel_format(536870920u), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { status = wuffs_base__make_status(wuffs_base__error__unsupported_option); goto exit; } v_dst_bytes_per_pixel = ((uint64_t)((v_dst_bits_per_pixel / 8u))); if (self->private_impl.f_width > 0u) { v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); while (v_dst_y < self->private_impl.f_height) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_dst_y); v_dst_x = 0u; while (v_dst_x < self->private_impl.f_width) { if ((v_dst_x & 7u) == 0u) { while (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_dst_y); v_dst_x_in_bytes = (((uint64_t)(v_dst_x)) * v_dst_bytes_per_pixel); if (v_dst_x_in_bytes <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_x_in_bytes); } } v_c8 = wuffs_base__peek_u8be__no_bounds_check(iop_a_src); iop_a_src += 1u; } if (((uint8_t)(v_c8 & 128u)) == 0u) { v_src[0u] = 0u; } else { v_src[0u] = 255u; } v_c8 = ((uint8_t)((((uint32_t)(v_c8)) << 1u))); wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, wuffs_base__utility__empty_slice_u8(), wuffs_base__make_slice_u8(v_src, 1)); if (v_dst_bytes_per_pixel <= ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_i(v_dst, v_dst_bytes_per_pixel); } v_dst_x += 1u; } v_dst_y += 1u; } } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_frame.v_dst_bytes_per_pixel = v_dst_bytes_per_pixel; self->private_data.s_do_decode_frame.v_dst_x = v_dst_x; self->private_data.s_do_decode_frame.v_dst_y = v_dst_y; memcpy(self->private_data.s_do_decode_frame.v_src, v_src, sizeof(v_src)); self->private_data.s_do_decode_frame.v_c8 = v_c8; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func wbmp.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_wbmp__decoder__frame_dirty_rect( const wuffs_wbmp__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func wbmp.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_wbmp__decoder__num_animation_loops( const wuffs_wbmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func wbmp.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__num_decoded_frame_configs( const wuffs_wbmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func wbmp.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_wbmp__decoder__num_decoded_frames( const wuffs_wbmp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func wbmp.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__restart_frame( wuffs_wbmp__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if (a_index != 0u) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; self->private_impl.f_frame_config_io_position = a_io_position; return wuffs_base__make_status(NULL); } // -------- func wbmp.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_wbmp__decoder__set_report_metadata( wuffs_wbmp__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func wbmp.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_wbmp__decoder__tell_me_more( wuffs_wbmp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func wbmp.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_wbmp__decoder__workbuf_len( const wuffs_wbmp__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(0u, 0u); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WBMP) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WEBP) // ---------------- Status Codes Implementations const char wuffs_webp__error__bad_huffman_code_over_subscribed[] = "#webp: bad Huffman code (over-subscribed)"; const char wuffs_webp__error__bad_huffman_code_under_subscribed[] = "#webp: bad Huffman code (under-subscribed)"; const char wuffs_webp__error__bad_huffman_code[] = "#webp: bad Huffman code"; const char wuffs_webp__error__bad_back_reference[] = "#webp: bad back-reference"; const char wuffs_webp__error__bad_color_cache[] = "#webp: bad color cache"; const char wuffs_webp__error__bad_header[] = "#webp: bad header"; const char wuffs_webp__error__bad_transform[] = "#webp: bad transform"; const char wuffs_webp__error__short_chunk[] = "#webp: short chunk"; const char wuffs_webp__error__truncated_input[] = "#webp: truncated input"; const char wuffs_webp__error__unsupported_number_of_huffman_groups[] = "#webp: unsupported number of Huffman groups"; const char wuffs_webp__error__unsupported_transform_after_color_indexing_transform[] = "#webp: unsupported transform after color indexing transform"; const char wuffs_webp__error__unsupported_webp_file[] = "#webp: unsupported WebP file"; const char wuffs_webp__error__internal_error_inconsistent_huffman_code[] = "#webp: internal error: inconsistent Huffman code"; const char wuffs_webp__error__internal_error_inconsistent_dst_buffer[] = "#webp: internal error: inconsistent dst buffer"; const char wuffs_webp__error__internal_error_inconsistent_n_bits[] = "#webp: internal error: inconsistent n_bits"; // ---------------- Private Consts static const uint8_t WUFFS_WEBP__CODE_LENGTH_CODE_ORDER[19] WUFFS_BASE__POTENTIALLY_UNUSED = { 17u, 18u, 0u, 1u, 2u, 3u, 4u, 5u, 16u, 6u, 7u, 8u, 9u, 10u, 11u, 12u, 13u, 14u, 15u, }; static const uint8_t WUFFS_WEBP__REPEAT_N_BITS[4] WUFFS_BASE__POTENTIALLY_UNUSED = { 2u, 3u, 7u, 0u, }; static const uint8_t WUFFS_WEBP__REPEAT_COUNTS[4] WUFFS_BASE__POTENTIALLY_UNUSED = { 3u, 3u, 11u, 0u, }; static const uint16_t WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[5] WUFFS_BASE__POTENTIALLY_UNUSED = { 1612u, 0u, 511u, 1022u, 1533u, }; static const uint8_t WUFFS_WEBP__DISTANCE_MAP[120] WUFFS_BASE__POTENTIALLY_UNUSED = { 24u, 7u, 23u, 25u, 40u, 6u, 39u, 41u, 22u, 26u, 38u, 42u, 56u, 5u, 55u, 57u, 21u, 27u, 54u, 58u, 37u, 43u, 72u, 4u, 71u, 73u, 20u, 28u, 53u, 59u, 70u, 74u, 36u, 44u, 88u, 69u, 75u, 52u, 60u, 3u, 87u, 89u, 19u, 29u, 86u, 90u, 35u, 45u, 68u, 76u, 85u, 91u, 51u, 61u, 104u, 2u, 103u, 105u, 18u, 30u, 102u, 106u, 34u, 46u, 84u, 92u, 67u, 77u, 101u, 107u, 50u, 62u, 120u, 1u, 119u, 121u, 83u, 93u, 17u, 31u, 100u, 108u, 66u, 78u, 118u, 122u, 33u, 47u, 117u, 123u, 49u, 63u, 99u, 109u, 82u, 94u, 0u, 116u, 124u, 65u, 79u, 16u, 32u, 98u, 110u, 48u, 115u, 125u, 81u, 95u, 64u, 114u, 126u, 97u, 111u, 80u, 113u, 127u, 96u, 112u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_groups( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_n_huffman_groups); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_tree( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_hg, uint32_t a_ht); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_tree_simple( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_hg, uint32_t a_ht); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_code_length_code_lengths( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_code_lengths_huffman_nodes( wuffs_webp__decoder* self); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_huffman_nodes( wuffs_webp__decoder* self, uint32_t a_hg, uint32_t a_ht); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_code_lengths( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_pixels_slow( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_dst, wuffs_base__io_buffer* a_src, uint32_t a_width, uint32_t a_height, wuffs_base__slice_u8 a_tile_data, uint32_t a_tile_size_log2); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_predictor( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix, wuffs_base__slice_u8 a_tile_data); WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_webp__decoder__absolute_difference( const wuffs_webp__decoder* self, uint32_t a_a, uint32_t a_b); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_webp__decoder__mode12( const wuffs_webp__decoder* self, uint8_t a_l, uint8_t a_t, uint8_t a_tl); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_webp__decoder__mode13( const wuffs_webp__decoder* self, uint8_t a_l, uint8_t a_t, uint8_t a_tl); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_cross_color( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix, wuffs_base__slice_u8 a_tile_data); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_subtract_green( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_color_indexing( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config( wuffs_webp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config_limited( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config_limited_vp8l( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_frame_config( wuffs_webp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_frame( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_transform( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_color_cache_parameters( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_hg_table( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_width, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_pixels( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_dst, wuffs_base__io_buffer* a_src, uint32_t a_width, uint32_t a_height, wuffs_base__slice_u8 a_tile_data, uint32_t a_tile_size_log2); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__swizzle( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_src, wuffs_base__pixel_blend a_blend); // ---------------- VTables const wuffs_base__image_decoder__func_ptrs wuffs_webp__decoder__func_ptrs_for__wuffs_base__image_decoder = { (wuffs_base__status(*)(void*, wuffs_base__pixel_buffer*, wuffs_base__io_buffer*, wuffs_base__pixel_blend, wuffs_base__slice_u8, wuffs_base__decode_frame_options*))(&wuffs_webp__decoder__decode_frame), (wuffs_base__status(*)(void*, wuffs_base__frame_config*, wuffs_base__io_buffer*))(&wuffs_webp__decoder__decode_frame_config), (wuffs_base__status(*)(void*, wuffs_base__image_config*, wuffs_base__io_buffer*))(&wuffs_webp__decoder__decode_image_config), (wuffs_base__rect_ie_u32(*)(const void*))(&wuffs_webp__decoder__frame_dirty_rect), (uint64_t(*)(const void*, uint32_t))(&wuffs_webp__decoder__get_quirk), (uint32_t(*)(const void*))(&wuffs_webp__decoder__num_animation_loops), (uint64_t(*)(const void*))(&wuffs_webp__decoder__num_decoded_frame_configs), (uint64_t(*)(const void*))(&wuffs_webp__decoder__num_decoded_frames), (wuffs_base__status(*)(void*, uint64_t, uint64_t))(&wuffs_webp__decoder__restart_frame), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_webp__decoder__set_quirk), (wuffs_base__empty_struct(*)(void*, uint32_t, bool))(&wuffs_webp__decoder__set_report_metadata), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*))(&wuffs_webp__decoder__tell_me_more), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_webp__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_webp__decoder__initialize( wuffs_webp__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__image_decoder.vtable_name = wuffs_base__image_decoder__vtable_name; self->private_impl.vtable_for__wuffs_base__image_decoder.function_pointers = (const void*)(&wuffs_webp__decoder__func_ptrs_for__wuffs_base__image_decoder); return wuffs_base__make_status(NULL); } wuffs_webp__decoder* wuffs_webp__decoder__alloc(void) { wuffs_webp__decoder* x = (wuffs_webp__decoder*)(calloc(1, sizeof(wuffs_webp__decoder))); if (!x) { return NULL; } if (wuffs_webp__decoder__initialize( x, sizeof(wuffs_webp__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_webp__decoder(void) { return sizeof(wuffs_webp__decoder); } // ---------------- Function Implementations // -------- func webp.decoder.decode_huffman_groups WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_groups( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_n_huffman_groups) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_hg = 0; uint32_t v_ht = 0; uint32_t coro_susp_point = self->private_impl.p_decode_huffman_groups; if (coro_susp_point) { v_hg = self->private_data.s_decode_huffman_groups.v_hg; v_ht = self->private_data.s_decode_huffman_groups.v_ht; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_hg = 0u; while (v_hg < a_n_huffman_groups) { v_ht = 0u; while (v_ht < 5u) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_webp__decoder__decode_huffman_tree(self, a_src, v_hg, v_ht); if (status.repr) { goto suspend; } v_ht += 1u; } v_hg += 1u; } goto ok; ok: self->private_impl.p_decode_huffman_groups = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_huffman_groups = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_huffman_groups.v_hg = v_hg; self->private_data.s_decode_huffman_groups.v_ht = v_ht; goto exit; exit: return status; } // -------- func webp.decoder.decode_huffman_tree WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_tree( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_hg, uint32_t a_ht) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_use_simple = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_huffman_tree; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (a_ht >= 4u) { self->private_impl.f_ht_n_symbols = 40u; } else if (a_ht > 0u) { self->private_impl.f_ht_n_symbols = 256u; } else if (self->private_impl.f_color_cache_bits == 0u) { self->private_impl.f_ht_n_symbols = 280u; } else { self->private_impl.f_ht_n_symbols = (280u + (((uint32_t)(1u)) << self->private_impl.f_color_cache_bits)); } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_use_simple = (self->private_impl.f_bits & 1u); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; if (v_use_simple != 0u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); status = wuffs_webp__decoder__decode_huffman_tree_simple(self, a_src, a_hg, a_ht); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_webp__decoder__decode_code_length_code_lengths(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } v_status = wuffs_webp__decoder__build_code_lengths_huffman_nodes(self); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_webp__decoder__build_code_lengths(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } v_status = wuffs_webp__decoder__build_huffman_nodes(self, a_hg, a_ht); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } } ok: self->private_impl.p_decode_huffman_tree = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_huffman_tree = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_huffman_tree_simple WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_huffman_tree_simple( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_hg, uint32_t a_ht) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_use_second_symbol = 0; uint32_t v_first_symbol_n_bits = 0; uint32_t v_symbol0 = 0; uint32_t v_symbol1 = 0; uint32_t v_base_offset = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_huffman_tree_simple; if (coro_susp_point) { v_use_second_symbol = self->private_data.s_decode_huffman_tree_simple.v_use_second_symbol; v_first_symbol_n_bits = self->private_data.s_decode_huffman_tree_simple.v_first_symbol_n_bits; v_symbol0 = self->private_data.s_decode_huffman_tree_simple.v_symbol0; v_base_offset = self->private_data.s_decode_huffman_tree_simple.v_base_offset; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 2u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (self->private_impl.f_n_bits >= 2u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_use_second_symbol = (self->private_impl.f_bits & 1u); v_first_symbol_n_bits = ((((self->private_impl.f_bits & 2u) >> 1u) * 7u) + 1u); self->private_impl.f_bits >>= 2u; self->private_impl.f_n_bits -= 2u; if (self->private_impl.f_n_bits < v_first_symbol_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= v_first_symbol_n_bits) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_symbol0 = (self->private_impl.f_bits & ((((uint32_t)(1u)) << v_first_symbol_n_bits) - 1u)); self->private_impl.f_bits >>= v_first_symbol_n_bits; self->private_impl.f_n_bits -= v_first_symbol_n_bits; v_base_offset = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[a_ht])); if (v_use_second_symbol != 0u) { if (self->private_impl.f_n_bits < 8u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (self->private_impl.f_n_bits >= 8u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_symbol1 = (self->private_impl.f_bits & 255u); self->private_impl.f_bits >>= 8u; self->private_impl.f_n_bits -= 8u; self->private_data.f_huffman_nodes[a_hg][(v_base_offset + 0u)] = ((uint16_t)((v_base_offset + 1u))); self->private_data.f_huffman_nodes[a_hg][(v_base_offset + 1u)] = ((uint16_t)((v_symbol0 | 32768u))); self->private_data.f_huffman_nodes[a_hg][(v_base_offset + 2u)] = ((uint16_t)((v_symbol1 | 32768u))); } else { self->private_data.f_huffman_nodes[a_hg][v_base_offset] = ((uint16_t)((v_symbol0 | 32768u))); } goto ok; ok: self->private_impl.p_decode_huffman_tree_simple = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_huffman_tree_simple = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_huffman_tree_simple.v_use_second_symbol = v_use_second_symbol; self->private_data.s_decode_huffman_tree_simple.v_first_symbol_n_bits = v_first_symbol_n_bits; self->private_data.s_decode_huffman_tree_simple.v_symbol0 = v_symbol0; self->private_data.s_decode_huffman_tree_simple.v_base_offset = v_base_offset; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_code_length_code_lengths WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_code_length_code_lengths( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_n_codes = 0; uint32_t v_i = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_code_length_code_lengths; if (coro_susp_point) { v_n_codes = self->private_data.s_decode_code_length_code_lengths.v_n_codes; v_i = self->private_data.s_decode_code_length_code_lengths.v_i; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 4u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (self->private_impl.f_n_bits >= 4u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_n_codes = ((self->private_impl.f_bits & 15u) + 4u); self->private_impl.f_bits >>= 4u; self->private_impl.f_n_bits -= 4u; v_i = 0u; while (v_i < v_n_codes) { if (self->private_impl.f_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= 3u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } self->private_impl.f_code_length_code_lengths[WUFFS_WEBP__CODE_LENGTH_CODE_ORDER[v_i]] = ((uint8_t)((self->private_impl.f_bits & 7u))); self->private_impl.f_bits >>= 3u; self->private_impl.f_n_bits -= 3u; v_i += 1u; } while (v_i < 19u) { self->private_impl.f_code_length_code_lengths[WUFFS_WEBP__CODE_LENGTH_CODE_ORDER[v_i]] = 0u; v_i += 1u; } goto ok; ok: self->private_impl.p_decode_code_length_code_lengths = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_code_length_code_lengths = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_code_length_code_lengths.v_n_codes = v_n_codes; self->private_data.s_decode_code_length_code_lengths.v_i = v_i; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.build_code_lengths_huffman_nodes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_code_lengths_huffman_nodes( wuffs_webp__decoder* self) { uint32_t v_code_bits = 0; uint32_t v_code_len = 0; uint32_t v_symbol = 0; uint32_t v_histogram[8] = {0}; uint32_t v_n_used_symbols = 0; uint32_t v_last_used_symbol = 0; uint32_t v_subscription_weight = 0; uint32_t v_subscription_total = 0; uint32_t v_curr_code = 0; uint32_t v_next_codes[9] = {0}; uint32_t v_n_branches = 0; uint32_t v_h = 0; uint32_t v_children = 0; uint16_t v_node = 0; v_symbol = 0u; while (v_symbol < 19u) { v_code_len = ((uint32_t)(self->private_impl.f_code_length_code_lengths[v_symbol])); if (v_code_len != 0u) { v_histogram[v_code_len] += 1u; v_n_used_symbols += 1u; v_last_used_symbol = v_symbol; } v_symbol += 1u; } if (v_n_used_symbols < 1u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code); } else if (v_n_used_symbols == 1u) { self->private_data.f_code_lengths_huffman_nodes[0u] = ((uint16_t)((v_last_used_symbol | 32768u))); return wuffs_base__make_status(NULL); } v_subscription_weight = 16384u; v_code_len = 1u; while (true) { v_curr_code = ((uint32_t)(((uint32_t)(v_curr_code + v_histogram[v_code_len])) << 1u)); v_next_codes[(v_code_len + 1u)] = v_curr_code; v_subscription_total += ((uint32_t)(v_subscription_weight * v_histogram[v_code_len])); v_subscription_weight >>= 1u; if (v_code_len >= 7u) { break; } v_code_len += 1u; } if (v_subscription_total > 32768u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code_over_subscribed); } else if (v_subscription_total < 32768u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code_under_subscribed); } self->private_data.f_code_lengths_huffman_nodes[0u] = 0u; v_symbol = 0u; while (v_symbol < 19u) { v_code_len = ((uint32_t)(self->private_impl.f_code_length_code_lengths[v_symbol])); if (v_code_len > 0u) { v_code_bits = v_next_codes[v_code_len]; v_next_codes[v_code_len] += 1u; v_code_bits <<= (32u - v_code_len); v_h = 0u; while (v_code_len > 0u) { v_node = self->private_data.f_code_lengths_huffman_nodes[v_h]; if (v_node == 0u) { v_children = ((uint32_t)(1u + ((uint32_t)(2u * v_n_branches)))); v_children = wuffs_base__u32__min(v_children, 35u); self->private_data.f_code_lengths_huffman_nodes[v_h] = ((uint16_t)(v_children)); self->private_data.f_code_lengths_huffman_nodes[(v_children + 0u)] = 0u; self->private_data.f_code_lengths_huffman_nodes[(v_children + 1u)] = 0u; v_h = (v_children + (v_code_bits >> 31u)); v_n_branches += 1u; } else { v_children = ((uint32_t)(v_node)); v_h = (wuffs_base__u32__min(v_children, 35u) + (v_code_bits >> 31u)); } v_code_bits <<= 1u; v_code_len -= 1u; } self->private_data.f_code_lengths_huffman_nodes[v_h] = ((uint16_t)((v_symbol | 32768u))); } v_symbol += 1u; } return wuffs_base__make_status(NULL); } // -------- func webp.decoder.build_huffman_nodes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_huffman_nodes( wuffs_webp__decoder* self, uint32_t a_hg, uint32_t a_ht) { uint32_t v_base_offset = 0; uint32_t v_code_bits = 0; uint32_t v_code_len = 0; uint32_t v_symbol = 0; uint32_t v_histogram[16] = {0}; uint32_t v_n_used_symbols = 0; uint32_t v_last_used_symbol = 0; uint32_t v_subscription_weight = 0; uint32_t v_subscription_total = 0; uint32_t v_curr_code = 0; uint32_t v_next_codes[17] = {0}; uint32_t v_n_branches = 0; uint32_t v_h = 0; uint32_t v_children = 0; uint16_t v_node = 0; v_base_offset = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[a_ht])); v_symbol = 0u; while (v_symbol < self->private_impl.f_ht_n_symbols) { v_code_len = ((uint32_t)(((uint16_t)(self->private_data.f_code_lengths[v_symbol] & 15u)))); if (v_code_len != 0u) { v_histogram[v_code_len] += 1u; v_n_used_symbols += 1u; v_last_used_symbol = v_symbol; } v_symbol += 1u; } if (v_n_used_symbols < 1u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code); } else if (v_n_used_symbols == 1u) { self->private_data.f_huffman_nodes[a_hg][v_base_offset] = ((uint16_t)((v_last_used_symbol | 32768u))); return wuffs_base__make_status(NULL); } v_subscription_weight = 16384u; v_code_len = 1u; while (true) { v_curr_code = ((uint32_t)(((uint32_t)(v_curr_code + v_histogram[v_code_len])) << 1u)); v_next_codes[(v_code_len + 1u)] = v_curr_code; v_subscription_total += ((uint32_t)(v_subscription_weight * v_histogram[v_code_len])); v_subscription_weight >>= 1u; if (v_code_len >= 15u) { break; } v_code_len += 1u; } if (v_subscription_total > 32768u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code_over_subscribed); } else if (v_subscription_total < 32768u) { return wuffs_base__make_status(wuffs_webp__error__bad_huffman_code_under_subscribed); } self->private_data.f_huffman_nodes[a_hg][v_base_offset] = 0u; v_symbol = 0u; while (v_symbol < self->private_impl.f_ht_n_symbols) { v_code_len = ((uint32_t)(((uint16_t)(self->private_data.f_code_lengths[v_symbol] & 15u)))); if (v_code_len != 0u) { v_code_bits = v_next_codes[v_code_len]; v_next_codes[v_code_len] += 1u; v_code_bits <<= (32u - v_code_len); v_h = v_base_offset; while (v_code_len > 0u) { v_node = self->private_data.f_huffman_nodes[a_hg][v_h]; if (v_node == 0u) { v_children = ((uint32_t)(v_base_offset + ((uint32_t)(1u + ((uint32_t)(2u * v_n_branches)))))); v_children = wuffs_base__u32__min(v_children, 6265u); self->private_data.f_huffman_nodes[a_hg][v_h] = ((uint16_t)(v_children)); self->private_data.f_huffman_nodes[a_hg][(v_children + 0u)] = 0u; self->private_data.f_huffman_nodes[a_hg][(v_children + 1u)] = 0u; v_h = (v_children + (v_code_bits >> 31u)); v_n_branches += 1u; } else { v_children = ((uint32_t)(v_node)); v_h = (wuffs_base__u32__min(v_children, 6265u) + (v_code_bits >> 31u)); } v_code_bits <<= 1u; v_code_len -= 1u; } self->private_data.f_huffman_nodes[a_hg][v_h] = ((uint16_t)((v_symbol | 32768u))); } v_symbol += 1u; } return wuffs_base__make_status(NULL); } // -------- func webp.decoder.build_code_lengths WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__build_code_lengths( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_use_length = 0; uint32_t v_length_n_bits = 0; uint32_t v_length = 0; uint16_t v_prev_code_length = 0; uint32_t v_h = 0; uint32_t v_s = 0; uint32_t v_s_max = 0; uint16_t v_node = 0; uint32_t v_symbol = 0; uint16_t v_repeat_value = 0; uint32_t v_repeat_n_bits = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_build_code_lengths; if (coro_susp_point) { v_length_n_bits = self->private_data.s_build_code_lengths.v_length_n_bits; v_prev_code_length = self->private_data.s_build_code_lengths.v_prev_code_length; v_s = self->private_data.s_build_code_lengths.v_s; v_s_max = self->private_data.s_build_code_lengths.v_s_max; v_node = self->private_data.s_build_code_lengths.v_node; v_repeat_value = self->private_data.s_build_code_lengths.v_repeat_value; v_repeat_n_bits = self->private_data.s_build_code_lengths.v_repeat_n_bits; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_use_length = (self->private_impl.f_bits & 1u); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; self->private_impl.f_ht_code_lengths_remaining = self->private_impl.f_ht_n_symbols; if (v_use_length != 0u) { if (self->private_impl.f_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= 3u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_length_n_bits = (((self->private_impl.f_bits & 7u) * 2u) + 2u); self->private_impl.f_bits >>= 3u; self->private_impl.f_n_bits -= 3u; while (self->private_impl.f_n_bits < v_length_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (self->private_impl.f_n_bits >= v_length_n_bits) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_length = ((self->private_impl.f_bits & ((((uint32_t)(1u)) << v_length_n_bits) - 1u)) + 2u); self->private_impl.f_bits >>= v_length_n_bits; self->private_impl.f_n_bits -= v_length_n_bits; if (v_length > self->private_impl.f_ht_n_symbols) { status = wuffs_base__make_status(wuffs_webp__error__bad_huffman_code); goto exit; } self->private_impl.f_ht_code_lengths_remaining = v_length; } v_prev_code_length = 8u; while (v_s < self->private_impl.f_ht_n_symbols) { if (self->private_impl.f_ht_code_lengths_remaining <= 0u) { while (v_s < self->private_impl.f_ht_n_symbols) { self->private_data.f_code_lengths[v_s] = 0u; v_s += 1u; } break; } self->private_impl.f_ht_code_lengths_remaining -= 1u; v_h = 0u; while (true) { v_node = self->private_data.f_code_lengths_huffman_nodes[v_h]; if (v_node >= 32768u) { break; } else if (v_node > 35u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_huffman_code); goto exit; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = (((uint32_t)(v_node)) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_symbol = ((uint32_t)(((uint16_t)(v_node & 32767u)))); if (v_symbol == 0u) { self->private_data.f_code_lengths[v_s] = 0u; v_s += 1u; continue; } else if (v_symbol < 16u) { v_prev_code_length = ((uint16_t)(v_symbol)); self->private_data.f_code_lengths[v_s] = v_prev_code_length; v_s += 1u; continue; } else if (v_symbol == 16u) { v_repeat_value = v_prev_code_length; } else { v_repeat_value = 0u; } v_repeat_n_bits = ((uint32_t)(WUFFS_WEBP__REPEAT_N_BITS[(v_symbol & 3u)])); v_s_max = ((uint32_t)(((uint32_t)(WUFFS_WEBP__REPEAT_COUNTS[(v_symbol & 3u)])) + v_s)); if (self->private_impl.f_n_bits < v_repeat_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if (self->private_impl.f_n_bits >= v_repeat_n_bits) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_s_max += (self->private_impl.f_bits & ((((uint32_t)(1u)) << v_repeat_n_bits) - 1u)); self->private_impl.f_bits >>= v_repeat_n_bits; self->private_impl.f_n_bits -= v_repeat_n_bits; if (v_s_max > self->private_impl.f_ht_n_symbols) { status = wuffs_base__make_status(wuffs_webp__error__bad_huffman_code); goto exit; } while (v_s < v_s_max) { self->private_data.f_code_lengths[v_s] = v_repeat_value; v_s += 1u; } } goto ok; ok: self->private_impl.p_build_code_lengths = 0; goto exit; } goto suspend; suspend: self->private_impl.p_build_code_lengths = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_build_code_lengths.v_length_n_bits = v_length_n_bits; self->private_data.s_build_code_lengths.v_prev_code_length = v_prev_code_length; self->private_data.s_build_code_lengths.v_s = v_s; self->private_data.s_build_code_lengths.v_s_max = v_s_max; self->private_data.s_build_code_lengths.v_node = v_node; self->private_data.s_build_code_lengths.v_repeat_value = v_repeat_value; self->private_data.s_build_code_lengths.v_repeat_n_bits = v_repeat_n_bits; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_pixels_slow WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_pixels_slow( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_dst, wuffs_base__io_buffer* a_src, uint32_t a_width, uint32_t a_height, wuffs_base__slice_u8 a_tile_data, uint32_t a_tile_size_log2) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint64_t v_p = 0; uint64_t v_p_max = 0; uint32_t v_tile_size_log2 = 0; uint32_t v_width_in_tiles = 0; uint32_t v_x = 0; uint32_t v_y = 0; uint32_t v_i = 0; uint32_t v_hg = 0; uint32_t v_h = 0; uint16_t v_node = 0; uint32_t v_pixel_g = 0; uint32_t v_color = 0; wuffs_base__slice_u8 v_dst_pixel = {0}; uint32_t v_back_ref_len_n_bits = 0; uint32_t v_back_ref_len_minus_1 = 0; uint32_t v_back_ref_dist_n_bits = 0; uint32_t v_back_ref_dist_sym = 0; uint32_t v_back_ref_dist_premap_minus_1 = 0; uint32_t v_back_ref_dist_minus_1 = 0; uint32_t v_dm = 0; uint32_t v_dx = 0; uint32_t v_dy = 0; uint64_t v_p_end = 0; uint64_t v_dist4 = 0; uint64_t v_q = 0; wuffs_base__slice_u8 v_color_cache_pixels = {0}; uint64_t v_color_cache_p = 0; uint32_t v_color_cache_shift = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_pixels_slow; if (coro_susp_point) { v_p = self->private_data.s_decode_pixels_slow.v_p; v_p_max = self->private_data.s_decode_pixels_slow.v_p_max; v_tile_size_log2 = self->private_data.s_decode_pixels_slow.v_tile_size_log2; v_width_in_tiles = self->private_data.s_decode_pixels_slow.v_width_in_tiles; v_x = self->private_data.s_decode_pixels_slow.v_x; v_y = self->private_data.s_decode_pixels_slow.v_y; v_hg = self->private_data.s_decode_pixels_slow.v_hg; v_node = self->private_data.s_decode_pixels_slow.v_node; v_color = self->private_data.s_decode_pixels_slow.v_color; v_back_ref_len_n_bits = self->private_data.s_decode_pixels_slow.v_back_ref_len_n_bits; v_back_ref_len_minus_1 = self->private_data.s_decode_pixels_slow.v_back_ref_len_minus_1; v_back_ref_dist_n_bits = self->private_data.s_decode_pixels_slow.v_back_ref_dist_n_bits; v_back_ref_dist_premap_minus_1 = self->private_data.s_decode_pixels_slow.v_back_ref_dist_premap_minus_1; v_color_cache_p = self->private_data.s_decode_pixels_slow.v_color_cache_p; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_p_max = ((uint64_t)((4u * a_width * a_height))); if (((uint64_t)(a_dst.len)) < v_p_max) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_dst_buffer); goto exit; } if (a_tile_size_log2 != 0u) { v_tile_size_log2 = a_tile_size_log2; v_width_in_tiles = ((a_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2); } else { v_tile_size_log2 = 31u; v_width_in_tiles = 1u; } while (v_p < v_p_max) { v_i = ((uint32_t)(((uint32_t)(((uint32_t)(((uint32_t)((v_y >> v_tile_size_log2) * v_width_in_tiles)) + (v_x >> v_tile_size_log2))) * 4u)) + 1u)); if (((uint64_t)(v_i)) < ((uint64_t)(a_tile_data.len))) { v_hg = ((uint32_t)(a_tile_data.ptr[((uint64_t)(v_i))])); } v_h = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[0u])); while (true) { v_node = self->private_data.f_huffman_nodes[v_hg][v_h]; if (v_node >= 32768u) { break; } else if (v_node > 6265u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_huffman_code); goto exit; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = (((uint32_t)(v_node)) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_pixel_g = ((uint32_t)(((uint16_t)(v_node & 32767u)))); if (v_pixel_g < 256u) { v_color = (v_pixel_g << 8u); v_h = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[1u])); while (true) { v_node = self->private_data.f_huffman_nodes[v_hg][v_h]; if (v_node >= 32768u) { break; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = ((((uint32_t)(v_node)) & 4095u) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_color |= (((uint32_t)(((uint16_t)(v_node & 255u)))) << 16u); v_h = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[2u])); while (true) { v_node = self->private_data.f_huffman_nodes[v_hg][v_h]; if (v_node >= 32768u) { break; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = ((((uint32_t)(v_node)) & 4095u) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_color |= (((uint32_t)(((uint16_t)(v_node & 255u)))) << 0u); v_h = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[3u])); while (true) { v_node = self->private_data.f_huffman_nodes[v_hg][v_h]; if (v_node >= 32768u) { break; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = ((((uint32_t)(v_node)) & 4095u) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_color |= (((uint32_t)(((uint16_t)(v_node & 255u)))) << 24u); } else if (v_pixel_g < 280u) { if (v_pixel_g < 260u) { v_back_ref_len_minus_1 = (v_pixel_g - 256u); } else { v_back_ref_len_n_bits = ((v_pixel_g - 258u) >> 1u); v_back_ref_len_minus_1 = ((((uint32_t)(2u)) + (v_pixel_g & 1u)) << v_back_ref_len_n_bits); while (self->private_impl.f_n_bits < v_back_ref_len_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if (self->private_impl.f_n_bits >= v_back_ref_len_n_bits) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_back_ref_len_minus_1 += (self->private_impl.f_bits & ((((uint32_t)(1u)) << v_back_ref_len_n_bits) - 1u)); self->private_impl.f_bits >>= v_back_ref_len_n_bits; self->private_impl.f_n_bits -= v_back_ref_len_n_bits; } v_h = ((uint32_t)(WUFFS_WEBP__HUFFMAN_TABLE_BASE_OFFSETS[4u])); while (true) { v_node = self->private_data.f_huffman_nodes[v_hg][v_h]; if (v_node >= 32768u) { break; } if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_h = ((((uint32_t)(v_node)) & 4095u) + (self->private_impl.f_bits & 1u)); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; } v_back_ref_dist_sym = ((uint32_t)(((uint16_t)(v_node & 32767u)))); if (v_back_ref_dist_sym < 4u) { v_back_ref_dist_premap_minus_1 = v_back_ref_dist_sym; } else if (v_back_ref_dist_sym < 40u) { v_back_ref_dist_n_bits = ((v_back_ref_dist_sym - 2u) >> 1u); v_back_ref_dist_premap_minus_1 = ((((uint32_t)(2u)) + (v_back_ref_dist_sym & 1u)) << v_back_ref_dist_n_bits); while (self->private_impl.f_n_bits < v_back_ref_dist_n_bits) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (self->private_impl.f_n_bits >= v_back_ref_dist_n_bits) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_back_ref_dist_premap_minus_1 += (self->private_impl.f_bits & ((((uint32_t)(1u)) << v_back_ref_dist_n_bits) - 1u)); self->private_impl.f_bits >>= v_back_ref_dist_n_bits; self->private_impl.f_n_bits -= v_back_ref_dist_n_bits; } if (v_back_ref_dist_premap_minus_1 >= 120u) { v_back_ref_dist_minus_1 = (v_back_ref_dist_premap_minus_1 - 120u); } else { v_dm = ((uint32_t)(WUFFS_WEBP__DISTANCE_MAP[v_back_ref_dist_premap_minus_1])); v_dy = (v_dm >> 4u); v_dx = ((uint32_t)(7u - (v_dm & 15u))); v_back_ref_dist_minus_1 = ((uint32_t)((a_width * v_dy) + v_dx)); } v_p_end = (v_p + ((uint64_t)(((v_back_ref_len_minus_1 + 1u) * 4u)))); v_dist4 = ((((uint64_t)(v_back_ref_dist_minus_1)) * 4u) + 4u); if ((v_p_end > v_p_max) || (v_p_end > ((uint64_t)(a_dst.len))) || (v_p < v_dist4)) { status = wuffs_base__make_status(wuffs_webp__error__bad_back_reference); goto exit; } v_q = (v_p - v_dist4); while ((v_q < v_p) && (v_p < v_p_end)) { a_dst.ptr[v_p] = a_dst.ptr[v_q]; v_p += 1u; v_q += 1u; } v_x += (v_back_ref_len_minus_1 + 1u); while (v_x >= a_width) { v_x -= a_width; v_y += 1u; } continue; } else { if ((v_color_cache_p > v_p) || (v_p > ((uint64_t)(a_dst.len)))) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_dst_buffer); goto exit; } v_color_cache_pixels = wuffs_base__slice_u8__subslice_ij(a_dst, v_color_cache_p, v_p); v_color_cache_p = v_p; v_color_cache_shift = ((32u - self->private_impl.f_color_cache_bits) & 31u); while (((uint64_t)(v_color_cache_pixels.len)) >= 4u) { v_color = wuffs_base__peek_u32le__no_bounds_check(v_color_cache_pixels.ptr); self->private_data.f_color_cache[((((uint32_t)(v_color * 506832829u)) >> v_color_cache_shift) & 2047u)] = v_color; v_color_cache_pixels = wuffs_base__slice_u8__subslice_i(v_color_cache_pixels, 4u); } v_color = self->private_data.f_color_cache[((v_pixel_g - 280u) & 2047u)]; } if (v_p > ((uint64_t)(a_dst.len))) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_dst_buffer); goto exit; } v_dst_pixel = wuffs_base__slice_u8__subslice_i(a_dst, v_p); if (((uint64_t)(v_dst_pixel.len)) < 4u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_dst_buffer); goto exit; } wuffs_base__poke_u32le__no_bounds_check(v_dst_pixel.ptr, v_color); v_p += 4u; v_x += 1u; if (v_x == a_width) { v_x = 0u; v_y += 1u; } } goto ok; ok: self->private_impl.p_decode_pixels_slow = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_pixels_slow = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_pixels_slow.v_p = v_p; self->private_data.s_decode_pixels_slow.v_p_max = v_p_max; self->private_data.s_decode_pixels_slow.v_tile_size_log2 = v_tile_size_log2; self->private_data.s_decode_pixels_slow.v_width_in_tiles = v_width_in_tiles; self->private_data.s_decode_pixels_slow.v_x = v_x; self->private_data.s_decode_pixels_slow.v_y = v_y; self->private_data.s_decode_pixels_slow.v_hg = v_hg; self->private_data.s_decode_pixels_slow.v_node = v_node; self->private_data.s_decode_pixels_slow.v_color = v_color; self->private_data.s_decode_pixels_slow.v_back_ref_len_n_bits = v_back_ref_len_n_bits; self->private_data.s_decode_pixels_slow.v_back_ref_len_minus_1 = v_back_ref_len_minus_1; self->private_data.s_decode_pixels_slow.v_back_ref_dist_n_bits = v_back_ref_dist_n_bits; self->private_data.s_decode_pixels_slow.v_back_ref_dist_premap_minus_1 = v_back_ref_dist_premap_minus_1; self->private_data.s_decode_pixels_slow.v_color_cache_p = v_color_cache_p; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.apply_transform_predictor WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_predictor( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix, wuffs_base__slice_u8 a_tile_data) { uint64_t v_w4 = 0; wuffs_base__slice_u8 v_prev_row = {0}; wuffs_base__slice_u8 v_curr_row = {0}; uint32_t v_tile_size_log2 = 0; uint32_t v_tiles_per_row = 0; uint32_t v_mask = 0; uint32_t v_y = 0; uint32_t v_x = 0; uint64_t v_t = 0; wuffs_base__slice_u8 v_tile_data = {0}; uint8_t v_mode = 0; uint32_t v_l0 = 0; uint32_t v_l1 = 0; uint32_t v_l2 = 0; uint32_t v_l3 = 0; uint32_t v_c0 = 0; uint32_t v_c1 = 0; uint32_t v_c2 = 0; uint32_t v_c3 = 0; uint32_t v_t0 = 0; uint32_t v_t1 = 0; uint32_t v_t2 = 0; uint32_t v_t3 = 0; uint32_t v_sum_l = 0; uint32_t v_sum_t = 0; if ((self->private_impl.f_width <= 0u) || (self->private_impl.f_height <= 0u)) { return wuffs_base__make_empty_struct(); } v_w4 = ((uint64_t)((self->private_impl.f_width * 4u))); v_curr_row = wuffs_base__utility__empty_slice_u8(); if (v_w4 <= ((uint64_t)(a_pix.len))) { v_curr_row = wuffs_base__slice_u8__subslice_j(a_pix, v_w4); } if (((uint64_t)(v_curr_row.len)) >= 4u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[3u] += 255u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } while (((uint64_t)(v_curr_row.len)) >= 8u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += v_curr_row.ptr[0u]; v_curr_row.ptr[5u] += v_curr_row.ptr[1u]; v_curr_row.ptr[6u] += v_curr_row.ptr[2u]; v_curr_row.ptr[7u] += v_curr_row.ptr[3u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_curr_row = wuffs_base__slice_u8__subslice_i(v_curr_row, 4u); } v_tile_size_log2 = ((uint32_t)(self->private_impl.f_transform_tile_size_log2[0u])); v_tiles_per_row = ((self->private_impl.f_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2); v_mask = ((((uint32_t)(1u)) << v_tile_size_log2) - 1u); v_y = 1u; while (v_y < self->private_impl.f_height) { v_t = ((uint64_t)((4u * (v_y >> v_tile_size_log2) * v_tiles_per_row))); v_tile_data = wuffs_base__utility__empty_slice_u8(); if (v_t <= ((uint64_t)(a_tile_data.len))) { v_tile_data = wuffs_base__slice_u8__subslice_i(a_tile_data, v_t); if (((uint64_t)(v_tile_data.len)) >= 4u) { v_mode = ((uint8_t)(v_tile_data.ptr[1u] & 15u)); v_tile_data = wuffs_base__slice_u8__subslice_i(v_tile_data, 4u); } } if (v_w4 <= ((uint64_t)(a_pix.len))) { v_prev_row = a_pix; a_pix = wuffs_base__slice_u8__subslice_i(a_pix, v_w4); v_curr_row = a_pix; } if ((((uint64_t)(v_prev_row.len)) >= 4u) && (((uint64_t)(v_curr_row.len)) >= 4u)) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[0u] += v_prev_row.ptr[0u]; v_curr_row.ptr[1u] += v_prev_row.ptr[1u]; v_curr_row.ptr[2u] += v_prev_row.ptr[2u]; v_curr_row.ptr[3u] += v_prev_row.ptr[3u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } v_x = 1u; while (v_x < self->private_impl.f_width) { if (((v_x & v_mask) == 0u) && (((uint64_t)(v_tile_data.len)) >= 4u)) { v_mode = ((uint8_t)(v_tile_data.ptr[1u] & 15u)); v_tile_data = wuffs_base__slice_u8__subslice_i(v_tile_data, 4u); } if ((((uint64_t)(v_prev_row.len)) < 12u) || (((uint64_t)(v_curr_row.len)) < 8u)) { break; } if (v_mode == 0u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[7u] += 255u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 1u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += v_curr_row.ptr[0u]; v_curr_row.ptr[5u] += v_curr_row.ptr[1u]; v_curr_row.ptr[6u] += v_curr_row.ptr[2u]; v_curr_row.ptr[7u] += v_curr_row.ptr[3u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 2u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += v_prev_row.ptr[4u]; v_curr_row.ptr[5u] += v_prev_row.ptr[5u]; v_curr_row.ptr[6u] += v_prev_row.ptr[6u]; v_curr_row.ptr[7u] += v_prev_row.ptr[7u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 3u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += v_prev_row.ptr[8u]; v_curr_row.ptr[5u] += v_prev_row.ptr[9u]; v_curr_row.ptr[6u] += v_prev_row.ptr[10u]; v_curr_row.ptr[7u] += v_prev_row.ptr[11u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 4u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += v_prev_row.ptr[0u]; v_curr_row.ptr[5u] += v_prev_row.ptr[1u]; v_curr_row.ptr[6u] += v_prev_row.ptr[2u]; v_curr_row.ptr[7u] += v_prev_row.ptr[3u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 5u) { v_l0 = ((((uint32_t)(v_curr_row.ptr[0u])) + ((uint32_t)(v_prev_row.ptr[8u]))) / 2u); v_l1 = ((((uint32_t)(v_curr_row.ptr[1u])) + ((uint32_t)(v_prev_row.ptr[9u]))) / 2u); v_l2 = ((((uint32_t)(v_curr_row.ptr[2u])) + ((uint32_t)(v_prev_row.ptr[10u]))) / 2u); v_l3 = ((((uint32_t)(v_curr_row.ptr[3u])) + ((uint32_t)(v_prev_row.ptr[11u]))) / 2u); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((v_l0 + ((uint32_t)(v_prev_row.ptr[4u]))) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((v_l1 + ((uint32_t)(v_prev_row.ptr[5u]))) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((v_l2 + ((uint32_t)(v_prev_row.ptr[6u]))) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((v_l3 + ((uint32_t)(v_prev_row.ptr[7u]))) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 6u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[0u])) + ((uint32_t)(v_prev_row.ptr[0u]))) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[1u])) + ((uint32_t)(v_prev_row.ptr[1u]))) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[2u])) + ((uint32_t)(v_prev_row.ptr[2u]))) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[3u])) + ((uint32_t)(v_prev_row.ptr[3u]))) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 7u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[0u])) + ((uint32_t)(v_prev_row.ptr[4u]))) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[1u])) + ((uint32_t)(v_prev_row.ptr[5u]))) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[2u])) + ((uint32_t)(v_prev_row.ptr[6u]))) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((((uint32_t)(v_curr_row.ptr[3u])) + ((uint32_t)(v_prev_row.ptr[7u]))) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 8u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[0u])) + ((uint32_t)(v_prev_row.ptr[4u]))) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[1u])) + ((uint32_t)(v_prev_row.ptr[5u]))) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[2u])) + ((uint32_t)(v_prev_row.ptr[6u]))) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[3u])) + ((uint32_t)(v_prev_row.ptr[7u]))) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 9u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[4u])) + ((uint32_t)(v_prev_row.ptr[8u]))) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[5u])) + ((uint32_t)(v_prev_row.ptr[9u]))) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[6u])) + ((uint32_t)(v_prev_row.ptr[10u]))) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((((uint32_t)(v_prev_row.ptr[7u])) + ((uint32_t)(v_prev_row.ptr[11u]))) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 10u) { v_l0 = ((((uint32_t)(v_curr_row.ptr[0u])) + ((uint32_t)(v_prev_row.ptr[0u]))) / 2u); v_l1 = ((((uint32_t)(v_curr_row.ptr[1u])) + ((uint32_t)(v_prev_row.ptr[1u]))) / 2u); v_l2 = ((((uint32_t)(v_curr_row.ptr[2u])) + ((uint32_t)(v_prev_row.ptr[2u]))) / 2u); v_l3 = ((((uint32_t)(v_curr_row.ptr[3u])) + ((uint32_t)(v_prev_row.ptr[3u]))) / 2u); v_t0 = ((((uint32_t)(v_prev_row.ptr[4u])) + ((uint32_t)(v_prev_row.ptr[8u]))) / 2u); v_t1 = ((((uint32_t)(v_prev_row.ptr[5u])) + ((uint32_t)(v_prev_row.ptr[9u]))) / 2u); v_t2 = ((((uint32_t)(v_prev_row.ptr[6u])) + ((uint32_t)(v_prev_row.ptr[10u]))) / 2u); v_t3 = ((((uint32_t)(v_prev_row.ptr[7u])) + ((uint32_t)(v_prev_row.ptr[11u]))) / 2u); #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(((v_l0 + v_t0) / 2u))); v_curr_row.ptr[5u] += ((uint8_t)(((v_l1 + v_t1) / 2u))); v_curr_row.ptr[6u] += ((uint8_t)(((v_l2 + v_t2) / 2u))); v_curr_row.ptr[7u] += ((uint8_t)(((v_l3 + v_t3) / 2u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 11u) { v_l0 = ((uint32_t)(v_curr_row.ptr[0u])); v_l1 = ((uint32_t)(v_curr_row.ptr[1u])); v_l2 = ((uint32_t)(v_curr_row.ptr[2u])); v_l3 = ((uint32_t)(v_curr_row.ptr[3u])); v_c0 = ((uint32_t)(v_prev_row.ptr[0u])); v_c1 = ((uint32_t)(v_prev_row.ptr[1u])); v_c2 = ((uint32_t)(v_prev_row.ptr[2u])); v_c3 = ((uint32_t)(v_prev_row.ptr[3u])); v_t0 = ((uint32_t)(v_prev_row.ptr[4u])); v_t1 = ((uint32_t)(v_prev_row.ptr[5u])); v_t2 = ((uint32_t)(v_prev_row.ptr[6u])); v_t3 = ((uint32_t)(v_prev_row.ptr[7u])); v_sum_l = (wuffs_webp__decoder__absolute_difference(self, v_c0, v_t0) + wuffs_webp__decoder__absolute_difference(self, v_c1, v_t1) + wuffs_webp__decoder__absolute_difference(self, v_c2, v_t2) + wuffs_webp__decoder__absolute_difference(self, v_c3, v_t3)); v_sum_t = (wuffs_webp__decoder__absolute_difference(self, v_c0, v_l0) + wuffs_webp__decoder__absolute_difference(self, v_c1, v_l1) + wuffs_webp__decoder__absolute_difference(self, v_c2, v_l2) + wuffs_webp__decoder__absolute_difference(self, v_c3, v_l3)); if (v_sum_l < v_sum_t) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(v_l0)); v_curr_row.ptr[5u] += ((uint8_t)(v_l1)); v_curr_row.ptr[6u] += ((uint8_t)(v_l2)); v_curr_row.ptr[7u] += ((uint8_t)(v_l3)); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += ((uint8_t)(v_t0)); v_curr_row.ptr[5u] += ((uint8_t)(v_t1)); v_curr_row.ptr[6u] += ((uint8_t)(v_t2)); v_curr_row.ptr[7u] += ((uint8_t)(v_t3)); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } } else if (v_mode == 12u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += wuffs_webp__decoder__mode12(self, v_curr_row.ptr[0u], v_prev_row.ptr[4u], v_prev_row.ptr[0u]); v_curr_row.ptr[5u] += wuffs_webp__decoder__mode12(self, v_curr_row.ptr[1u], v_prev_row.ptr[5u], v_prev_row.ptr[1u]); v_curr_row.ptr[6u] += wuffs_webp__decoder__mode12(self, v_curr_row.ptr[2u], v_prev_row.ptr[6u], v_prev_row.ptr[2u]); v_curr_row.ptr[7u] += wuffs_webp__decoder__mode12(self, v_curr_row.ptr[3u], v_prev_row.ptr[7u], v_prev_row.ptr[3u]); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } else if (v_mode == 13u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_curr_row.ptr[4u] += wuffs_webp__decoder__mode13(self, v_curr_row.ptr[0u], v_prev_row.ptr[4u], v_prev_row.ptr[0u]); v_curr_row.ptr[5u] += wuffs_webp__decoder__mode13(self, v_curr_row.ptr[1u], v_prev_row.ptr[5u], v_prev_row.ptr[1u]); v_curr_row.ptr[6u] += wuffs_webp__decoder__mode13(self, v_curr_row.ptr[2u], v_prev_row.ptr[6u], v_prev_row.ptr[2u]); v_curr_row.ptr[7u] += wuffs_webp__decoder__mode13(self, v_curr_row.ptr[3u], v_prev_row.ptr[7u], v_prev_row.ptr[3u]); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } v_curr_row = wuffs_base__slice_u8__subslice_i(v_curr_row, 4u); v_prev_row = wuffs_base__slice_u8__subslice_i(v_prev_row, 4u); v_x += 1u; } v_y += 1u; } return wuffs_base__make_empty_struct(); } // -------- func webp.decoder.absolute_difference WUFFS_BASE__GENERATED_C_CODE static uint32_t wuffs_webp__decoder__absolute_difference( const wuffs_webp__decoder* self, uint32_t a_a, uint32_t a_b) { if (a_a < a_b) { return (a_b - a_a); } return (a_a - a_b); } // -------- func webp.decoder.mode12 WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_webp__decoder__mode12( const wuffs_webp__decoder* self, uint8_t a_l, uint8_t a_t, uint8_t a_tl) { uint32_t v_v = 0; v_v = ((uint32_t)((((uint32_t)(a_l)) + ((uint32_t)(a_t))) - ((uint32_t)(a_tl)))); if (v_v < 256u) { return ((uint8_t)(v_v)); } else if (v_v < 512u) { return 255u; } return 0u; } // -------- func webp.decoder.mode13 WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_webp__decoder__mode13( const wuffs_webp__decoder* self, uint8_t a_l, uint8_t a_t, uint8_t a_tl) { uint32_t v_x = 0; uint32_t v_y = 0; uint32_t v_z = 0; uint32_t v_v = 0; v_x = ((((uint32_t)(a_l)) + ((uint32_t)(a_t))) / 2u); v_y = ((uint32_t)(a_tl)); v_z = ((uint32_t)(v_x - v_y)); v_v = ((uint32_t)(v_x + wuffs_base__utility__sign_extend_rshift_u32(((uint32_t)(v_z + (v_z >> 31u))), 1u))); if (v_v < 256u) { return ((uint8_t)(v_v)); } else if (v_v < 512u) { return 255u; } return 0u; } // -------- func webp.decoder.apply_transform_cross_color WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_cross_color( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix, wuffs_base__slice_u8 a_tile_data) { uint32_t v_tile_size_log2 = 0; uint32_t v_tiles_per_row = 0; uint32_t v_mask = 0; uint32_t v_y = 0; uint32_t v_x = 0; uint64_t v_t = 0; wuffs_base__slice_u8 v_tile_data = {0}; uint32_t v_g2r = 0; uint32_t v_g2b = 0; uint32_t v_r2b = 0; uint8_t v_b = 0; uint8_t v_g = 0; uint8_t v_r = 0; v_tile_size_log2 = ((uint32_t)(self->private_impl.f_transform_tile_size_log2[1u])); v_tiles_per_row = ((self->private_impl.f_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2); v_mask = ((((uint32_t)(1u)) << v_tile_size_log2) - 1u); v_y = 0u; while (v_y < self->private_impl.f_height) { v_t = ((uint64_t)((4u * (v_y >> v_tile_size_log2) * v_tiles_per_row))); v_tile_data = wuffs_base__utility__empty_slice_u8(); if (v_t <= ((uint64_t)(a_tile_data.len))) { v_tile_data = wuffs_base__slice_u8__subslice_i(a_tile_data, v_t); } v_x = 0u; while (v_x < self->private_impl.f_width) { if (((v_x & v_mask) == 0u) && (((uint64_t)(v_tile_data.len)) >= 4u)) { v_g2r = wuffs_base__utility__sign_extend_convert_u8_u32(v_tile_data.ptr[0u]); v_g2b = wuffs_base__utility__sign_extend_convert_u8_u32(v_tile_data.ptr[1u]); v_r2b = wuffs_base__utility__sign_extend_convert_u8_u32(v_tile_data.ptr[2u]); v_tile_data = wuffs_base__slice_u8__subslice_i(v_tile_data, 4u); } if (((uint64_t)(a_pix.len)) >= 4u) { v_b = a_pix.ptr[0u]; v_g = a_pix.ptr[1u]; v_r = a_pix.ptr[2u]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_r += ((uint8_t)((((uint32_t)(wuffs_base__utility__sign_extend_convert_u8_u32(v_g) * v_g2r)) >> 5u))); v_b += ((uint8_t)((((uint32_t)(wuffs_base__utility__sign_extend_convert_u8_u32(v_g) * v_g2b)) >> 5u))); v_b += ((uint8_t)((((uint32_t)(wuffs_base__utility__sign_extend_convert_u8_u32(v_r) * v_r2b)) >> 5u))); #if defined(__GNUC__) #pragma GCC diagnostic pop #endif a_pix.ptr[0u] = v_b; a_pix.ptr[2u] = v_r; a_pix = wuffs_base__slice_u8__subslice_i(a_pix, 4u); } v_x += 1u; } v_y += 1u; } return wuffs_base__make_empty_struct(); } // -------- func webp.decoder.apply_transform_subtract_green WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_subtract_green( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix) { wuffs_base__slice_u8 v_p = {0}; uint8_t v_g = 0; { wuffs_base__slice_u8 i_slice_p = a_pix; v_p.ptr = i_slice_p.ptr; v_p.len = 4; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 4) * 4)); while (v_p.ptr < i_end0_p) { v_g = v_p.ptr[1u]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_p.ptr[0u] += v_g; v_p.ptr[2u] += v_g; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_p.ptr += 4; } v_p.len = 0; } return wuffs_base__make_empty_struct(); } // -------- func webp.decoder.apply_transform_color_indexing WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_webp__decoder__apply_transform_color_indexing( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_pix) { uint32_t v_tile_size_log2 = 0; uint32_t v_bits_per_pixel = 0; uint32_t v_x_mask = 0; uint32_t v_s_mask = 0; uint64_t v_src_index = 0; uint32_t v_y = 0; uint64_t v_di = 0; uint64_t v_dj = 0; wuffs_base__slice_u8 v_dst = {0}; uint32_t v_x = 0; uint32_t v_s = 0; uint32_t v_p = 0; uint8_t v_p0 = 0; uint8_t v_p1 = 0; uint8_t v_p2 = 0; uint8_t v_p3 = 0; v_tile_size_log2 = ((uint32_t)(self->private_impl.f_transform_tile_size_log2[3u])); if (v_tile_size_log2 == 0u) { { wuffs_base__slice_u8 i_slice_dst = a_pix; v_dst.ptr = i_slice_dst.ptr; v_dst.len = 4; const uint8_t* i_end0_dst = wuffs_private_impl__ptr_u8_plus_len(v_dst.ptr, (((i_slice_dst.len - (size_t)(v_dst.ptr - i_slice_dst.ptr)) / 4) * 4)); while (v_dst.ptr < i_end0_dst) { v_p = (((uint32_t)(v_dst.ptr[1u])) * 4u); v_p0 = self->private_data.f_palette[(v_p + 0u)]; v_p1 = self->private_data.f_palette[(v_p + 1u)]; v_p2 = self->private_data.f_palette[(v_p + 2u)]; v_p3 = self->private_data.f_palette[(v_p + 3u)]; v_dst.ptr[0u] = v_p0; v_dst.ptr[1u] = v_p1; v_dst.ptr[2u] = v_p2; v_dst.ptr[3u] = v_p3; v_dst.ptr += 4; } v_dst.len = 0; } return wuffs_base__make_empty_struct(); } v_bits_per_pixel = (((uint32_t)(8u)) >> v_tile_size_log2); v_x_mask = ((((uint32_t)(1u)) << v_tile_size_log2) - 1u); v_s_mask = ((((uint32_t)(1u)) << v_bits_per_pixel) - 1u); v_src_index = ((uint64_t)((self->private_impl.f_workbuf_offset_for_color_indexing + 1u))); v_y = 0u; while (v_y < self->private_impl.f_height) { v_di = ((uint64_t)((4u * (v_y + 0u) * self->private_impl.f_width))); v_dj = ((uint64_t)((4u * (v_y + 1u) * self->private_impl.f_width))); if ((v_di > v_dj) || (v_dj > ((uint64_t)(a_pix.len)))) { break; } v_dst = wuffs_base__slice_u8__subslice_ij(a_pix, v_di, v_dj); v_x = 0u; while (((uint64_t)(v_dst.len)) >= 4u) { if (((v_x & v_x_mask) == 0u) && (v_src_index < ((uint64_t)(a_pix.len)))) { v_s = ((uint32_t)(a_pix.ptr[v_src_index])); v_src_index += 4u; } v_p = ((v_s & v_s_mask) * 4u); v_s >>= v_bits_per_pixel; v_p0 = self->private_data.f_palette[(v_p + 0u)]; v_p1 = self->private_data.f_palette[(v_p + 1u)]; v_p2 = self->private_data.f_palette[(v_p + 2u)]; v_p3 = self->private_data.f_palette[(v_p + 3u)]; v_dst.ptr[0u] = v_p0; v_dst.ptr[1u] = v_p1; v_dst.ptr[2u] = v_p2; v_dst.ptr[3u] = v_p3; v_dst = wuffs_base__slice_u8__subslice_i(v_dst, 4u); v_x += 1u; } v_y += 1u; } return wuffs_base__make_empty_struct(); } // -------- func webp.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__get_quirk( const wuffs_webp__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func webp.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__set_quirk( wuffs_webp__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func webp.decoder.decode_image_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_image_config( wuffs_webp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_webp__decoder__do_decode_image_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_webp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func webp.decoder.do_decode_image_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config( wuffs_webp__decoder* self, wuffs_base__image_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; uint64_t v_r_mark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence != 0u) { status = wuffs_base__make_status(wuffs_base__error__bad_call_sequence); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c32 = t_0; } if (v_c32 != 1179011410u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } self->private_impl.f_riff_chunk_length = t_1; } if ((self->private_impl.f_riff_chunk_length & 1u) != 0u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } while (true) { { const bool o_0_closed_a_src = a_src->meta.closed; const uint8_t* o_0_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_riff_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_webp__decoder__do_decode_image_config_limited(self, a_src); v_status = t_2; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_riff_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); io2_a_src = o_0_io2_a_src; if (a_src) { a_src->meta.closed = o_0_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } if (wuffs_base__status__is_ok(&v_status)) { break; } else if ( ! wuffs_base__status__is_suspension(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } else if ((v_status.repr == wuffs_base__suspension__short_read) && (self->private_impl.f_riff_chunk_length == 0u)) { status = wuffs_base__make_status(wuffs_webp__error__short_chunk); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } self->private_impl.f_frame_config_io_position = wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src))); if (a_dst != NULL) { wuffs_base__image_config__set( a_dst, self->private_impl.f_pixfmt, 0u, self->private_impl.f_width, self->private_impl.f_height, self->private_impl.f_frame_config_io_position, false); } self->private_impl.f_call_sequence = 32u; ok: self->private_impl.p_do_decode_image_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.do_decode_image_config_limited WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config_limited( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; uint64_t v_r_mark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config_limited; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config_limited.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config_limited.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c32 = t_0; } if (v_c32 != 1346520407u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config_limited.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config_limited.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_c32 = t_1; } if (v_c32 == 540561494u) { status = wuffs_base__make_status(wuffs_webp__error__unsupported_webp_file); goto exit; } else if (v_c32 == 1278758998u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); uint32_t t_2; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_2 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config_limited.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config_limited.scratch; uint32_t num_bits_2 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_2; if (num_bits_2 == 24) { t_2 = ((uint32_t)(*scratch)); break; } num_bits_2 += 8u; *scratch |= ((uint64_t)(num_bits_2)) << 56; } } self->private_impl.f_sub_chunk_length = t_2; } if (self->private_impl.f_sub_chunk_length < 4u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } self->private_impl.f_sub_chunk_has_padding = ((self->private_impl.f_sub_chunk_length & 1u) != 0u); while (true) { { const bool o_0_closed_a_src = a_src->meta.closed; const uint8_t* o_0_io2_a_src = io2_a_src; wuffs_private_impl__io_reader__limit(&io2_a_src, iop_a_src, ((uint64_t)(self->private_impl.f_sub_chunk_length))); if (a_src) { size_t n = ((size_t)(io2_a_src - a_src->data.ptr)); a_src->meta.closed = a_src->meta.closed && (a_src->meta.wi <= n); a_src->meta.wi = n; } v_r_mark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_3 = wuffs_webp__decoder__do_decode_image_config_limited_vp8l(self, a_src); v_status = t_3; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u32__sat_sub_indirect(&self->private_impl.f_sub_chunk_length, ((uint32_t)(wuffs_private_impl__io__count_since(v_r_mark, ((uint64_t)(iop_a_src - io0_a_src)))))); io2_a_src = o_0_io2_a_src; if (a_src) { a_src->meta.closed = o_0_closed_a_src; a_src->meta.wi = ((size_t)(io2_a_src - a_src->data.ptr)); } } if (wuffs_base__status__is_ok(&v_status)) { break; } else if ( ! wuffs_base__status__is_suspension(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } else if ((v_status.repr == wuffs_base__suspension__short_read) && (self->private_impl.f_sub_chunk_length == 0u)) { status = wuffs_base__make_status(wuffs_webp__error__short_chunk); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); } } else if (v_c32 == 1480085590u) { status = wuffs_base__make_status(wuffs_webp__error__unsupported_webp_file); goto exit; } else { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } ok: self->private_impl.p_do_decode_image_config_limited = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config_limited = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.do_decode_image_config_limited_vp8l WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_image_config_limited_vp8l( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; uint32_t v_transform_size = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_image_config_limited_vp8l; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint32_t t_0 = *iop_a_src++; v_c32 = t_0; } if (v_c32 != 47u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_1 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_decode_image_config_limited_vp8l.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_decode_image_config_limited_vp8l.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 24) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_c32 = t_1; } self->private_impl.f_width = ((v_c32 & 16383u) + 1u); v_c32 >>= 14u; self->private_impl.f_height = ((v_c32 & 16383u) + 1u); v_c32 >>= 14u; self->private_impl.f_pixfmt = 2415954056u; if ((v_c32 & 1u) != 0u) { self->private_impl.f_pixfmt = 2164295816u; } v_c32 >>= 1u; if (v_c32 != 0u) { status = wuffs_base__make_status(wuffs_webp__error__bad_header); goto exit; } v_transform_size = (4u * ((self->private_impl.f_width + 3u) >> 2u) * ((self->private_impl.f_height + 3u) >> 2u)); self->private_impl.f_workbuf_offset_for_transform[0u] = ((4u * self->private_impl.f_width * self->private_impl.f_height) + (0u * v_transform_size)); self->private_impl.f_workbuf_offset_for_transform[1u] = ((4u * self->private_impl.f_width * self->private_impl.f_height) + (1u * v_transform_size)); self->private_impl.f_workbuf_offset_for_transform[2u] = ((4u * self->private_impl.f_width * self->private_impl.f_height) + (2u * v_transform_size)); self->private_impl.f_workbuf_offset_for_transform[3u] = ((4u * self->private_impl.f_width * self->private_impl.f_height) + (3u * v_transform_size)); goto ok; ok: self->private_impl.p_do_decode_image_config_limited_vp8l = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_image_config_limited_vp8l = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_frame_config WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_frame_config( wuffs_webp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 2)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_webp__decoder__do_decode_frame_config(self, a_dst, a_src); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_webp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 2 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func webp.decoder.do_decode_frame_config WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_frame_config( wuffs_webp__decoder* self, wuffs_base__frame_config* a_dst, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame_config; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 32u) { } else if (self->private_impl.f_call_sequence < 32u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_webp__decoder__do_decode_image_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else if (self->private_impl.f_call_sequence == 40u) { if (self->private_impl.f_frame_config_io_position != wuffs_base__u64__sat_add((a_src ? a_src->meta.pos : 0), ((uint64_t)(iop_a_src - io0_a_src)))) { status = wuffs_base__make_status(wuffs_base__error__bad_restart); goto exit; } } else if (self->private_impl.f_call_sequence == 64u) { self->private_impl.f_call_sequence = 96u; status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } if (a_dst != NULL) { wuffs_base__frame_config__set( a_dst, wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height), ((wuffs_base__flicks)(0u)), 0u, self->private_impl.f_frame_config_io_position, 0u, false, false, 0u); } self->private_impl.f_call_sequence = 64u; ok: self->private_impl.p_do_decode_frame_config = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame_config = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__decode_frame( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 3)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_decode_frame; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_webp__decoder__do_decode_frame(self, a_dst, a_src, a_blend, a_workbuf, a_opts); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_webp__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 3 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func webp.decoder.do_decode_frame WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__do_decode_frame( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__pixel_blend a_blend, wuffs_base__slice_u8 a_workbuf, wuffs_base__decode_frame_options* a_opts) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_has_more = 0; uint32_t v_width = 0; wuffs_base__slice_u8 v_dst = {0}; wuffs_base__slice_u8 v_tile_data = {0}; wuffs_base__status v_status = wuffs_base__make_status(NULL); wuffs_base__slice_u8 v_pix = {0}; uint32_t v_which = 0; uint32_t v_transform_type = 0; uint64_t v_ti = 0; uint64_t v_tj = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_decode_frame; if (coro_susp_point) { v_width = self->private_data.s_do_decode_frame.v_width; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_call_sequence == 64u) { } else if (self->private_impl.f_call_sequence < 64u) { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_webp__decoder__do_decode_frame_config(self, NULL, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } else { status = wuffs_base__make_status(wuffs_base__note__end_of_data); goto ok; } self->private_impl.f_seen_transform[0u] = false; self->private_impl.f_seen_transform[1u] = false; self->private_impl.f_seen_transform[2u] = false; self->private_impl.f_seen_transform[3u] = false; self->private_impl.f_n_transforms = 0u; while (true) { if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_has_more = (self->private_impl.f_bits & 1u); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; if (v_has_more == 0u) { break; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_webp__decoder__decode_transform(self, a_src, a_workbuf); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } } v_width = self->private_impl.f_width; if (self->private_impl.f_seen_transform[3u]) { v_width = self->private_impl.f_color_indexing_width; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_webp__decoder__decode_color_cache_parameters(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_overall_color_cache_bits = self->private_impl.f_color_cache_bits; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); status = wuffs_webp__decoder__decode_hg_table(self, a_src, v_width, a_workbuf); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } self->private_impl.f_color_cache_bits = self->private_impl.f_overall_color_cache_bits; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); status = wuffs_webp__decoder__decode_huffman_groups(self, a_src, self->private_impl.f_overall_n_huffman_groups); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } while (true) { if ((((uint64_t)(self->private_impl.f_workbuf_offset_for_color_indexing)) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u])) > ((uint64_t)(a_workbuf.len))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } v_dst = wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_color_indexing)), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u]))); v_tile_data = wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_1 = wuffs_webp__decoder__decode_pixels(self, v_dst, a_src, v_width, self->private_impl.f_height, v_tile_data, self->private_impl.f_overall_tile_size_log2); v_status = t_1; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(7); } if (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(a_workbuf.len))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } v_pix = wuffs_base__slice_u8__subslice_j(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u]))); v_which = self->private_impl.f_n_transforms; while (v_which > 0u) { v_which -= 1u; v_transform_type = ((uint32_t)(self->private_impl.f_transform_type[v_which])); v_tile_data = wuffs_base__utility__empty_slice_u8(); if (v_transform_type < 2u) { v_ti = ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 1u)])); v_tj = ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 2u)])); if ((v_ti <= v_tj) && (v_tj <= ((uint64_t)(a_workbuf.len)))) { v_tile_data = wuffs_base__slice_u8__subslice_ij(a_workbuf, v_ti, v_tj); } } if (v_transform_type == 0u) { wuffs_webp__decoder__apply_transform_predictor(self, v_pix, v_tile_data); } else if (v_transform_type == 1u) { wuffs_webp__decoder__apply_transform_cross_color(self, v_pix, v_tile_data); } else if (v_transform_type == 2u) { wuffs_webp__decoder__apply_transform_subtract_green(self, v_pix); } else { wuffs_webp__decoder__apply_transform_color_indexing(self, v_pix); v_width = self->private_impl.f_width; } } v_status = wuffs_webp__decoder__swizzle(self, a_dst, v_pix, a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { status = v_status; if (wuffs_base__status__is_error(&status)) { goto exit; } else if (wuffs_base__status__is_suspension(&status)) { status = wuffs_base__make_status(wuffs_base__error__cannot_return_a_suspension); goto exit; } goto ok; } self->private_impl.f_call_sequence = 96u; ok: self->private_impl.p_do_decode_frame = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_decode_frame = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_decode_frame.v_width = v_width; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_transform WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_transform( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_transform_type = 0; uint32_t v_tile_size_log2 = 0; wuffs_base__slice_u8 v_p = {0}; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_transform; if (coro_susp_point) { v_transform_type = self->private_data.s_decode_transform.v_transform_type; v_tile_size_log2 = self->private_data.s_decode_transform.v_tile_size_log2; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 2u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (self->private_impl.f_n_bits >= 2u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_transform_type = (self->private_impl.f_bits & 3u); self->private_impl.f_bits >>= 2u; self->private_impl.f_n_bits -= 2u; if (self->private_impl.f_seen_transform[v_transform_type] || (self->private_impl.f_n_transforms >= 4u)) { status = wuffs_base__make_status(wuffs_webp__error__bad_transform); goto exit; } else if (self->private_impl.f_seen_transform[3u]) { status = wuffs_base__make_status(wuffs_webp__error__unsupported_transform_after_color_indexing_transform); goto exit; } self->private_impl.f_seen_transform[v_transform_type] = true; self->private_impl.f_transform_type[self->private_impl.f_n_transforms] = ((uint8_t)(v_transform_type)); self->private_impl.f_n_transforms += 1u; if (v_transform_type < 2u) { if (self->private_impl.f_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= 3u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_tile_size_log2 = ((self->private_impl.f_bits & 7u) + 2u); self->private_impl.f_transform_tile_size_log2[v_transform_type] = ((uint8_t)(v_tile_size_log2)); self->private_impl.f_bits >>= 3u; self->private_impl.f_n_bits -= 3u; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_webp__decoder__decode_color_cache_parameters(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_webp__decoder__decode_huffman_groups(self, a_src, 1u); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } while (true) { if ((((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 1u)])) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 2u)]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 2u)])) > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_webp__decoder__decode_pixels(self, wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 1u)])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[(v_transform_type + 2u)]))), a_src, ((self->private_impl.f_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2), ((self->private_impl.f_height + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2), wuffs_base__utility__empty_slice_u8(), 0u); v_status = t_2; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } } else if (v_transform_type == 2u) { } else { if (self->private_impl.f_n_bits < 8u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (self->private_impl.f_n_bits >= 8u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } self->private_impl.f_color_indexing_palette_size = ((self->private_impl.f_bits & 255u) + 1u); self->private_impl.f_bits >>= 8u; self->private_impl.f_n_bits -= 8u; if (self->private_impl.f_color_indexing_palette_size <= 2u) { self->private_impl.f_color_indexing_width = ((self->private_impl.f_width + 7u) / 8u); self->private_impl.f_transform_tile_size_log2[3u] = 3u; } else if (self->private_impl.f_color_indexing_palette_size <= 4u) { self->private_impl.f_color_indexing_width = ((self->private_impl.f_width + 3u) / 4u); self->private_impl.f_transform_tile_size_log2[3u] = 2u; } else if (self->private_impl.f_color_indexing_palette_size <= 16u) { self->private_impl.f_color_indexing_width = ((self->private_impl.f_width + 1u) / 2u); self->private_impl.f_transform_tile_size_log2[3u] = 1u; } else { self->private_impl.f_color_indexing_width = self->private_impl.f_width; self->private_impl.f_transform_tile_size_log2[3u] = 0u; } if (self->private_impl.f_width >= self->private_impl.f_color_indexing_width) { self->private_impl.f_workbuf_offset_for_color_indexing = (4u * (self->private_impl.f_width - self->private_impl.f_color_indexing_width) * self->private_impl.f_height); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); status = wuffs_webp__decoder__decode_color_cache_parameters(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); status = wuffs_webp__decoder__decode_huffman_groups(self, a_src, 1u); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); status = wuffs_webp__decoder__decode_pixels(self, wuffs_base__make_slice_u8(self->private_data.f_palette, (4u * self->private_impl.f_color_indexing_palette_size)), a_src, self->private_impl.f_color_indexing_palette_size, 1u, wuffs_base__utility__empty_slice_u8(), 0u); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } wuffs_private_impl__bulk_memset(&self->private_data.f_palette[(4u * self->private_impl.f_color_indexing_palette_size)], (1024u - (4u * self->private_impl.f_color_indexing_palette_size)), 0u); v_p = wuffs_base__make_slice_u8(self->private_data.f_palette, (4u * self->private_impl.f_color_indexing_palette_size)); while (((uint64_t)(v_p.len)) >= 8u) { #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_p.ptr[4u] += v_p.ptr[0u]; v_p.ptr[5u] += v_p.ptr[1u]; v_p.ptr[6u] += v_p.ptr[2u]; v_p.ptr[7u] += v_p.ptr[3u]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif v_p = wuffs_base__slice_u8__subslice_i(v_p, 4u); } } ok: self->private_impl.p_decode_transform = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_transform = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_transform.v_transform_type = v_transform_type; self->private_data.s_decode_transform.v_tile_size_log2 = v_tile_size_log2; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_color_cache_parameters WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_color_cache_parameters( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_use_color_cache = 0; uint32_t v_color_cache_bits = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_color_cache_parameters; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_use_color_cache = (self->private_impl.f_bits & 1u); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; self->private_impl.f_color_cache_bits = 0u; if (v_use_color_cache != 0u) { if (self->private_impl.f_n_bits < 4u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= 4u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_color_cache_bits = (self->private_impl.f_bits & 15u); self->private_impl.f_bits >>= 4u; self->private_impl.f_n_bits -= 4u; if ((v_color_cache_bits < 1u) || (11u < v_color_cache_bits)) { status = wuffs_base__make_status(wuffs_webp__error__bad_color_cache); goto exit; } self->private_impl.f_color_cache_bits = v_color_cache_bits; } goto ok; ok: self->private_impl.p_decode_color_cache_parameters = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_color_cache_parameters = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_hg_table WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_hg_table( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_src, uint32_t a_width, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_use_hg_table = 0; uint32_t v_tile_size_log2 = 0; wuffs_base__slice_u8 v_hg_pixels = {0}; uint64_t v_n = 0; wuffs_base__slice_u8 v_p = {0}; uint32_t v_hg_plus_1 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_hg_table; if (coro_susp_point) { v_tile_size_log2 = self->private_data.s_decode_hg_table.v_tile_size_log2; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if (self->private_impl.f_n_bits < 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } self->private_impl.f_bits = ((uint32_t)(v_c8)); self->private_impl.f_n_bits = 8u; } v_use_hg_table = (self->private_impl.f_bits & 1u); self->private_impl.f_bits >>= 1u; self->private_impl.f_n_bits -= 1u; if (v_use_hg_table == 0u) { self->private_impl.f_overall_n_huffman_groups = 1u; self->private_impl.f_overall_tile_size_log2 = 0u; if ((((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u])) > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } v_hg_pixels = wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))); if (((uint64_t)(v_hg_pixels.len)) >= 4u) { v_hg_pixels.ptr[0u] = 0u; v_hg_pixels.ptr[1u] = 0u; v_hg_pixels.ptr[2u] = 0u; v_hg_pixels.ptr[3u] = 0u; } status = wuffs_base__make_status(NULL); goto ok; } if (self->private_impl.f_n_bits < 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (self->private_impl.f_n_bits >= 3u) { status = wuffs_base__make_status(wuffs_webp__error__internal_error_inconsistent_n_bits); goto exit; } self->private_impl.f_bits |= (((uint32_t)(v_c8)) << self->private_impl.f_n_bits); self->private_impl.f_n_bits += 8u; } v_tile_size_log2 = ((self->private_impl.f_bits & 7u) + 2u); self->private_impl.f_bits >>= 3u; self->private_impl.f_n_bits -= 3u; self->private_impl.f_overall_tile_size_log2 = v_tile_size_log2; if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); status = wuffs_webp__decoder__decode_color_cache_parameters(self, a_src); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); status = wuffs_webp__decoder__decode_huffman_groups(self, a_src, 1u); if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } if (status.repr) { goto suspend; } while (true) { if ((((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u])) > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_webp__decoder__decode_pixels(self, wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))), a_src, ((a_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2), ((self->private_impl.f_height + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2), wuffs_base__utility__empty_slice_u8(), 0u); v_status = t_2; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); } self->private_impl.f_overall_n_huffman_groups = 1u; if ((((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])) > ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))) || (((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u])) > ((uint64_t)(a_workbuf.len)))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } v_hg_pixels = wuffs_base__slice_u8__subslice_ij(a_workbuf, ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[0u])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[1u]))); v_n = ((uint64_t)((((a_width + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2) * ((self->private_impl.f_height + ((((uint32_t)(1u)) << v_tile_size_log2) - 1u)) >> v_tile_size_log2) * 4u))); if (v_n > ((uint64_t)(v_hg_pixels.len))) { status = wuffs_base__make_status(wuffs_base__error__bad_workbuf_length); goto exit; } v_p = wuffs_base__slice_u8__subslice_j(v_hg_pixels, v_n); while (((uint64_t)(v_p.len)) >= 4u) { if (v_p.ptr[2u] != 0u) { status = wuffs_base__make_status(wuffs_webp__error__unsupported_number_of_huffman_groups); goto exit; } v_hg_plus_1 = (((uint32_t)(v_p.ptr[1u])) + 1u); if (self->private_impl.f_overall_n_huffman_groups < v_hg_plus_1) { self->private_impl.f_overall_n_huffman_groups = v_hg_plus_1; } v_p = wuffs_base__slice_u8__subslice_i(v_p, 4u); } ok: self->private_impl.p_decode_hg_table = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_hg_table = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_hg_table.v_tile_size_log2 = v_tile_size_log2; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func webp.decoder.decode_pixels WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__decode_pixels( wuffs_webp__decoder* self, wuffs_base__slice_u8 a_dst, wuffs_base__io_buffer* a_src, uint32_t a_width, uint32_t a_height, wuffs_base__slice_u8 a_tile_data, uint32_t a_tile_size_log2) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_i = 0; uint32_t v_n = 0; uint32_t coro_susp_point = self->private_impl.p_decode_pixels; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; v_i = 0u; v_n = (((uint32_t)(1u)) << self->private_impl.f_color_cache_bits); while (v_i < v_n) { self->private_data.f_color_cache[v_i] = 0u; v_i += 1u; } WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); status = wuffs_webp__decoder__decode_pixels_slow(self, a_dst, a_src, a_width, a_height, a_tile_data, a_tile_size_log2); if (status.repr) { goto suspend; } goto ok; ok: self->private_impl.p_decode_pixels = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_pixels = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: return status; } // -------- func webp.decoder.swizzle WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_webp__decoder__swizzle( wuffs_webp__decoder* self, wuffs_base__pixel_buffer* a_dst, wuffs_base__slice_u8 a_src, wuffs_base__pixel_blend a_blend) { wuffs_base__status v_status = wuffs_base__make_status(NULL); wuffs_base__pixel_format v_dst_pixfmt = {0}; uint32_t v_dst_bits_per_pixel = 0; uint32_t v_dst_bytes_per_pixel = 0; uint64_t v_dst_bytes_per_row = 0; wuffs_base__slice_u8 v_dst_palette = {0}; wuffs_base__table_u8 v_tab = {0}; uint64_t v_src_bytes_per_row = 0; wuffs_base__slice_u8 v_dst = {0}; uint32_t v_y = 0; v_status = wuffs_base__pixel_swizzler__prepare(&self->private_impl.f_swizzler, wuffs_base__pixel_buffer__pixel_format(a_dst), wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_palette, 1024)), wuffs_base__utility__make_pixel_format(self->private_impl.f_pixfmt), wuffs_base__utility__empty_slice_u8(), a_blend); if ( ! wuffs_base__status__is_ok(&v_status)) { return wuffs_private_impl__status__ensure_not_a_suspension(v_status); } v_dst_pixfmt = wuffs_base__pixel_buffer__pixel_format(a_dst); v_dst_bits_per_pixel = wuffs_base__pixel_format__bits_per_pixel(&v_dst_pixfmt); if ((v_dst_bits_per_pixel & 7u) != 0u) { return wuffs_base__make_status(wuffs_base__error__unsupported_option); } v_dst_bytes_per_pixel = (v_dst_bits_per_pixel / 8u); v_dst_bytes_per_row = ((uint64_t)((self->private_impl.f_width * v_dst_bytes_per_pixel))); v_dst_palette = wuffs_base__pixel_buffer__palette_or_else(a_dst, wuffs_base__make_slice_u8(self->private_data.f_palette, 1024)); v_tab = wuffs_base__pixel_buffer__plane(a_dst, 0u); v_src_bytes_per_row = ((uint64_t)((self->private_impl.f_width * 4u))); while (v_src_bytes_per_row <= ((uint64_t)(a_src.len))) { v_dst = wuffs_private_impl__table_u8__row_u32(v_tab, v_y); if (v_dst_bytes_per_row < ((uint64_t)(v_dst.len))) { v_dst = wuffs_base__slice_u8__subslice_j(v_dst, v_dst_bytes_per_row); } wuffs_base__pixel_swizzler__swizzle_interleaved_from_slice(&self->private_impl.f_swizzler, v_dst, v_dst_palette, wuffs_base__slice_u8__subslice_j(a_src, v_src_bytes_per_row)); a_src = wuffs_base__slice_u8__subslice_i(a_src, v_src_bytes_per_row); v_y += 1u; } return wuffs_base__make_status(NULL); } // -------- func webp.decoder.frame_dirty_rect WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__rect_ie_u32 wuffs_webp__decoder__frame_dirty_rect( const wuffs_webp__decoder* self) { if (!self) { return wuffs_base__utility__empty_rect_ie_u32(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_rect_ie_u32(); } return wuffs_base__utility__make_rect_ie_u32( 0u, 0u, self->private_impl.f_width, self->private_impl.f_height); } // -------- func webp.decoder.num_animation_loops WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_webp__decoder__num_animation_loops( const wuffs_webp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func webp.decoder.num_decoded_frame_configs WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__num_decoded_frame_configs( const wuffs_webp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 32u) { return 1u; } return 0u; } // -------- func webp.decoder.num_decoded_frames WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_webp__decoder__num_decoded_frames( const wuffs_webp__decoder* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (self->private_impl.f_call_sequence > 64u) { return 1u; } return 0u; } // -------- func webp.decoder.restart_frame WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__restart_frame( wuffs_webp__decoder* self, uint64_t a_index, uint64_t a_io_position) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (self->private_impl.f_call_sequence < 32u) { return wuffs_base__make_status(wuffs_base__error__bad_call_sequence); } if ((a_index != 0u) || (a_io_position != self->private_impl.f_frame_config_io_position)) { return wuffs_base__make_status(wuffs_base__error__bad_argument); } self->private_impl.f_call_sequence = 40u; return wuffs_base__make_status(NULL); } // -------- func webp.decoder.set_report_metadata WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_webp__decoder__set_report_metadata( wuffs_webp__decoder* self, uint32_t a_fourcc, bool a_report) { return wuffs_base__make_empty_struct(); } // -------- func webp.decoder.tell_me_more WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_webp__decoder__tell_me_more( wuffs_webp__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 4)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); status = wuffs_base__make_status(wuffs_base__error__no_more_information); goto exit; goto ok; ok: goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func webp.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_webp__decoder__workbuf_len( const wuffs_webp__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_base__utility__make_range_ii_u64(((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[3u])), ((uint64_t)(self->private_impl.f_workbuf_offset_for_transform[3u]))); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WEBP) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH32) // ---------------- Status Codes Implementations // ---------------- Private Consts #define WUFFS_XXHASH32__XXH_PRIME32_1 2654435761u #define WUFFS_XXHASH32__XXH_PRIME32_2 2246822519u #define WUFFS_XXHASH32__XXH_PRIME32_3 3266489917u #define WUFFS_XXHASH32__XXH_PRIME32_4 668265263u #define WUFFS_XXHASH32__XXH_PRIME32_5 374761393u #define WUFFS_XXHASH32__INITIAL_V0 606290984u #define WUFFS_XXHASH32__INITIAL_V1 2246822519u #define WUFFS_XXHASH32__INITIAL_V2 0u #define WUFFS_XXHASH32__INITIAL_V3 1640531535u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_xxhash32__hasher__up( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x); // ---------------- VTables const wuffs_base__hasher_u32__func_ptrs wuffs_xxhash32__hasher__func_ptrs_for__wuffs_base__hasher_u32 = { (uint32_t(*)(const void*))(&wuffs_xxhash32__hasher__checksum_u32), (uint64_t(*)(const void*, uint32_t))(&wuffs_xxhash32__hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_xxhash32__hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_xxhash32__hasher__update), (uint32_t(*)(void*, wuffs_base__slice_u8))(&wuffs_xxhash32__hasher__update_u32), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xxhash32__hasher__initialize( wuffs_xxhash32__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_u32.vtable_name = wuffs_base__hasher_u32__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_u32.function_pointers = (const void*)(&wuffs_xxhash32__hasher__func_ptrs_for__wuffs_base__hasher_u32); return wuffs_base__make_status(NULL); } wuffs_xxhash32__hasher* wuffs_xxhash32__hasher__alloc(void) { wuffs_xxhash32__hasher* x = (wuffs_xxhash32__hasher*)(calloc(1, sizeof(wuffs_xxhash32__hasher))); if (!x) { return NULL; } if (wuffs_xxhash32__hasher__initialize( x, sizeof(wuffs_xxhash32__hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_xxhash32__hasher(void) { return sizeof(wuffs_xxhash32__hasher); } // ---------------- Function Implementations // -------- func xxhash32.hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash32__hasher__get_quirk( const wuffs_xxhash32__hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func xxhash32.hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xxhash32__hasher__set_quirk( wuffs_xxhash32__hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func xxhash32.hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_xxhash32__hasher__update( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } wuffs_base__slice_u8 v_remaining = {0}; if ((self->private_impl.f_length_modulo_u32 == 0u) && ! self->private_impl.f_length_overflows_u32) { self->private_impl.f_v0 = 606290984u; self->private_impl.f_v1 = 2246822519u; self->private_impl.f_v2 = 0u; self->private_impl.f_v3 = 1640531535u; } while (((uint64_t)(a_x.len)) > 0u) { v_remaining = wuffs_base__slice_u8__subslice_j(a_x, 0u); if (((uint64_t)(a_x.len)) > 16777216u) { v_remaining = wuffs_base__slice_u8__subslice_i(a_x, 16777216u); a_x = wuffs_base__slice_u8__subslice_j(a_x, 16777216u); } wuffs_xxhash32__hasher__up(self, a_x); a_x = v_remaining; } return wuffs_base__make_empty_struct(); } // -------- func xxhash32.hasher.update_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_xxhash32__hasher__update_u32( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } wuffs_xxhash32__hasher__update(self, a_x); return wuffs_xxhash32__hasher__checksum_u32(self); } // -------- func xxhash32.hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_xxhash32__hasher__up( wuffs_xxhash32__hasher* self, wuffs_base__slice_u8 a_x) { uint32_t v_new_lmu = 0; uint32_t v_buf_u32 = 0; uint32_t v_buf_len = 0; uint32_t v_v0 = 0; uint32_t v_v1 = 0; uint32_t v_v2 = 0; uint32_t v_v3 = 0; wuffs_base__slice_u8 v_p = {0}; v_new_lmu = ((uint32_t)(self->private_impl.f_length_modulo_u32 + ((uint32_t)(((uint64_t)(a_x.len)))))); self->private_impl.f_length_overflows_u32 = ((v_new_lmu < self->private_impl.f_length_modulo_u32) || self->private_impl.f_length_overflows_u32); self->private_impl.f_length_modulo_u32 = v_new_lmu; while (true) { if (self->private_impl.f_buf_len >= 16u) { v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[0u])) | (((uint32_t)(self->private_impl.f_buf_data[1u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[2u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[3u])) << 24u)); v_v0 = ((uint32_t)(self->private_impl.f_v0 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v0 = (((uint32_t)(v_v0 << 13u)) | (v_v0 >> 19u)); self->private_impl.f_v0 = ((uint32_t)(v_v0 * 2654435761u)); v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[4u])) | (((uint32_t)(self->private_impl.f_buf_data[5u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[6u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[7u])) << 24u)); v_v1 = ((uint32_t)(self->private_impl.f_v1 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v1 = (((uint32_t)(v_v1 << 13u)) | (v_v1 >> 19u)); self->private_impl.f_v1 = ((uint32_t)(v_v1 * 2654435761u)); v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[8u])) | (((uint32_t)(self->private_impl.f_buf_data[9u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[10u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[11u])) << 24u)); v_v2 = ((uint32_t)(self->private_impl.f_v2 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v2 = (((uint32_t)(v_v2 << 13u)) | (v_v2 >> 19u)); self->private_impl.f_v2 = ((uint32_t)(v_v2 * 2654435761u)); v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[12u])) | (((uint32_t)(self->private_impl.f_buf_data[13u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[14u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[15u])) << 24u)); v_v3 = ((uint32_t)(self->private_impl.f_v3 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v3 = (((uint32_t)(v_v3 << 13u)) | (v_v3 >> 19u)); self->private_impl.f_v3 = ((uint32_t)(v_v3 * 2654435761u)); self->private_impl.f_buf_len = 0u; break; } if (((uint64_t)(a_x.len)) <= 0u) { return wuffs_base__make_empty_struct(); } self->private_impl.f_buf_data[self->private_impl.f_buf_len] = a_x.ptr[0u]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif self->private_impl.f_buf_len += 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } v_buf_len = ((uint32_t)(((uint8_t)(self->private_impl.f_buf_len & 15u)))); v_v0 = self->private_impl.f_v0; v_v1 = self->private_impl.f_v1; v_v2 = self->private_impl.f_v2; v_v3 = self->private_impl.f_v3; { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 16; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 16) * 16)); while (v_p.ptr < i_end0_p) { v_buf_u32 = (((uint32_t)(v_p.ptr[0u])) | (((uint32_t)(v_p.ptr[1u])) << 8u) | (((uint32_t)(v_p.ptr[2u])) << 16u) | (((uint32_t)(v_p.ptr[3u])) << 24u)); v_v0 = ((uint32_t)(v_v0 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v0 = (((uint32_t)(v_v0 << 13u)) | (v_v0 >> 19u)); v_v0 = ((uint32_t)(v_v0 * 2654435761u)); v_buf_u32 = (((uint32_t)(v_p.ptr[4u])) | (((uint32_t)(v_p.ptr[5u])) << 8u) | (((uint32_t)(v_p.ptr[6u])) << 16u) | (((uint32_t)(v_p.ptr[7u])) << 24u)); v_v1 = ((uint32_t)(v_v1 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v1 = (((uint32_t)(v_v1 << 13u)) | (v_v1 >> 19u)); v_v1 = ((uint32_t)(v_v1 * 2654435761u)); v_buf_u32 = (((uint32_t)(v_p.ptr[8u])) | (((uint32_t)(v_p.ptr[9u])) << 8u) | (((uint32_t)(v_p.ptr[10u])) << 16u) | (((uint32_t)(v_p.ptr[11u])) << 24u)); v_v2 = ((uint32_t)(v_v2 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v2 = (((uint32_t)(v_v2 << 13u)) | (v_v2 >> 19u)); v_v2 = ((uint32_t)(v_v2 * 2654435761u)); v_buf_u32 = (((uint32_t)(v_p.ptr[12u])) | (((uint32_t)(v_p.ptr[13u])) << 8u) | (((uint32_t)(v_p.ptr[14u])) << 16u) | (((uint32_t)(v_p.ptr[15u])) << 24u)); v_v3 = ((uint32_t)(v_v3 + ((uint32_t)(v_buf_u32 * 2246822519u)))); v_v3 = (((uint32_t)(v_v3 << 13u)) | (v_v3 >> 19u)); v_v3 = ((uint32_t)(v_v3 * 2654435761u)); v_p.ptr += 16; } v_p.len = 1; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end1_p) { self->private_impl.f_buf_data[v_buf_len] = v_p.ptr[0u]; v_buf_len = ((v_buf_len + 1u) & 15u); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_buf_len = ((uint8_t)(v_buf_len)); self->private_impl.f_v0 = v_v0; self->private_impl.f_v1 = v_v1; self->private_impl.f_v2 = v_v2; self->private_impl.f_v3 = v_v3; return wuffs_base__make_empty_struct(); } // -------- func xxhash32.hasher.checksum_u32 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint32_t wuffs_xxhash32__hasher__checksum_u32( const wuffs_xxhash32__hasher* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } uint32_t v_ret = 0; uint32_t v_i = 0; uint32_t v_n = 0; uint32_t v_buf_u32 = 0; if ((self->private_impl.f_length_modulo_u32 >= 16u) || self->private_impl.f_length_overflows_u32) { v_ret += (((uint32_t)(self->private_impl.f_v0 << 1u)) | (self->private_impl.f_v0 >> 31u)); v_ret += (((uint32_t)(self->private_impl.f_v1 << 7u)) | (self->private_impl.f_v1 >> 25u)); v_ret += (((uint32_t)(self->private_impl.f_v2 << 12u)) | (self->private_impl.f_v2 >> 20u)); v_ret += (((uint32_t)(self->private_impl.f_v3 << 18u)) | (self->private_impl.f_v3 >> 14u)); v_ret += self->private_impl.f_length_modulo_u32; } else { v_ret += 374761393u; v_ret += self->private_impl.f_length_modulo_u32; } v_n = 16u; v_n = wuffs_base__u32__min(v_n, ((uint32_t)(self->private_impl.f_buf_len))); if (4u <= v_n) { v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[0u])) | (((uint32_t)(self->private_impl.f_buf_data[1u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[2u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[3u])) << 24u)); v_ret += ((uint32_t)(v_buf_u32 * 3266489917u)); v_ret = (((uint32_t)(v_ret << 17u)) | (v_ret >> 15u)); v_ret *= 668265263u; v_i = 4u; } if (8u <= v_n) { v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[4u])) | (((uint32_t)(self->private_impl.f_buf_data[5u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[6u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[7u])) << 24u)); v_ret += ((uint32_t)(v_buf_u32 * 3266489917u)); v_ret = (((uint32_t)(v_ret << 17u)) | (v_ret >> 15u)); v_ret *= 668265263u; v_i = 8u; } if (12u <= v_n) { v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[8u])) | (((uint32_t)(self->private_impl.f_buf_data[9u])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[10u])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[11u])) << 24u)); v_ret += ((uint32_t)(v_buf_u32 * 3266489917u)); v_ret = (((uint32_t)(v_ret << 17u)) | (v_ret >> 15u)); v_ret *= 668265263u; v_i = 12u; } while (v_i < v_n) { v_ret += ((uint32_t)(((uint32_t)(self->private_impl.f_buf_data[v_i])) * 374761393u)); v_ret = (((uint32_t)(v_ret << 11u)) | (v_ret >> 21u)); v_ret *= 2654435761u; v_i += 1u; } v_ret ^= (v_ret >> 15u); v_ret *= 2246822519u; v_ret ^= (v_ret >> 13u); v_ret *= 3266489917u; v_ret ^= (v_ret >> 16u); return v_ret; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH32) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH64) // ---------------- Status Codes Implementations // ---------------- Private Consts #define WUFFS_XXHASH64__XXH_PRIME64_1 11400714785074694791u #define WUFFS_XXHASH64__XXH_PRIME64_2 14029467366897019727u #define WUFFS_XXHASH64__XXH_PRIME64_3 1609587929392839161u #define WUFFS_XXHASH64__XXH_PRIME64_4 9650029242287828579u #define WUFFS_XXHASH64__XXH_PRIME64_5 2870177450012600261u #define WUFFS_XXHASH64__INITIAL_V0 6983438078262162902u #define WUFFS_XXHASH64__INITIAL_V1 14029467366897019727u #define WUFFS_XXHASH64__INITIAL_V2 0u #define WUFFS_XXHASH64__INITIAL_V3 7046029288634856825u // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_xxhash64__hasher__up( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x); // ---------------- VTables const wuffs_base__hasher_u64__func_ptrs wuffs_xxhash64__hasher__func_ptrs_for__wuffs_base__hasher_u64 = { (uint64_t(*)(const void*))(&wuffs_xxhash64__hasher__checksum_u64), (uint64_t(*)(const void*, uint32_t))(&wuffs_xxhash64__hasher__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_xxhash64__hasher__set_quirk), (wuffs_base__empty_struct(*)(void*, wuffs_base__slice_u8))(&wuffs_xxhash64__hasher__update), (uint64_t(*)(void*, wuffs_base__slice_u8))(&wuffs_xxhash64__hasher__update_u64), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xxhash64__hasher__initialize( wuffs_xxhash64__hasher* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__hasher_u64.vtable_name = wuffs_base__hasher_u64__vtable_name; self->private_impl.vtable_for__wuffs_base__hasher_u64.function_pointers = (const void*)(&wuffs_xxhash64__hasher__func_ptrs_for__wuffs_base__hasher_u64); return wuffs_base__make_status(NULL); } wuffs_xxhash64__hasher* wuffs_xxhash64__hasher__alloc(void) { wuffs_xxhash64__hasher* x = (wuffs_xxhash64__hasher*)(calloc(1, sizeof(wuffs_xxhash64__hasher))); if (!x) { return NULL; } if (wuffs_xxhash64__hasher__initialize( x, sizeof(wuffs_xxhash64__hasher), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_xxhash64__hasher(void) { return sizeof(wuffs_xxhash64__hasher); } // ---------------- Function Implementations // -------- func xxhash64.hasher.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__get_quirk( const wuffs_xxhash64__hasher* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } return 0u; } // -------- func xxhash64.hasher.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xxhash64__hasher__set_quirk( wuffs_xxhash64__hasher* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func xxhash64.hasher.update WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__empty_struct wuffs_xxhash64__hasher__update( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return wuffs_base__make_empty_struct(); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_empty_struct(); } if ((self->private_impl.f_length_modulo_u64 == 0u) && ! self->private_impl.f_length_overflows_u64) { self->private_impl.f_v0 = 6983438078262162902u; self->private_impl.f_v1 = 14029467366897019727u; self->private_impl.f_v2 = 0u; self->private_impl.f_v3 = 7046029288634856825u; } wuffs_xxhash64__hasher__up(self, a_x); return wuffs_base__make_empty_struct(); } // -------- func xxhash64.hasher.update_u64 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__update_u64( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x) { if (!self) { return 0; } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return 0; } wuffs_xxhash64__hasher__update(self, a_x); return wuffs_xxhash64__hasher__checksum_u64(self); } // -------- func xxhash64.hasher.up WUFFS_BASE__GENERATED_C_CODE static wuffs_base__empty_struct wuffs_xxhash64__hasher__up( wuffs_xxhash64__hasher* self, wuffs_base__slice_u8 a_x) { uint64_t v_new_lmu = 0; uint64_t v_buf_u64 = 0; uint32_t v_buf_len = 0; uint64_t v_v0 = 0; uint64_t v_v1 = 0; uint64_t v_v2 = 0; uint64_t v_v3 = 0; wuffs_base__slice_u8 v_p = {0}; v_new_lmu = ((uint64_t)(self->private_impl.f_length_modulo_u64 + ((uint64_t)(a_x.len)))); self->private_impl.f_length_overflows_u64 = ((v_new_lmu < self->private_impl.f_length_modulo_u64) || self->private_impl.f_length_overflows_u64); self->private_impl.f_length_modulo_u64 = v_new_lmu; while (true) { if (self->private_impl.f_buf_len >= 32u) { v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[0u])) | (((uint64_t)(self->private_impl.f_buf_data[1u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[2u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[3u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[4u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[5u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[6u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[7u])) << 56u)); v_v0 = ((uint64_t)(self->private_impl.f_v0 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v0 = (((uint64_t)(v_v0 << 31u)) | (v_v0 >> 33u)); self->private_impl.f_v0 = ((uint64_t)(v_v0 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[8u])) | (((uint64_t)(self->private_impl.f_buf_data[9u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[10u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[11u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[12u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[13u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[14u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[15u])) << 56u)); v_v1 = ((uint64_t)(self->private_impl.f_v1 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v1 = (((uint64_t)(v_v1 << 31u)) | (v_v1 >> 33u)); self->private_impl.f_v1 = ((uint64_t)(v_v1 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[16u])) | (((uint64_t)(self->private_impl.f_buf_data[17u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[18u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[19u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[20u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[21u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[22u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[23u])) << 56u)); v_v2 = ((uint64_t)(self->private_impl.f_v2 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v2 = (((uint64_t)(v_v2 << 31u)) | (v_v2 >> 33u)); self->private_impl.f_v2 = ((uint64_t)(v_v2 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[24u])) | (((uint64_t)(self->private_impl.f_buf_data[25u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[26u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[27u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[28u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[29u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[30u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[31u])) << 56u)); v_v3 = ((uint64_t)(self->private_impl.f_v3 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v3 = (((uint64_t)(v_v3 << 31u)) | (v_v3 >> 33u)); self->private_impl.f_v3 = ((uint64_t)(v_v3 * 11400714785074694791u)); self->private_impl.f_buf_len = 0u; break; } if (((uint64_t)(a_x.len)) <= 0u) { return wuffs_base__make_empty_struct(); } self->private_impl.f_buf_data[self->private_impl.f_buf_len] = a_x.ptr[0u]; self->private_impl.f_buf_len += 1u; a_x = wuffs_base__slice_u8__subslice_i(a_x, 1u); } v_buf_len = (self->private_impl.f_buf_len & 31u); v_v0 = self->private_impl.f_v0; v_v1 = self->private_impl.f_v1; v_v2 = self->private_impl.f_v2; v_v3 = self->private_impl.f_v3; { wuffs_base__slice_u8 i_slice_p = a_x; v_p.ptr = i_slice_p.ptr; v_p.len = 32; const uint8_t* i_end0_p = wuffs_private_impl__ptr_u8_plus_len(v_p.ptr, (((i_slice_p.len - (size_t)(v_p.ptr - i_slice_p.ptr)) / 32) * 32)); while (v_p.ptr < i_end0_p) { v_buf_u64 = (((uint64_t)(v_p.ptr[0u])) | (((uint64_t)(v_p.ptr[1u])) << 8u) | (((uint64_t)(v_p.ptr[2u])) << 16u) | (((uint64_t)(v_p.ptr[3u])) << 24u) | (((uint64_t)(v_p.ptr[4u])) << 32u) | (((uint64_t)(v_p.ptr[5u])) << 40u) | (((uint64_t)(v_p.ptr[6u])) << 48u) | (((uint64_t)(v_p.ptr[7u])) << 56u)); v_v0 = ((uint64_t)(v_v0 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v0 = (((uint64_t)(v_v0 << 31u)) | (v_v0 >> 33u)); v_v0 = ((uint64_t)(v_v0 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(v_p.ptr[8u])) | (((uint64_t)(v_p.ptr[9u])) << 8u) | (((uint64_t)(v_p.ptr[10u])) << 16u) | (((uint64_t)(v_p.ptr[11u])) << 24u) | (((uint64_t)(v_p.ptr[12u])) << 32u) | (((uint64_t)(v_p.ptr[13u])) << 40u) | (((uint64_t)(v_p.ptr[14u])) << 48u) | (((uint64_t)(v_p.ptr[15u])) << 56u)); v_v1 = ((uint64_t)(v_v1 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v1 = (((uint64_t)(v_v1 << 31u)) | (v_v1 >> 33u)); v_v1 = ((uint64_t)(v_v1 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(v_p.ptr[16u])) | (((uint64_t)(v_p.ptr[17u])) << 8u) | (((uint64_t)(v_p.ptr[18u])) << 16u) | (((uint64_t)(v_p.ptr[19u])) << 24u) | (((uint64_t)(v_p.ptr[20u])) << 32u) | (((uint64_t)(v_p.ptr[21u])) << 40u) | (((uint64_t)(v_p.ptr[22u])) << 48u) | (((uint64_t)(v_p.ptr[23u])) << 56u)); v_v2 = ((uint64_t)(v_v2 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v2 = (((uint64_t)(v_v2 << 31u)) | (v_v2 >> 33u)); v_v2 = ((uint64_t)(v_v2 * 11400714785074694791u)); v_buf_u64 = (((uint64_t)(v_p.ptr[24u])) | (((uint64_t)(v_p.ptr[25u])) << 8u) | (((uint64_t)(v_p.ptr[26u])) << 16u) | (((uint64_t)(v_p.ptr[27u])) << 24u) | (((uint64_t)(v_p.ptr[28u])) << 32u) | (((uint64_t)(v_p.ptr[29u])) << 40u) | (((uint64_t)(v_p.ptr[30u])) << 48u) | (((uint64_t)(v_p.ptr[31u])) << 56u)); v_v3 = ((uint64_t)(v_v3 + ((uint64_t)(v_buf_u64 * 14029467366897019727u)))); v_v3 = (((uint64_t)(v_v3 << 31u)) | (v_v3 >> 33u)); v_v3 = ((uint64_t)(v_v3 * 11400714785074694791u)); v_p.ptr += 32; } v_p.len = 1; const uint8_t* i_end1_p = wuffs_private_impl__ptr_u8_plus_len(i_slice_p.ptr, i_slice_p.len); while (v_p.ptr < i_end1_p) { self->private_impl.f_buf_data[v_buf_len] = v_p.ptr[0u]; v_buf_len = ((v_buf_len + 1u) & 31u); v_p.ptr += 1; } v_p.len = 0; } self->private_impl.f_buf_len = v_buf_len; self->private_impl.f_v0 = v_v0; self->private_impl.f_v1 = v_v1; self->private_impl.f_v2 = v_v2; self->private_impl.f_v3 = v_v3; return wuffs_base__make_empty_struct(); } // -------- func xxhash64.hasher.checksum_u64 WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xxhash64__hasher__checksum_u64( const wuffs_xxhash64__hasher* self) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } uint64_t v_ret = 0; uint64_t v_v0 = 0; uint64_t v_v1 = 0; uint64_t v_v2 = 0; uint64_t v_v3 = 0; uint32_t v_i = 0; uint32_t v_i8 = 0; uint32_t v_n = 0; uint32_t v_buf_u32 = 0; uint64_t v_buf_u64 = 0; if ((self->private_impl.f_length_modulo_u64 >= 32u) || self->private_impl.f_length_overflows_u64) { v_ret += (((uint64_t)(self->private_impl.f_v0 << 1u)) | (self->private_impl.f_v0 >> 63u)); v_ret += (((uint64_t)(self->private_impl.f_v1 << 7u)) | (self->private_impl.f_v1 >> 57u)); v_ret += (((uint64_t)(self->private_impl.f_v2 << 12u)) | (self->private_impl.f_v2 >> 52u)); v_ret += (((uint64_t)(self->private_impl.f_v3 << 18u)) | (self->private_impl.f_v3 >> 46u)); v_v0 = ((uint64_t)(self->private_impl.f_v0 * 14029467366897019727u)); v_v0 = (((uint64_t)(v_v0 << 31u)) | (v_v0 >> 33u)); v_v0 *= 11400714785074694791u; v_v1 = ((uint64_t)(self->private_impl.f_v1 * 14029467366897019727u)); v_v1 = (((uint64_t)(v_v1 << 31u)) | (v_v1 >> 33u)); v_v1 *= 11400714785074694791u; v_v2 = ((uint64_t)(self->private_impl.f_v2 * 14029467366897019727u)); v_v2 = (((uint64_t)(v_v2 << 31u)) | (v_v2 >> 33u)); v_v2 *= 11400714785074694791u; v_v3 = ((uint64_t)(self->private_impl.f_v3 * 14029467366897019727u)); v_v3 = (((uint64_t)(v_v3 << 31u)) | (v_v3 >> 33u)); v_v3 *= 11400714785074694791u; v_ret = ((uint64_t)(((uint64_t)((v_ret ^ v_v0) * 11400714785074694791u)) + 9650029242287828579u)); v_ret = ((uint64_t)(((uint64_t)((v_ret ^ v_v1) * 11400714785074694791u)) + 9650029242287828579u)); v_ret = ((uint64_t)(((uint64_t)((v_ret ^ v_v2) * 11400714785074694791u)) + 9650029242287828579u)); v_ret = ((uint64_t)(((uint64_t)((v_ret ^ v_v3) * 11400714785074694791u)) + 9650029242287828579u)); v_ret += self->private_impl.f_length_modulo_u64; } else { v_ret += 2870177450012600261u; v_ret += self->private_impl.f_length_modulo_u64; } v_n = 32u; v_n = wuffs_base__u32__min(v_n, self->private_impl.f_buf_len); if (8u <= v_n) { v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[0u])) | (((uint64_t)(self->private_impl.f_buf_data[1u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[2u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[3u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[4u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[5u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[6u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[7u])) << 56u)); v_buf_u64 *= 14029467366897019727u; v_buf_u64 = (((uint64_t)(v_buf_u64 << 31u)) | (v_buf_u64 >> 33u)); v_buf_u64 *= 11400714785074694791u; v_ret ^= v_buf_u64; v_ret = (((uint64_t)(v_ret << 27u)) | (v_ret >> 37u)); v_ret *= 11400714785074694791u; v_ret += 9650029242287828579u; v_i = 8u; } if (16u <= v_n) { v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[8u])) | (((uint64_t)(self->private_impl.f_buf_data[9u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[10u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[11u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[12u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[13u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[14u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[15u])) << 56u)); v_buf_u64 *= 14029467366897019727u; v_buf_u64 = (((uint64_t)(v_buf_u64 << 31u)) | (v_buf_u64 >> 33u)); v_buf_u64 *= 11400714785074694791u; v_ret ^= v_buf_u64; v_ret = (((uint64_t)(v_ret << 27u)) | (v_ret >> 37u)); v_ret *= 11400714785074694791u; v_ret += 9650029242287828579u; v_i = 16u; } if (24u <= v_n) { v_buf_u64 = (((uint64_t)(self->private_impl.f_buf_data[16u])) | (((uint64_t)(self->private_impl.f_buf_data[17u])) << 8u) | (((uint64_t)(self->private_impl.f_buf_data[18u])) << 16u) | (((uint64_t)(self->private_impl.f_buf_data[19u])) << 24u) | (((uint64_t)(self->private_impl.f_buf_data[20u])) << 32u) | (((uint64_t)(self->private_impl.f_buf_data[21u])) << 40u) | (((uint64_t)(self->private_impl.f_buf_data[22u])) << 48u) | (((uint64_t)(self->private_impl.f_buf_data[23u])) << 56u)); v_buf_u64 *= 14029467366897019727u; v_buf_u64 = (((uint64_t)(v_buf_u64 << 31u)) | (v_buf_u64 >> 33u)); v_buf_u64 *= 11400714785074694791u; v_ret ^= v_buf_u64; v_ret = (((uint64_t)(v_ret << 27u)) | (v_ret >> 37u)); v_ret *= 11400714785074694791u; v_ret += 9650029242287828579u; v_i = 24u; } if ((v_n & 4u) != 0u) { v_i8 = (v_i & 24u); v_buf_u32 = (((uint32_t)(self->private_impl.f_buf_data[(v_i8 + 0u)])) | (((uint32_t)(self->private_impl.f_buf_data[(v_i8 + 1u)])) << 8u) | (((uint32_t)(self->private_impl.f_buf_data[(v_i8 + 2u)])) << 16u) | (((uint32_t)(self->private_impl.f_buf_data[(v_i8 + 3u)])) << 24u)); v_ret ^= ((uint64_t)(((uint64_t)(v_buf_u32)) * 11400714785074694791u)); v_ret = (((uint64_t)(v_ret << 23u)) | (v_ret >> 41u)); v_ret *= 14029467366897019727u; v_ret += 1609587929392839161u; v_i = (v_i8 + 4u); } while (v_i < v_n) { v_ret ^= ((uint64_t)(((uint64_t)(self->private_impl.f_buf_data[v_i])) * 2870177450012600261u)); v_ret = (((uint64_t)(v_ret << 11u)) | (v_ret >> 53u)); v_ret *= 11400714785074694791u; v_i += 1u; } v_ret ^= (v_ret >> 33u); v_ret *= 14029467366897019727u; v_ret ^= (v_ret >> 29u); v_ret *= 1609587929392839161u; v_ret ^= (v_ret >> 32u); return ((uint64_t)(v_ret)); } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XXHASH64) #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XZ) // ---------------- Status Codes Implementations const char wuffs_xz__error__bad_bcj_offset[] = "#xz: bad BCJ offset"; const char wuffs_xz__error__bad_block_header[] = "#xz: bad block header"; const char wuffs_xz__error__bad_checksum[] = "#xz: bad checksum"; const char wuffs_xz__error__bad_filter[] = "#xz: bad filter"; const char wuffs_xz__error__bad_footer[] = "#xz: bad footer"; const char wuffs_xz__error__bad_header[] = "#xz: bad header"; const char wuffs_xz__error__bad_header_concatenated_stream[] = "#xz: bad header (concatenated stream)"; const char wuffs_xz__error__bad_index[] = "#xz: bad index"; const char wuffs_xz__error__bad_padding[] = "#xz: bad padding"; const char wuffs_xz__error__truncated_input[] = "#xz: truncated input"; const char wuffs_xz__error__unsupported_checksum_algorithm[] = "#xz: unsupported checksum algorithm"; const char wuffs_xz__error__unsupported_filter[] = "#xz: unsupported filter"; const char wuffs_xz__error__unsupported_filter_combination[] = "#xz: unsupported filter combination"; const char wuffs_xz__error__internal_error_inconsistent_bcj_filter_state[] = "#xz: internal error: inconsistent BCJ filter state"; // ---------------- Private Consts static const bool WUFFS_XZ__FILTER_04_X86_MASK_TO_ALLOWED_STATUS[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 1u, 1u, 1u, 0u, 1u, 0u, 0u, 0u, }; static const uint8_t WUFFS_XZ__FILTER_04_X86_MASK_TO_BIT_NUM[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 1u, 2u, 2u, 3u, 3u, 3u, 3u, }; static const uint32_t WUFFS_XZ__FILTER_04_X86_MASK_TO_XOR_OPERAND[8] WUFFS_BASE__POTENTIALLY_UNUSED = { 4294967295u, 16777215u, 65535u, 65535u, 255u, 255u, 255u, 255u, }; static const uint8_t WUFFS_XZ__FILTER_06_IA64_BRANCH_TABLE[32] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 0u, 4u, 4u, 6u, 6u, 0u, 0u, 7u, 7u, 4u, 4u, 0u, 0u, 4u, 4u, 0u, 0u, }; #define WUFFS_XZ__QUIRKS_BASE 2021322752u static const uint8_t WUFFS_XZ__CHECKSUM_LENGTH[4] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 4u, 8u, 32u, }; static const uint8_t WUFFS_XZ__ZEROES[3] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, }; static const uint8_t WUFFS_XZ__BCJ_OFFSET_ALIGNMENT[12] WUFFS_BASE__POTENTIALLY_UNUSED = { 0u, 0u, 0u, 0u, 1u, 4u, 16u, 4u, 2u, 4u, 4u, 2u, }; // ---------------- Private Initializer Prototypes // ---------------- Private Function Prototypes WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_non_final_filters( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_non_final_filters__choosy_default( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_04_x86( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_05_powerpc( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_06_ia64( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_07_arm( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_08_armthumb( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_09_sparc( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_0a_arm64( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_0b_riscv( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__do_transform_io( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__decode_block_header_with_padding( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__decode_block_header_sans_padding( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__verify_index( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src); WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__verify_footer( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src); // ---------------- VTables const wuffs_base__io_transformer__func_ptrs wuffs_xz__decoder__func_ptrs_for__wuffs_base__io_transformer = { (wuffs_base__optional_u63(*)(const void*))(&wuffs_xz__decoder__dst_history_retain_length), (uint64_t(*)(const void*, uint32_t))(&wuffs_xz__decoder__get_quirk), (wuffs_base__status(*)(void*, uint32_t, uint64_t))(&wuffs_xz__decoder__set_quirk), (wuffs_base__status(*)(void*, wuffs_base__io_buffer*, wuffs_base__io_buffer*, wuffs_base__slice_u8))(&wuffs_xz__decoder__transform_io), (wuffs_base__range_ii_u64(*)(const void*))(&wuffs_xz__decoder__workbuf_len), }; // ---------------- Initializer Implementations wuffs_base__status WUFFS_BASE__WARN_UNUSED_RESULT wuffs_xz__decoder__initialize( wuffs_xz__decoder* self, size_t sizeof_star_self, uint64_t wuffs_version, uint32_t options){ if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (sizeof(*self) != sizeof_star_self) { return wuffs_base__make_status(wuffs_base__error__bad_sizeof_receiver); } if (((wuffs_version >> 32) != WUFFS_VERSION_MAJOR) || (((wuffs_version >> 16) & 0xFFFF) > WUFFS_VERSION_MINOR)) { return wuffs_base__make_status(wuffs_base__error__bad_wuffs_version); } if ((options & WUFFS_INITIALIZE__ALREADY_ZEROED) != 0) { // The whole point of this if-check is to detect an uninitialized *self. // We disable the warning on GCC. Clang-5.0 does not have this warning. #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wmaybe-uninitialized" #endif if (self->private_impl.magic != 0) { return wuffs_base__make_status(wuffs_base__error__initialize_falsely_claimed_already_zeroed); } #if !defined(__clang__) && defined(__GNUC__) #pragma GCC diagnostic pop #endif } else { if ((options & WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED) == 0) { memset(self, 0, sizeof(*self)); options |= WUFFS_INITIALIZE__ALREADY_ZEROED; } else { memset(&(self->private_impl), 0, sizeof(self->private_impl)); } } self->private_impl.choosy_apply_non_final_filters = &wuffs_xz__decoder__apply_non_final_filters__choosy_default; { wuffs_base__status z = wuffs_crc32__ieee_hasher__initialize( &self->private_data.f_crc32, sizeof(self->private_data.f_crc32), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_crc64__ecma_hasher__initialize( &self->private_data.f_crc64, sizeof(self->private_data.f_crc64), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_sha256__hasher__initialize( &self->private_data.f_sha256, sizeof(self->private_data.f_sha256), WUFFS_VERSION, options); if (z.repr) { return z; } } { wuffs_base__status z = wuffs_lzma__decoder__initialize( &self->private_data.f_lzma, sizeof(self->private_data.f_lzma), WUFFS_VERSION, options); if (z.repr) { return z; } } self->private_impl.magic = WUFFS_BASE__MAGIC; self->private_impl.vtable_for__wuffs_base__io_transformer.vtable_name = wuffs_base__io_transformer__vtable_name; self->private_impl.vtable_for__wuffs_base__io_transformer.function_pointers = (const void*)(&wuffs_xz__decoder__func_ptrs_for__wuffs_base__io_transformer); return wuffs_base__make_status(NULL); } wuffs_xz__decoder* wuffs_xz__decoder__alloc(void) { wuffs_xz__decoder* x = (wuffs_xz__decoder*)(calloc(1, sizeof(wuffs_xz__decoder))); if (!x) { return NULL; } if (wuffs_xz__decoder__initialize( x, sizeof(wuffs_xz__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__ALREADY_ZEROED).repr) { free(x); return NULL; } return x; } size_t sizeof__wuffs_xz__decoder(void) { return sizeof(wuffs_xz__decoder); } // ---------------- Function Implementations // -------- func xz.decoder.apply_non_final_filters WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_non_final_filters( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { return (*self->private_impl.choosy_apply_non_final_filters)(self, a_dst_slice); } WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_non_final_filters__choosy_default( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { uint32_t v_f = 0; uint64_t v_i = 0; uint32_t v_filter_id = 0; uint32_t v_delta_dist = 0; uint32_t v_delta_pos = 0; uint8_t v_c8 = 0; if (self->private_impl.f_num_non_final_filters <= 0u) { return 0u; } v_f = (self->private_impl.f_num_non_final_filters - 1u); while (true) { v_filter_id = (self->private_impl.f_filters[v_f] & 127u); if (v_filter_id == 3u) { v_delta_dist = (((self->private_impl.f_filters[v_f] >> 8u) & 255u) + 1u); v_delta_pos = (self->private_impl.f_filters[v_f] >> 24u); v_i = 0u; while (v_i < ((uint64_t)(a_dst_slice.len))) { v_c8 = a_dst_slice.ptr[v_i]; #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_c8 += self->private_data.f_filter_data[v_f][(((uint32_t)(v_delta_dist + v_delta_pos)) & 255u)]; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif self->private_data.f_filter_data[v_f][(v_delta_pos & 255u)] = v_c8; v_delta_pos -= 1u; a_dst_slice.ptr[v_i] = v_c8; v_i += 1u; } self->private_impl.f_filters[v_f] &= 65535u; self->private_impl.f_filters[v_f] |= ((uint32_t)(v_delta_pos << 24u)); } if (v_f <= 0u) { break; } v_f -= 1u; } return 0u; } // -------- func xz.decoder.apply_filter_04_x86 WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_04_x86( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint64_t v_i = 0; uint64_t v_prev_pos = 0; uint32_t v_prev_mask = 0; uint8_t v_c8 = 0; uint32_t v_src = 0; uint32_t v_dst = 0; uint32_t v_bit_num = 0; v_s = a_dst_slice; v_p = ((uint32_t)(self->private_impl.f_bcj_pos + 5u)); v_prev_pos = 18446744073709551615u; v_prev_mask = self->private_impl.f_bcj_x86_prev_mask; while (((uint64_t)(v_s.len)) >= 5u) { if (((uint8_t)(v_s.ptr[0u] & 254u)) != 232u) { v_i += 1u; v_p += 1u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 1u); continue; } v_prev_pos = ((uint64_t)(v_i - v_prev_pos)); if (v_prev_pos > 3u) { v_prev_mask = 0u; } else if (v_prev_pos > 0u) { v_prev_mask = (((uint32_t)(v_prev_mask << (v_prev_pos - 1u))) & 7u); if (v_prev_mask != 0u) { v_c8 = v_s.ptr[((uint8_t)(4u - WUFFS_XZ__FILTER_04_X86_MASK_TO_BIT_NUM[(v_prev_mask & 7u)]))]; if ( ! WUFFS_XZ__FILTER_04_X86_MASK_TO_ALLOWED_STATUS[(v_prev_mask & 7u)] || (v_c8 == 0u) || (v_c8 == 255u)) { v_prev_pos = v_i; v_prev_mask = (((uint32_t)(v_prev_mask << 1u)) | 1u); v_i += 1u; v_p += 1u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 1u); continue; } } } v_prev_pos = v_i; v_c8 = v_s.ptr[4u]; if ((v_c8 != 0u) && (v_c8 != 255u)) { v_prev_mask = (((uint32_t)(v_prev_mask << 1u)) | 1u); v_i += 1u; v_p += 1u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 1u); continue; } v_src = ((((uint32_t)(v_s.ptr[1u])) << 0u) | (((uint32_t)(v_s.ptr[2u])) << 8u) | (((uint32_t)(v_s.ptr[3u])) << 16u) | (((uint32_t)(v_s.ptr[4u])) << 24u)); while (true) { v_dst = ((uint32_t)(v_src - v_p)); if (v_prev_mask == 0u) { break; } v_bit_num = ((uint32_t)(WUFFS_XZ__FILTER_04_X86_MASK_TO_BIT_NUM[(v_prev_mask & 7u)])); v_c8 = ((uint8_t)((v_dst >> (24u - (v_bit_num * 8u))))); if ((v_c8 != 0u) && (v_c8 != 255u)) { break; } v_src = (v_dst ^ WUFFS_XZ__FILTER_04_X86_MASK_TO_XOR_OPERAND[(v_prev_mask & 7u)]); } v_dst &= 33554431u; v_dst |= ((uint32_t)(0u - (v_dst & 16777216u))); v_s.ptr[1u] = ((uint8_t)((v_dst >> 0u))); v_s.ptr[2u] = ((uint8_t)((v_dst >> 8u))); v_s.ptr[3u] = ((uint8_t)((v_dst >> 16u))); v_s.ptr[4u] = ((uint8_t)((v_dst >> 24u))); v_i += 5u; v_p += 5u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 5u); } v_prev_pos = ((uint64_t)(v_i - v_prev_pos)); if (v_prev_pos > 3u) { self->private_impl.f_bcj_x86_prev_mask = 0u; } else if (v_prev_pos > 0u) { self->private_impl.f_bcj_x86_prev_mask = ((uint32_t)(v_prev_mask << (v_prev_pos - 1u))); } self->private_impl.f_bcj_pos = ((uint32_t)(v_p - 5u)); return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_05_powerpc WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_05_powerpc( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; v_s = a_dst_slice; v_p = self->private_impl.f_bcj_pos; while (((uint64_t)(v_s.len)) >= 4u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 24u) | (((uint32_t)(v_s.ptr[1u])) << 16u) | (((uint32_t)(v_s.ptr[2u])) << 8u) | (((uint32_t)(v_s.ptr[3u])) << 0u)); if ((v_x & 4227858435u) == 1207959553u) { v_x = ((((uint32_t)((v_x & 67108860u) - v_p)) & 67108860u) | 1207959553u); v_s.ptr[0u] = ((uint8_t)((v_x >> 24u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 0u))); } v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } self->private_impl.f_bcj_pos = v_p; return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_06_ia64 WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_06_ia64( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_mask = 0; uint32_t v_slot = 0; uint32_t v_bit_pos = 0; uint32_t v_byte_pos = 0; uint32_t v_bit_res = 0; uint64_t v_x = 0; uint32_t v_j = 0; uint64_t v_norm = 0; uint32_t v_addr = 0; v_s = a_dst_slice; v_p = self->private_impl.f_bcj_pos; while (((uint64_t)(v_s.len)) >= 16u) { v_mask = ((uint32_t)(WUFFS_XZ__FILTER_06_IA64_BRANCH_TABLE[((uint8_t)(v_s.ptr[0u] & 31u))])); v_slot = 0u; while (true) { do { if (((v_mask >> v_slot) & 1u) == 0u) { break; } v_bit_pos = ((v_slot * 41u) + 5u); v_byte_pos = (v_bit_pos >> 3u); v_bit_res = (v_bit_pos & 7u); v_x = 0u; v_j = 0u; while (v_j < 6u) { v_x |= (((uint64_t)(v_s.ptr[(v_j + v_byte_pos)])) << (8u * v_j)); v_j += 1u; } v_norm = (v_x >> v_bit_res); if ((((v_norm >> 37u) & 15u) != 5u) || (((v_norm >> 9u) & 7u) != 0u)) { break; } v_addr = ((uint32_t)(((v_norm >> 13u) & 1048575u))); v_addr |= (((uint32_t)(((v_norm >> 36u) & 1u))) << 20u); v_addr <<= 4u; v_addr -= v_p; v_addr >>= 4u; v_norm &= 18446743996400148479u; v_norm |= (((uint64_t)((v_addr & 1048575u))) << 13u); v_norm |= (((uint64_t)((v_addr & 1048576u))) << 16u); v_x &= ((((uint64_t)(1u)) << v_bit_res) - 1u); v_x |= ((uint64_t)(v_norm << v_bit_res)); v_j = 0u; while (v_j < 6u) { v_s.ptr[(v_j + v_byte_pos)] = ((uint8_t)((v_x >> (8u * v_j)))); v_j += 1u; } } while (0); if (v_slot >= 2u) { break; } v_slot += 1u; } v_p += 16u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 16u); } self->private_impl.f_bcj_pos = v_p; return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_07_arm WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_07_arm( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; v_s = a_dst_slice; v_p = ((uint32_t)(self->private_impl.f_bcj_pos + 8u)); while (((uint64_t)(v_s.len)) >= 4u) { if (v_s.ptr[3u] == 235u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 0u) | (((uint32_t)(v_s.ptr[1u])) << 8u) | (((uint32_t)(v_s.ptr[2u])) << 16u) | (((uint32_t)(v_s.ptr[3u])) << 24u)); v_x = (((uint32_t)(((v_x & 16777215u) << 2u) - v_p)) >> 2u); v_s.ptr[0u] = ((uint8_t)((v_x >> 0u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 16u))); } v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } self->private_impl.f_bcj_pos = ((uint32_t)(v_p - 8u)); return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_08_armthumb WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_08_armthumb( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; uint32_t v_y = 0; v_s = a_dst_slice; v_p = ((uint32_t)(self->private_impl.f_bcj_pos + 4u)); while (((uint64_t)(v_s.len)) >= 4u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 0u) | (((uint32_t)(v_s.ptr[1u])) << 8u) | (((uint32_t)(v_s.ptr[2u])) << 16u) | (((uint32_t)(v_s.ptr[3u])) << 24u)); if ((v_x & 4160813056u) != 4160811008u) { v_p += 2u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 2u); continue; } v_y = ((((uint32_t)(((uint8_t)(v_s.ptr[0u] & 255u)))) << 11u) | (((uint32_t)(((uint8_t)(v_s.ptr[1u] & 7u)))) << 19u) | (((uint32_t)(((uint8_t)(v_s.ptr[2u] & 255u)))) << 0u) | (((uint32_t)(((uint8_t)(v_s.ptr[3u] & 7u)))) << 8u)); v_y = (((uint32_t)(((uint32_t)(v_y << 1u)) - v_p)) >> 1u); v_s.ptr[0u] = ((uint8_t)((v_y >> 11u))); v_s.ptr[1u] = ((uint8_t)((((v_y >> 19u) & 7u) | 240u))); v_s.ptr[2u] = ((uint8_t)((v_y >> 0u))); v_s.ptr[3u] = ((uint8_t)((((v_y >> 8u) & 7u) | 248u))); v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } self->private_impl.f_bcj_pos = ((uint32_t)(v_p - 4u)); return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_09_sparc WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_09_sparc( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; v_s = a_dst_slice; v_p = self->private_impl.f_bcj_pos; while (((uint64_t)(v_s.len)) >= 4u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 24u) | (((uint32_t)(v_s.ptr[1u])) << 16u) | (((uint32_t)(v_s.ptr[2u])) << 8u) | (((uint32_t)(v_s.ptr[3u])) << 0u)); if (((v_x >> 22u) == 256u) || ((v_x >> 22u) == 511u)) { v_x = (((uint32_t)(((uint32_t)(v_x << 2u)) - v_p)) >> 2u); v_x = ((1073741824u - (v_x & 4194304u)) | 1073741824u | (v_x & 4194303u)); v_s.ptr[0u] = ((uint8_t)((v_x >> 24u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 0u))); } v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } self->private_impl.f_bcj_pos = v_p; return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_0a_arm64 WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_0a_arm64( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; uint32_t v_y = 0; v_s = a_dst_slice; v_p = self->private_impl.f_bcj_pos; while (((uint64_t)(v_s.len)) >= 4u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 0u) | (((uint32_t)(v_s.ptr[1u])) << 8u) | (((uint32_t)(v_s.ptr[2u])) << 16u) | (((uint32_t)(v_s.ptr[3u])) << 24u)); if ((v_x >> 26u) == 37u) { v_y = ((uint32_t)(v_x - (v_p >> 2u))); v_x = (2483027968u | (v_y & 67108863u)); v_s.ptr[0u] = ((uint8_t)((v_x >> 0u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 24u))); } else if ((v_x & 2667577344u) == 2415919104u) { v_y = (((v_x >> 29u) & 3u) | ((v_x >> 3u) & 2097148u)); if ((((uint32_t)(v_y + 131072u)) & 1835008u) == 0u) { v_y -= (v_p >> 12u); v_x &= 2415919135u; v_x |= ((v_y & 3u) << 29u); v_x |= ((v_y & 262140u) << 3u); v_x |= (((uint32_t)(0u - (v_y & 131072u))) & 14680064u); v_s.ptr[0u] = ((uint8_t)((v_x >> 0u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 24u))); } } v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); } self->private_impl.f_bcj_pos = v_p; return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.apply_filter_0b_riscv WUFFS_BASE__GENERATED_C_CODE static uint8_t wuffs_xz__decoder__apply_filter_0b_riscv( wuffs_xz__decoder* self, wuffs_base__slice_u8 a_dst_slice) { wuffs_base__slice_u8 v_s = {0}; uint32_t v_p = 0; uint32_t v_x = 0; uint32_t v_x27 = 0; uint32_t v_y = 0; uint32_t v_addr = 0; v_s = a_dst_slice; v_p = self->private_impl.f_bcj_pos; while (((uint64_t)(v_s.len)) >= 8u) { if (v_s.ptr[0u] == 239u) { if (((uint8_t)(v_s.ptr[1u] & 13u)) != 0u) { v_p += 2u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 2u); continue; } v_addr = ((((uint32_t)(((uint8_t)(v_s.ptr[1u] & 240u)))) << 13u) | (((uint32_t)(v_s.ptr[2u])) << 9u) | (((uint32_t)(v_s.ptr[3u])) << 1u)); v_addr -= v_p; v_s.ptr[1u] = ((uint8_t)(((uint8_t)(v_s.ptr[1u] & 15u)) | ((uint8_t)(((v_addr >> 8u) & 240u))))); v_s.ptr[2u] = ((uint8_t)((((v_addr >> 16u) & 15u) | ((v_addr >> 7u) & 16u) | (((uint32_t)(v_addr << 4u)) & 224u)))); v_s.ptr[3u] = ((uint8_t)((((v_addr >> 4u) & 127u) | ((v_addr >> 13u) & 128u)))); v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); continue; } else if (((uint8_t)(v_s.ptr[0u] & 127u)) == 23u) { v_x = ((((uint32_t)(v_s.ptr[0u])) << 0u) | (((uint32_t)(v_s.ptr[1u])) << 8u) | (((uint32_t)(v_s.ptr[2u])) << 16u) | (((uint32_t)(v_s.ptr[3u])) << 24u)); if ((v_x & 3712u) != 0u) { v_y = ((((uint32_t)(v_s.ptr[4u])) << 0u) | (((uint32_t)(v_s.ptr[5u])) << 8u) | (((uint32_t)(v_s.ptr[6u])) << 16u) | (((uint32_t)(v_s.ptr[7u])) << 24u)); if (((((uint32_t)(v_x << 8u)) ^ ((uint32_t)(v_y - 3u))) & 1015811u) != 0u) { v_p += 6u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 6u); continue; } v_addr = ((v_x & 4294963200u) | (v_y >> 20u)); v_x = (279u | ((uint32_t)(v_y << 12u))); v_s.ptr[0u] = ((uint8_t)((v_x >> 0u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 24u))); v_s.ptr[4u] = ((uint8_t)((v_addr >> 0u))); v_s.ptr[5u] = ((uint8_t)((v_addr >> 8u))); v_s.ptr[6u] = ((uint8_t)((v_addr >> 16u))); v_s.ptr[7u] = ((uint8_t)((v_addr >> 24u))); v_p += 8u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 8u); continue; } v_x27 = (v_x >> 27u); if (((uint32_t)(((uint32_t)(v_x - 12567u)) << 18u)) >= (v_x27 & 29u)) { v_p += 4u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 4u); continue; } v_addr = ((((uint32_t)(v_s.ptr[4u])) << 24u) | (((uint32_t)(v_s.ptr[5u])) << 16u) | (((uint32_t)(v_s.ptr[6u])) << 8u) | (((uint32_t)(v_s.ptr[7u])) << 0u)); v_addr -= v_p; v_y = ((v_x >> 12u) | ((uint32_t)(v_addr << 20u))); v_x = (23u | (v_x27 << 7u) | (((uint32_t)(v_addr + 2048u)) & 4294963200u)); v_s.ptr[0u] = ((uint8_t)((v_x >> 0u))); v_s.ptr[1u] = ((uint8_t)((v_x >> 8u))); v_s.ptr[2u] = ((uint8_t)((v_x >> 16u))); v_s.ptr[3u] = ((uint8_t)((v_x >> 24u))); v_s.ptr[4u] = ((uint8_t)((v_y >> 0u))); v_s.ptr[5u] = ((uint8_t)((v_y >> 8u))); v_s.ptr[6u] = ((uint8_t)((v_y >> 16u))); v_s.ptr[7u] = ((uint8_t)((v_y >> 24u))); v_p += 8u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 8u); continue; } v_p += 2u; v_s = wuffs_base__slice_u8__subslice_i(v_s, 2u); } self->private_impl.f_bcj_pos = v_p; return ((uint8_t)(((uint64_t)(v_s.len)))); } // -------- func xz.decoder.get_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC uint64_t wuffs_xz__decoder__get_quirk( const wuffs_xz__decoder* self, uint32_t a_key) { if (!self) { return 0; } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return 0; } if (a_key == 1u) { if (self->private_impl.f_ignore_checksum) { return 1u; } } else if (a_key == 2021322752u) { if (self->private_impl.f_standalone_format) { return 1u; } } return 0u; } // -------- func xz.decoder.set_quirk WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xz__decoder__set_quirk( wuffs_xz__decoder* self, uint32_t a_key, uint64_t a_value) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (a_key == 1u) { self->private_impl.f_ignore_checksum = (a_value > 0u); return wuffs_base__make_status(NULL); } else if (a_key == 2021322752u) { self->private_impl.f_standalone_format = (a_value > 0u); return wuffs_base__make_status(NULL); } return wuffs_base__make_status(wuffs_base__error__unsupported_option); } // -------- func xz.decoder.dst_history_retain_length WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__optional_u63 wuffs_xz__decoder__dst_history_retain_length( const wuffs_xz__decoder* self) { if (!self) { return wuffs_base__utility__make_optional_u63(false, 0u); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__make_optional_u63(false, 0u); } return wuffs_lzma__decoder__dst_history_retain_length(&self->private_data.f_lzma); } // -------- func xz.decoder.workbuf_len WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__range_ii_u64 wuffs_xz__decoder__workbuf_len( const wuffs_xz__decoder* self) { if (!self) { return wuffs_base__utility__empty_range_ii_u64(); } if ((self->private_impl.magic != WUFFS_BASE__MAGIC) && (self->private_impl.magic != WUFFS_BASE__DISABLED)) { return wuffs_base__utility__empty_range_ii_u64(); } return wuffs_lzma__decoder__workbuf_len(&self->private_data.f_lzma); } // -------- func xz.decoder.transform_io WUFFS_BASE__GENERATED_C_CODE WUFFS_BASE__MAYBE_STATIC wuffs_base__status wuffs_xz__decoder__transform_io( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { if (!self) { return wuffs_base__make_status(wuffs_base__error__bad_receiver); } if (self->private_impl.magic != WUFFS_BASE__MAGIC) { return wuffs_base__make_status( (self->private_impl.magic == WUFFS_BASE__DISABLED) ? wuffs_base__error__disabled_by_previous_error : wuffs_base__error__initialize_not_called); } if (!a_dst || !a_src) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__bad_argument); } if ((self->private_impl.active_coroutine != 0) && (self->private_impl.active_coroutine != 1)) { self->private_impl.magic = WUFFS_BASE__DISABLED; return wuffs_base__make_status(wuffs_base__error__interleaved_coroutine_calls); } self->private_impl.active_coroutine = 0; wuffs_base__status status = wuffs_base__make_status(NULL); wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t coro_susp_point = self->private_impl.p_transform_io; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { wuffs_base__status t_0 = wuffs_xz__decoder__do_transform_io(self, a_dst, a_src, a_workbuf); v_status = t_0; } if ((v_status.repr == wuffs_base__suspension__short_read) && (a_src && a_src->meta.closed)) { status = wuffs_base__make_status(wuffs_xz__error__truncated_input); goto exit; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(1); } ok: self->private_impl.p_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_impl.active_coroutine = wuffs_base__status__is_suspension(&status) ? 1 : 0; goto exit; exit: if (wuffs_base__status__is_error(&status)) { self->private_impl.magic = WUFFS_BASE__DISABLED; } return status; } // -------- func xz.decoder.do_transform_io WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__do_transform_io( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_dst, wuffs_base__io_buffer* a_src, wuffs_base__slice_u8 a_workbuf) { wuffs_base__status status = wuffs_base__make_status(NULL); uint64_t v_header_magic = 0; uint64_t v_dmark = 0; uint64_t v_smark = 0; uint8_t v_i8 = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_checksum32_have = 0; uint32_t v_checksum32_want = 0; uint64_t v_checksum64_have = 0; uint64_t v_checksum64_want = 0; wuffs_base__bitvec256 v_checksum256_have = {0}; uint64_t v_compressed_size = 0; uint64_t v_uncompressed_size = 0; uint32_t v_hash = 0; uint8_t v_c8 = 0; uint32_t v_c32 = 0; uint16_t v_footer_magic = 0; uint8_t* iop_a_dst = NULL; uint8_t* io0_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io1_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; uint8_t* io2_a_dst WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_dst && a_dst->data.ptr) { io0_a_dst = a_dst->data.ptr; io1_a_dst = io0_a_dst + a_dst->meta.wi; iop_a_dst = io1_a_dst; io2_a_dst = io0_a_dst + a_dst->data.len; if (a_dst->meta.closed) { io2_a_dst = iop_a_dst; } } const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_do_transform_io; if (coro_susp_point) { v_checksum32_have = self->private_data.s_do_transform_io.v_checksum32_have; v_checksum32_want = self->private_data.s_do_transform_io.v_checksum32_want; v_checksum256_have = self->private_data.s_do_transform_io.v_checksum256_have; v_compressed_size = self->private_data.s_do_transform_io.v_compressed_size; v_uncompressed_size = self->private_data.s_do_transform_io.v_uncompressed_size; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint64_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 6)) { t_0 = ((uint64_t)(wuffs_base__peek_u48le__no_bounds_check(iop_a_src))); iop_a_src += 6; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 40) { t_0 = ((uint64_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_header_magic = t_0; } if (v_header_magic != 388031461373u) { status = wuffs_base__make_status(wuffs_xz__error__bad_header); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint64_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 6)) { t_1 = ((uint64_t)(wuffs_base__peek_u48le__no_bounds_check(iop_a_src))); iop_a_src += 6; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 40) { t_1 = ((uint64_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_header_magic = t_1; } if (v_header_magic == 72400582410240u) { self->private_impl.f_checksummer = 0u; } else if (v_header_magic == 60327687946496u) { self->private_impl.f_checksummer = 1u; } else if (v_header_magic == 77742513456128u) { self->private_impl.f_checksummer = 2u; } else if (v_header_magic == 177077137508864u) { self->private_impl.f_checksummer = 3u; } else if ((v_header_magic & 61695u) != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_header); goto exit; } else { v_header_magic = (15u & (v_header_magic >> 8u)); if ((v_header_magic != 0u) && (v_header_magic != 1u) && (v_header_magic != 4u) && (v_header_magic != 10u)) { status = wuffs_base__make_status(wuffs_xz__error__unsupported_checksum_algorithm); goto exit; } status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } self->private_impl.f_flags = ((uint16_t)(v_header_magic)); self->private_impl.f_num_actual_blocks = 0u; while (true) { if (((uint64_t)(io2_a_src - iop_a_src)) <= 0u) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(5); continue; } else if (wuffs_base__peek_u8be__no_bounds_check(iop_a_src) == 0u) { break; } self->private_impl.f_num_actual_blocks += 1u; if ( ! self->private_impl.f_ignore_checksum) { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } self->private_impl.f_compressed_size_for_index = 4u; while (true) { v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_2 = wuffs_xz__decoder__decode_block_header_with_padding(self, a_src); v_status = t_2; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_compressed_size_for_index, wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)))); if ( ! self->private_impl.f_ignore_checksum) { v_checksum32_have = wuffs_crc32__ieee_hasher__update_u32(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(6); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); uint32_t t_3; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_3 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_3 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_3; if (num_bits_3 == 24) { t_3 = ((uint32_t)(*scratch)); break; } num_bits_3 += 8u; *scratch |= ((uint64_t)(num_bits_3)) << 56; } } v_checksum32_want = t_3; } if (self->private_impl.f_ignore_checksum) { } else if (v_checksum32_have != v_checksum32_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } else { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_private_impl__ignore_status(wuffs_crc64__ecma_hasher__initialize(&self->private_data.f_crc64, sizeof (wuffs_crc64__ecma_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); wuffs_private_impl__ignore_status(wuffs_sha256__hasher__initialize(&self->private_data.f_sha256, sizeof (wuffs_sha256__hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } v_compressed_size = 0u; v_uncompressed_size = 0u; while (true) { if (((uint64_t)(self->private_impl.f_bcj_undo_index)) > ((uint64_t)(io2_a_dst - iop_a_dst))) { status = wuffs_base__make_status(wuffs_base__suspension__short_write); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(9); continue; } v_dmark = ((uint64_t)(iop_a_dst - io0_a_dst)); v_smark = ((uint64_t)(iop_a_src - io0_a_src)); if (self->private_impl.f_num_non_final_filters == 0u) { { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_4 = wuffs_lzma__decoder__transform_io(&self->private_data.f_lzma, a_dst, a_src, a_workbuf); v_status = t_4; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } } else { if (self->private_impl.f_bcj_undo_index > 0u) { wuffs_private_impl__io_writer__copy_from_slice(&iop_a_dst, io2_a_dst,wuffs_base__make_slice_u8(self->private_data.f_filter_data[0u], self->private_impl.f_bcj_undo_index)); self->private_impl.f_bcj_undo_index = 0u; } { uint8_t* o_0_io0_a_dst = io0_a_dst; uint8_t* o_0_io1_a_dst = io1_a_dst; io0_a_dst = iop_a_dst; io1_a_dst = iop_a_dst; wuffs_base__io_buffer o_0_a_dst; if (a_dst) { memcpy(&o_0_a_dst, a_dst, sizeof(*a_dst)); size_t wi0 = a_dst->meta.wi; a_dst->data.ptr += wi0; a_dst->data.len -= wi0; a_dst->meta.ri = 0; a_dst->meta.wi = 0; a_dst->meta.pos = wuffs_base__u64__sat_add(a_dst->meta.pos, wi0); } { if (a_dst) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_5 = wuffs_lzma__decoder__transform_io(&self->private_data.f_lzma, a_dst, a_src, a_workbuf); v_status = t_5; if (a_dst) { iop_a_dst = a_dst->data.ptr + a_dst->meta.wi; } if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if (a_dst) { memcpy(a_dst, &o_0_a_dst, sizeof(*a_dst)); a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); io0_a_dst = o_0_io0_a_dst; io1_a_dst = o_0_io1_a_dst; } } self->private_impl.f_bcj_undo_index = wuffs_xz__decoder__apply_non_final_filters(self, wuffs_private_impl__io__since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); if ((self->private_impl.f_bcj_undo_index > 0u) && ! wuffs_base__status__is_ok(&v_status)) { v_i8 = ((uint8_t)(self->private_impl.f_bcj_undo_index - 1u)); while (true) { if ( ! (iop_a_dst > io1_a_dst)) { status = wuffs_base__make_status(wuffs_xz__error__internal_error_inconsistent_bcj_filter_state); goto exit; } self->private_data.f_filter_data[0u][v_i8] = iop_a_dst[-1]; iop_a_dst--; if (v_i8 <= 0u) { break; } #if defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif v_i8 -= 1u; #if defined(__GNUC__) #pragma GCC diagnostic pop #endif } } } v_compressed_size += wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src))); v_uncompressed_size += wuffs_private_impl__io__count_since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst))); if (self->private_impl.f_ignore_checksum) { } else if (self->private_impl.f_checksummer == 1u) { wuffs_crc32__ieee_hasher__update(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); } else if (self->private_impl.f_checksummer == 2u) { wuffs_crc64__ecma_hasher__update(&self->private_data.f_crc64, wuffs_private_impl__io__since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); } else if (self->private_impl.f_checksummer == 3u) { wuffs_sha256__hasher__update(&self->private_data.f_sha256, wuffs_private_impl__io__since(v_dmark, ((uint64_t)(iop_a_dst - io0_a_dst)), io0_a_dst)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(10); } if ((self->private_impl.f_block_has_compressed_size && (self->private_impl.f_block_compressed_size != v_compressed_size)) || (self->private_impl.f_block_has_uncompressed_size && (self->private_impl.f_block_uncompressed_size != v_uncompressed_size))) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_compressed_size_for_index, v_compressed_size); wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_compressed_size_for_index, ((uint64_t)(WUFFS_XZ__CHECKSUM_LENGTH[self->private_impl.f_checksummer]))); self->private_impl.f_verification_have_total_sizes[0u] += self->private_impl.f_compressed_size_for_index; v_hash = ((uint32_t)((self->private_impl.f_compressed_size_for_index ^ (self->private_impl.f_compressed_size_for_index >> 32u)))); v_hash *= 3432918353u; v_hash = (((uint32_t)(v_hash << 15u)) | (v_hash >> 17u)); v_hash *= 461845907u; v_hash ^= self->private_impl.f_verification_have_hashed_sizes[0u]; v_hash = (((uint32_t)(v_hash << 13u)) | (v_hash >> 19u)); self->private_impl.f_verification_have_hashed_sizes[0u] = ((uint32_t)(((uint32_t)(v_hash * 5u)) + 3864292196u)); self->private_impl.f_verification_have_total_sizes[1u] += v_uncompressed_size; v_hash = ((uint32_t)((v_uncompressed_size ^ (v_uncompressed_size >> 32u)))); v_hash *= 3432918353u; v_hash = (((uint32_t)(v_hash << 15u)) | (v_hash >> 17u)); v_hash *= 461845907u; v_hash ^= self->private_impl.f_verification_have_hashed_sizes[1u]; v_hash = (((uint32_t)(v_hash << 13u)) | (v_hash >> 19u)); self->private_impl.f_verification_have_hashed_sizes[1u] = ((uint32_t)(((uint32_t)(v_hash * 5u)) + 3864292196u)); while ((v_compressed_size & 3u) != 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_padding); goto exit; } v_compressed_size += 1u; } self->private_impl.f_lzma_needs_reset = true; if (self->private_impl.f_ignore_checksum) { self->private_data.s_do_transform_io.scratch = ((uint32_t)(WUFFS_XZ__CHECKSUM_LENGTH[self->private_impl.f_checksummer])); WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (self->private_data.s_do_transform_io.scratch > ((uint64_t)(io2_a_src - iop_a_src))) { self->private_data.s_do_transform_io.scratch -= ((uint64_t)(io2_a_src - iop_a_src)); iop_a_src = io2_a_src; status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } iop_a_src += self->private_data.s_do_transform_io.scratch; } else if (self->private_impl.f_checksummer == 1u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(13); uint32_t t_7; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_7 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(14); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_7 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_7; if (num_bits_7 == 24) { t_7 = ((uint32_t)(*scratch)); break; } num_bits_7 += 8u; *scratch |= ((uint64_t)(num_bits_7)) << 56; } } v_checksum32_want = t_7; } v_checksum32_have = wuffs_crc32__ieee_hasher__checksum_u32(&self->private_data.f_crc32); if (v_checksum32_have != v_checksum32_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } } else if (self->private_impl.f_checksummer == 2u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(15); uint64_t t_8; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_8 = wuffs_base__peek_u64le__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(16); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_8 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_8; if (num_bits_8 == 56) { t_8 = ((uint64_t)(*scratch)); break; } num_bits_8 += 8u; *scratch |= ((uint64_t)(num_bits_8)) << 56; } } v_checksum64_want = t_8; } v_checksum64_have = wuffs_crc64__ecma_hasher__checksum_u64(&self->private_data.f_crc64); if (v_checksum64_have != v_checksum64_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } } else if (self->private_impl.f_checksummer == 3u) { v_checksum256_have = wuffs_sha256__hasher__checksum_bitvec256(&self->private_data.f_sha256); { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(17); uint64_t t_9; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_9 = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(18); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_9 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_9); if (num_bits_9 == 56) { t_9 = ((uint64_t)(*scratch >> 0)); break; } num_bits_9 += 8u; *scratch |= ((uint64_t)(num_bits_9)); } } v_checksum64_want = t_9; } if (wuffs_base__bitvec256__get_u64(&v_checksum256_have, 3u) != v_checksum64_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(19); uint64_t t_10; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_10 = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(20); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_10 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_10); if (num_bits_10 == 56) { t_10 = ((uint64_t)(*scratch >> 0)); break; } num_bits_10 += 8u; *scratch |= ((uint64_t)(num_bits_10)); } } v_checksum64_want = t_10; } if (wuffs_base__bitvec256__get_u64(&v_checksum256_have, 2u) != v_checksum64_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(21); uint64_t t_11; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_11 = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(22); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_11 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_11); if (num_bits_11 == 56) { t_11 = ((uint64_t)(*scratch >> 0)); break; } num_bits_11 += 8u; *scratch |= ((uint64_t)(num_bits_11)); } } v_checksum64_want = t_11; } if (wuffs_base__bitvec256__get_u64(&v_checksum256_have, 1u) != v_checksum64_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(23); uint64_t t_12; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 8)) { t_12 = wuffs_base__peek_u64be__no_bounds_check(iop_a_src); iop_a_src += 8; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(24); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_12 = ((uint32_t)(*scratch & 0xFFu)); *scratch >>= 8; *scratch <<= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << (56 - num_bits_12); if (num_bits_12 == 56) { t_12 = ((uint64_t)(*scratch >> 0)); break; } num_bits_12 += 8u; *scratch |= ((uint64_t)(num_bits_12)); } } v_checksum64_want = t_12; } if (wuffs_base__bitvec256__get_u64(&v_checksum256_have, 0u) != v_checksum64_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } } } self->private_impl.f_backwards_size = 0u; if ( ! self->private_impl.f_ignore_checksum) { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } while (true) { v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_13 = wuffs_xz__decoder__verify_index(self, a_src); v_status = t_13; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u64__sat_add_indirect(&self->private_impl.f_backwards_size, wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)))); if ( ! self->private_impl.f_ignore_checksum) { wuffs_crc32__ieee_hasher__update(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(25); } if ( ! self->private_impl.f_ignore_checksum) { wuffs_crc32__ieee_hasher__update(&self->private_data.f_crc32, wuffs_base__make_slice_u8(wuffs_base__strip_const_from_u8_ptr(WUFFS_XZ__ZEROES), (3u & ((uint64_t)(0u - (3u & self->private_impl.f_backwards_size)))))); } while ((self->private_impl.f_backwards_size & 3u) != 0u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(26); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_14 = *iop_a_src++; v_c8 = t_14; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } self->private_impl.f_backwards_size += 1u; } self->private_impl.f_backwards_size >>= 2u; if ((self->private_impl.f_backwards_size == 0u) || (self->private_impl.f_backwards_size > 4294967295u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(27); uint32_t t_15; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_15 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(28); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_15 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_15; if (num_bits_15 == 24) { t_15 = ((uint32_t)(*scratch)); break; } num_bits_15 += 8u; *scratch |= ((uint64_t)(num_bits_15)) << 56; } } v_checksum32_want = t_15; } if (self->private_impl.f_ignore_checksum) { } else if (v_checksum32_want != wuffs_crc32__ieee_hasher__checksum_u32(&self->private_data.f_crc32)) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } else { wuffs_private_impl__ignore_status(wuffs_crc32__ieee_hasher__initialize(&self->private_data.f_crc32, sizeof (wuffs_crc32__ieee_hasher), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(29); uint32_t t_16; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_16 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(30); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_16 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_16; if (num_bits_16 == 24) { t_16 = ((uint32_t)(*scratch)); break; } num_bits_16 += 8u; *scratch |= ((uint64_t)(num_bits_16)) << 56; } } v_checksum32_want = t_16; } while (true) { v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_17 = wuffs_xz__decoder__verify_footer(self, a_src); v_status = t_17; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } if ( ! self->private_impl.f_ignore_checksum) { wuffs_crc32__ieee_hasher__update(&self->private_data.f_crc32, wuffs_private_impl__io__since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)), io0_a_src)); } if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(31); } if ( ! self->private_impl.f_ignore_checksum && (v_checksum32_want != wuffs_crc32__ieee_hasher__checksum_u32(&self->private_data.f_crc32))) { status = wuffs_base__make_status(wuffs_xz__error__bad_checksum); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(32); uint16_t t_18; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_18 = wuffs_base__peek_u16le__no_bounds_check(iop_a_src); iop_a_src += 2; } else { self->private_data.s_do_transform_io.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(33); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_do_transform_io.scratch; uint32_t num_bits_18 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_18; if (num_bits_18 == 8) { t_18 = ((uint16_t)(*scratch)); break; } num_bits_18 += 8u; *scratch |= ((uint64_t)(num_bits_18)) << 56; } } v_footer_magic = t_18; } if (v_footer_magic != 23129u) { status = wuffs_base__make_status(wuffs_xz__error__bad_footer); goto exit; } if ( ! self->private_impl.f_standalone_format) { break; } while (true) { while (((uint64_t)(io2_a_src - iop_a_src)) < 4u) { if (a_src && a_src->meta.closed) { if (((uint64_t)(io2_a_src - iop_a_src)) == 0u) { goto label__streams__break; } else { status = wuffs_base__make_status(wuffs_xz__error__truncated_input); goto exit; } } status = wuffs_base__make_status(wuffs_base__suspension__short_read); WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(34); } v_c32 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); if (v_c32 == 1484404733u) { break; } else if (v_c32 != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_header_concatenated_stream); goto exit; } iop_a_src += 4u; } self->private_impl.f_started_verify_index = false; } label__streams__break:; ok: self->private_impl.p_do_transform_io = 0; goto exit; } goto suspend; suspend: self->private_impl.p_do_transform_io = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_do_transform_io.v_checksum32_have = v_checksum32_have; self->private_data.s_do_transform_io.v_checksum32_want = v_checksum32_want; self->private_data.s_do_transform_io.v_checksum256_have = v_checksum256_have; self->private_data.s_do_transform_io.v_compressed_size = v_compressed_size; self->private_data.s_do_transform_io.v_uncompressed_size = v_uncompressed_size; goto exit; exit: if (a_dst && a_dst->data.ptr) { a_dst->meta.wi = ((size_t)(iop_a_dst - a_dst->data.ptr)); } if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func xz.decoder.decode_block_header_with_padding WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__decode_block_header_with_padding( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint64_t v_padded_size_have = 0; uint64_t v_padded_size_want = 0; uint64_t v_smark = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_block_header_with_padding; if (coro_susp_point) { v_padded_size_have = self->private_data.s_decode_block_header_with_padding.v_padded_size_have; v_padded_size_want = self->private_data.s_decode_block_header_with_padding.v_padded_size_want; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } v_padded_size_want = ((uint64_t)((((uint64_t)(v_c8)) * 4u) - 1u)); while (true) { v_smark = ((uint64_t)(iop_a_src - io0_a_src)); { if (a_src) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } wuffs_base__status t_1 = wuffs_xz__decoder__decode_block_header_sans_padding(self, a_src); v_status = t_1; if (a_src) { iop_a_src = a_src->data.ptr + a_src->meta.ri; } } wuffs_private_impl__u64__sat_add_indirect(&v_padded_size_have, wuffs_private_impl__io__count_since(v_smark, ((uint64_t)(iop_a_src - io0_a_src)))); if (wuffs_base__status__is_ok(&v_status)) { break; } status = v_status; WUFFS_BASE__COROUTINE_SUSPENSION_POINT_MAYBE_SUSPEND(2); } if (v_padded_size_have > v_padded_size_want) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } while (v_padded_size_have < v_padded_size_want) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } v_padded_size_have += 1u; } ok: self->private_impl.p_decode_block_header_with_padding = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_block_header_with_padding = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_block_header_with_padding.v_padded_size_have = v_padded_size_have; self->private_data.s_decode_block_header_with_padding.v_padded_size_want = v_padded_size_want; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func xz.decoder.decode_block_header_sans_padding WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__decode_block_header_sans_padding( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_c32 = 0; uint32_t v_alignment = 0; uint8_t v_flags = 0; uint8_t v_filter_id = 0; wuffs_base__status v_status = wuffs_base__make_status(NULL); uint32_t v_shift = 0; uint32_t v_f = 0; uint32_t v_k = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_decode_block_header_sans_padding; if (coro_susp_point) { v_flags = self->private_data.s_decode_block_header_sans_padding.v_flags; v_filter_id = self->private_data.s_decode_block_header_sans_padding.v_filter_id; v_shift = self->private_data.s_decode_block_header_sans_padding.v_shift; v_f = self->private_data.s_decode_block_header_sans_padding.v_f; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_flags = t_0; } self->private_impl.f_num_non_final_filters = ((uint32_t)(((uint8_t)(v_flags & 3u)))); if (((uint8_t)(v_flags & 60u)) != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } self->private_impl.f_block_has_compressed_size = (((uint8_t)(v_flags & 64u)) != 0u); if (self->private_impl.f_block_has_compressed_size) { self->private_impl.f_block_compressed_size = 0u; v_shift = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_shift <= 56u) { self->private_impl.f_block_compressed_size |= (((uint64_t)(((uint8_t)(v_c8 & 127u)))) << v_shift); if (v_c8 >= 128u) { v_shift += 7u; continue; } else if ((v_c8 == 0u) && (v_shift > 0u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } break; } else if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } self->private_impl.f_block_compressed_size |= (((uint64_t)(1u)) << 63u); break; } } self->private_impl.f_block_has_uncompressed_size = (((uint8_t)(v_flags & 128u)) != 0u); if (self->private_impl.f_block_has_uncompressed_size) { self->private_impl.f_block_uncompressed_size = 0u; v_shift = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_shift <= 56u) { self->private_impl.f_block_uncompressed_size |= (((uint64_t)(((uint8_t)(v_c8 & 127u)))) << v_shift); if (v_c8 >= 128u) { v_shift += 7u; continue; } else if ((v_c8 == 0u) && (v_shift > 0u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } break; } else if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_block_header); goto exit; } self->private_impl.f_block_uncompressed_size |= (((uint64_t)(1u)) << 63u); break; } } self->private_impl.f_bcj_x86_prev_mask = 0u; self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_non_final_filters__choosy_default); v_f = 0u; while (v_f < self->private_impl.f_num_non_final_filters) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_filter_id = t_3; } if (v_filter_id == 33u) { status = wuffs_base__make_status(wuffs_xz__error__bad_filter); goto exit; } else if (v_filter_id == 3u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(5); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_4 = *iop_a_src++; v_c8 = t_4; } if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_filter); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(6); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_5 = *iop_a_src++; v_c8 = t_5; } self->private_impl.f_filters[v_f] = ((((uint32_t)(v_c8)) << 8u) | 3u); v_k = 0u; while (v_k < 256u) { self->private_data.f_filter_data[v_f][v_k] = 0u; v_k += 1u; } } else if ((v_filter_id < 3u) || (11u < v_filter_id)) { status = wuffs_base__make_status(wuffs_xz__error__unsupported_filter); goto exit; } else if (v_f != 0u) { status = wuffs_base__make_status(wuffs_xz__error__unsupported_filter_combination); goto exit; } else { self->private_impl.f_filters[v_f] = ((uint32_t)(v_filter_id)); if (v_filter_id == 4u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_04_x86); } else if (v_filter_id == 5u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_05_powerpc); } else if (v_filter_id == 6u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_06_ia64); } else if (v_filter_id == 7u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_07_arm); } else if (v_filter_id == 8u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_08_armthumb); } else if (v_filter_id == 9u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_09_sparc); } else if (v_filter_id == 10u) { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_0a_arm64); } else { self->private_impl.choosy_apply_non_final_filters = ( &wuffs_xz__decoder__apply_filter_0b_riscv); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(7); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_6 = *iop_a_src++; v_c8 = t_6; } if (v_c8 == 0u) { self->private_impl.f_bcj_pos = 0u; } else if (v_c8 == 4u) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(8); uint32_t t_7; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_7 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_decode_block_header_sans_padding.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(9); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_decode_block_header_sans_padding.scratch; uint32_t num_bits_7 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_7; if (num_bits_7 == 24) { t_7 = ((uint32_t)(*scratch)); break; } num_bits_7 += 8u; *scratch |= ((uint64_t)(num_bits_7)) << 56; } } v_c32 = t_7; } v_alignment = ((uint32_t)(WUFFS_XZ__BCJ_OFFSET_ALIGNMENT[v_filter_id])); if (v_alignment > 0u) { if ((v_c32 % v_alignment) != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_bcj_offset); goto exit; } } self->private_impl.f_bcj_pos = v_c32; } else { status = wuffs_base__make_status(wuffs_xz__error__unsupported_filter); goto exit; } } v_f += 1u; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(10); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_8 = *iop_a_src++; v_filter_id = t_8; } if (v_filter_id == 33u) { if (self->private_impl.f_lzma_needs_reset) { wuffs_private_impl__ignore_status(wuffs_lzma__decoder__initialize(&self->private_data.f_lzma, sizeof (wuffs_lzma__decoder), WUFFS_VERSION, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED)); } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(11); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_9 = *iop_a_src++; v_c8 = t_9; } if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_filter); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(12); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_10 = *iop_a_src++; v_c8 = t_10; } v_status = wuffs_lzma__decoder__set_quirk(&self->private_data.f_lzma, 1348001793u, (2u | (((uint64_t)(v_c8)) << 8u))); if ( ! wuffs_base__status__is_ok(&v_status)) { status = wuffs_base__make_status(wuffs_xz__error__bad_filter); goto exit; } } else if ((v_filter_id < 3u) || (11u < v_filter_id)) { status = wuffs_base__make_status(wuffs_xz__error__unsupported_filter); goto exit; } else { status = wuffs_base__make_status(wuffs_xz__error__bad_filter); goto exit; } goto ok; ok: self->private_impl.p_decode_block_header_sans_padding = 0; goto exit; } goto suspend; suspend: self->private_impl.p_decode_block_header_sans_padding = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_decode_block_header_sans_padding.v_flags = v_flags; self->private_data.s_decode_block_header_sans_padding.v_filter_id = v_filter_id; self->private_data.s_decode_block_header_sans_padding.v_shift = v_shift; self->private_data.s_decode_block_header_sans_padding.v_f = v_f; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func xz.decoder.verify_index WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__verify_index( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint8_t v_c8 = 0; uint32_t v_shift = 0; uint32_t v_hash = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_verify_index; if (coro_susp_point) { v_shift = self->private_data.s_verify_index.v_shift; } switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; if ( ! self->private_impl.f_started_verify_index) { self->private_impl.f_started_verify_index = true; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_0 = *iop_a_src++; v_c8 = t_0; } if (v_c8 != 0u) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } self->private_impl.f_num_index_blocks = 0u; v_shift = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_1 = *iop_a_src++; v_c8 = t_1; } if (v_shift <= 56u) { self->private_impl.f_num_index_blocks |= (((uint64_t)(((uint8_t)(v_c8 & 127u)))) << v_shift); if (v_c8 >= 128u) { v_shift += 7u; continue; } else if ((v_c8 == 0u) && (v_shift > 0u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } break; } else if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } self->private_impl.f_num_index_blocks |= (((uint64_t)(1u)) << 63u); break; } if (self->private_impl.f_num_index_blocks != self->private_impl.f_num_actual_blocks) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } } while (self->private_impl.f_num_index_blocks > 0u) { self->private_impl.f_num_index_blocks -= 1u; self->private_impl.f_index_block_compressed_size = 0u; v_shift = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_2 = *iop_a_src++; v_c8 = t_2; } if (v_shift <= 56u) { self->private_impl.f_index_block_compressed_size |= (((uint64_t)(((uint8_t)(v_c8 & 127u)))) << v_shift); if (v_c8 >= 128u) { v_shift += 7u; continue; } else if ((v_c8 == 0u) && (v_shift > 0u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } break; } else if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } self->private_impl.f_index_block_compressed_size |= (((uint64_t)(1u)) << 63u); break; } self->private_impl.f_index_block_uncompressed_size = 0u; v_shift = 0u; while (true) { { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint8_t t_3 = *iop_a_src++; v_c8 = t_3; } if (v_shift <= 56u) { self->private_impl.f_index_block_uncompressed_size |= (((uint64_t)(((uint8_t)(v_c8 & 127u)))) << v_shift); if (v_c8 >= 128u) { v_shift += 7u; continue; } else if ((v_c8 == 0u) && (v_shift > 0u)) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } break; } else if (v_c8 != 1u) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } self->private_impl.f_index_block_uncompressed_size |= (((uint64_t)(1u)) << 63u); break; } self->private_impl.f_verification_want_total_sizes[0u] += self->private_impl.f_index_block_compressed_size; v_hash = ((uint32_t)((self->private_impl.f_index_block_compressed_size ^ (self->private_impl.f_index_block_compressed_size >> 32u)))); v_hash *= 3432918353u; v_hash = (((uint32_t)(v_hash << 15u)) | (v_hash >> 17u)); v_hash *= 461845907u; v_hash ^= self->private_impl.f_verification_want_hashed_sizes[0u]; v_hash = (((uint32_t)(v_hash << 13u)) | (v_hash >> 19u)); self->private_impl.f_verification_want_hashed_sizes[0u] = ((uint32_t)(((uint32_t)(v_hash * 5u)) + 3864292196u)); self->private_impl.f_verification_want_total_sizes[1u] += self->private_impl.f_index_block_uncompressed_size; v_hash = ((uint32_t)((self->private_impl.f_index_block_uncompressed_size ^ (self->private_impl.f_index_block_uncompressed_size >> 32u)))); v_hash *= 3432918353u; v_hash = (((uint32_t)(v_hash << 15u)) | (v_hash >> 17u)); v_hash *= 461845907u; v_hash ^= self->private_impl.f_verification_want_hashed_sizes[1u]; v_hash = (((uint32_t)(v_hash << 13u)) | (v_hash >> 19u)); self->private_impl.f_verification_want_hashed_sizes[1u] = ((uint32_t)(((uint32_t)(v_hash * 5u)) + 3864292196u)); } if ((self->private_impl.f_verification_have_hashed_sizes[0u] != self->private_impl.f_verification_want_hashed_sizes[0u]) || (self->private_impl.f_verification_have_hashed_sizes[1u] != self->private_impl.f_verification_want_hashed_sizes[1u]) || (self->private_impl.f_verification_have_total_sizes[0u] != self->private_impl.f_verification_want_total_sizes[0u]) || (self->private_impl.f_verification_have_total_sizes[1u] != self->private_impl.f_verification_want_total_sizes[1u])) { status = wuffs_base__make_status(wuffs_xz__error__bad_index); goto exit; } goto ok; ok: self->private_impl.p_verify_index = 0; goto exit; } goto suspend; suspend: self->private_impl.p_verify_index = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; self->private_data.s_verify_index.v_shift = v_shift; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } // -------- func xz.decoder.verify_footer WUFFS_BASE__GENERATED_C_CODE static wuffs_base__status wuffs_xz__decoder__verify_footer( wuffs_xz__decoder* self, wuffs_base__io_buffer* a_src) { wuffs_base__status status = wuffs_base__make_status(NULL); uint32_t v_c32 = 0; const uint8_t* iop_a_src = NULL; const uint8_t* io0_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io1_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; const uint8_t* io2_a_src WUFFS_BASE__POTENTIALLY_UNUSED = NULL; if (a_src && a_src->data.ptr) { io0_a_src = a_src->data.ptr; io1_a_src = io0_a_src + a_src->meta.ri; iop_a_src = io1_a_src; io2_a_src = io0_a_src + a_src->meta.wi; } uint32_t coro_susp_point = self->private_impl.p_verify_footer; switch (coro_susp_point) { WUFFS_BASE__COROUTINE_SUSPENSION_POINT_0; { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(1); uint32_t t_0; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 4)) { t_0 = wuffs_base__peek_u32le__no_bounds_check(iop_a_src); iop_a_src += 4; } else { self->private_data.s_verify_footer.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(2); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_verify_footer.scratch; uint32_t num_bits_0 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_0; if (num_bits_0 == 24) { t_0 = ((uint32_t)(*scratch)); break; } num_bits_0 += 8u; *scratch |= ((uint64_t)(num_bits_0)) << 56; } } v_c32 = t_0; } if (v_c32 != ((uint32_t)(self->private_impl.f_backwards_size))) { status = wuffs_base__make_status(wuffs_xz__error__bad_footer); goto exit; } { WUFFS_BASE__COROUTINE_SUSPENSION_POINT(3); uint32_t t_1; if (WUFFS_BASE__LIKELY(io2_a_src - iop_a_src >= 2)) { t_1 = ((uint32_t)(wuffs_base__peek_u16le__no_bounds_check(iop_a_src))); iop_a_src += 2; } else { self->private_data.s_verify_footer.scratch = 0; WUFFS_BASE__COROUTINE_SUSPENSION_POINT(4); while (true) { if (WUFFS_BASE__UNLIKELY(iop_a_src == io2_a_src)) { status = wuffs_base__make_status(wuffs_base__suspension__short_read); goto suspend; } uint64_t* scratch = &self->private_data.s_verify_footer.scratch; uint32_t num_bits_1 = ((uint32_t)(*scratch >> 56)); *scratch <<= 8; *scratch >>= 8; *scratch |= ((uint64_t)(*iop_a_src++)) << num_bits_1; if (num_bits_1 == 8) { t_1 = ((uint32_t)(*scratch)); break; } num_bits_1 += 8u; *scratch |= ((uint64_t)(num_bits_1)) << 56; } } v_c32 = t_1; } if (v_c32 != ((uint32_t)(self->private_impl.f_flags))) { status = wuffs_base__make_status(wuffs_xz__error__bad_footer); goto exit; } goto ok; ok: self->private_impl.p_verify_footer = 0; goto exit; } goto suspend; suspend: self->private_impl.p_verify_footer = wuffs_base__status__is_suspension(&status) ? coro_susp_point : 0; goto exit; exit: if (a_src && a_src->data.ptr) { a_src->meta.ri = ((size_t)(iop_a_src - a_src->data.ptr)); } return status; } #endif // !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__XZ) #if defined(__cplusplus) && defined(WUFFS_BASE__HAVE_UNIQUE_PTR) // ---------------- Auxiliary - Base // Auxiliary code is discussed at // https://github.com/google/wuffs/blob/main/doc/note/auxiliary-code.md #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__AUX__BASE) namespace wuffs_aux { namespace sync_io { // -------- DynIOBuffer::DynIOBuffer(uint64_t max_incl) : m_buf(wuffs_base__empty_io_buffer()), m_max_incl(max_incl) {} DynIOBuffer::~DynIOBuffer() { free(m_buf.data.ptr); } void // DynIOBuffer::drop() { free(m_buf.data.ptr); m_buf = wuffs_base__empty_io_buffer(); } DynIOBuffer::GrowResult // DynIOBuffer::grow(uint64_t min_incl) { uint64_t n = round_up(min_incl, m_max_incl); if (n == 0) { return ((min_incl == 0) && (m_max_incl == 0)) ? DynIOBuffer::GrowResult::OK : DynIOBuffer::GrowResult::FailedMaxInclExceeded; } else if (n > SIZE_MAX) { return DynIOBuffer::GrowResult::FailedOutOfMemory; } else if (n > m_buf.data.len) { uint8_t* ptr = static_cast(realloc(m_buf.data.ptr, static_cast(n))); if (!ptr) { return DynIOBuffer::GrowResult::FailedOutOfMemory; } m_buf.data.ptr = ptr; m_buf.data.len = static_cast(n); } return DynIOBuffer::GrowResult::OK; } // round_up rounds min_incl up, returning the smallest value x satisfying // (min_incl <= x) and (x <= max_incl) and some other constraints. It returns 0 // if there is no such x. // // When max_incl <= 4096, the other constraints are: // - (x == max_incl) // // When max_incl > 4096, the other constraints are: // - (x == max_incl) or (x is a power of 2) // - (x >= 4096) uint64_t // DynIOBuffer::round_up(uint64_t min_incl, uint64_t max_incl) { if (min_incl > max_incl) { return 0; } uint64_t n = 4096; if (n >= max_incl) { return max_incl; } while (n < min_incl) { if (n >= (max_incl / 2)) { return max_incl; } n *= 2; } return n; } // -------- Input::~Input() {} IOBuffer* // Input::BringsItsOwnIOBuffer() { return nullptr; } // -------- FileInput::FileInput(FILE* f) : m_f(f) {} std::string // FileInput::CopyIn(IOBuffer* dst) { if (!m_f) { return "wuffs_aux::sync_io::FileInput: nullptr file"; } else if (!dst) { return "wuffs_aux::sync_io::FileInput: nullptr IOBuffer"; } else if (dst->meta.closed) { return "wuffs_aux::sync_io::FileInput: end of file"; } else { dst->compact(); size_t n = fread(dst->writer_pointer(), 1, dst->writer_length(), m_f); dst->meta.wi += n; dst->meta.closed = feof(m_f); if (ferror(m_f)) { return "wuffs_aux::sync_io::FileInput: error reading file"; } } return ""; } // -------- MemoryInput::MemoryInput(const char* ptr, size_t len) : m_io(wuffs_base__ptr_u8__reader( static_cast(static_cast(const_cast(ptr))), len, true)) {} MemoryInput::MemoryInput(const uint8_t* ptr, size_t len) : m_io(wuffs_base__ptr_u8__reader(const_cast(ptr), len, true)) {} IOBuffer* // MemoryInput::BringsItsOwnIOBuffer() { return &m_io; } std::string // MemoryInput::CopyIn(IOBuffer* dst) { if (!dst) { return "wuffs_aux::sync_io::MemoryInput: nullptr IOBuffer"; } else if (dst->meta.closed) { return "wuffs_aux::sync_io::MemoryInput: end of file"; } else if (wuffs_base__slice_u8__overlaps(dst->data, m_io.data)) { // Treat m_io's data as immutable, so don't compact dst or otherwise write // to it. return "wuffs_aux::sync_io::MemoryInput: overlapping buffers"; } else { dst->compact(); size_t nd = dst->writer_length(); size_t ns = m_io.reader_length(); size_t n = (nd < ns) ? nd : ns; memcpy(dst->writer_pointer(), m_io.reader_pointer(), n); m_io.meta.ri += n; dst->meta.wi += n; dst->meta.closed = m_io.reader_length() == 0; } return ""; } // -------- } // namespace sync_io namespace private_impl { struct ErrorMessages { const char* max_incl_metadata_length_exceeded; const char* out_of_memory; const char* unexpected_end_of_file; const char* unsupported_metadata; const char* unsupported_negative_advance; // If adding new "const char*" typed fields to this struct, either add them // after existing fields or, if re-ordering fields, make sure that you update // all of the "const private_impl::ErrorMessages FooBarErrorMessages" values // in all of the sibling *.cc files. static inline const char* resolve(const char* s) { return s ? s : "wuffs_aux::private_impl: unknown error"; }; }; std::string // AdvanceIOBufferTo(const ErrorMessages& error_messages, sync_io::Input& input, IOBuffer& io_buf, uint64_t absolute_position) { if (absolute_position < io_buf.reader_position()) { return error_messages.resolve(error_messages.unsupported_negative_advance); } while (true) { uint64_t relative_position = absolute_position - io_buf.reader_position(); if (relative_position <= io_buf.reader_length()) { io_buf.meta.ri += (size_t)relative_position; break; } else if (io_buf.meta.closed) { return error_messages.resolve(error_messages.unexpected_end_of_file); } io_buf.meta.ri = io_buf.meta.wi; if (!input.BringsItsOwnIOBuffer()) { io_buf.compact(); } std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return error_message; } } return ""; } std::string // HandleMetadata( const ErrorMessages& error_messages, sync_io::Input& input, wuffs_base__io_buffer& io_buf, sync_io::DynIOBuffer& raw, wuffs_base__status (*tell_me_more_func)(void*, wuffs_base__io_buffer*, wuffs_base__more_information*, wuffs_base__io_buffer*), void* tell_me_more_receiver, std::string (*handle_metadata_func)(void*, const wuffs_base__more_information*, wuffs_base__slice_u8), void* handle_metadata_receiver) { wuffs_base__more_information minfo = wuffs_base__empty_more_information(); // Reset raw but keep its backing array (the raw.m_buf.data slice). raw.m_buf.meta = wuffs_base__empty_io_buffer_meta(); while (true) { minfo = wuffs_base__empty_more_information(); wuffs_base__status status = (*tell_me_more_func)( tell_me_more_receiver, &raw.m_buf, &minfo, &io_buf); switch (minfo.flavor) { case 0: case WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_RAW_TRANSFORM: case WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_PARSED: break; case WUFFS_BASE__MORE_INFORMATION__FLAVOR__METADATA_RAW_PASSTHROUGH: { wuffs_base__range_ie_u64 r = minfo.metadata_raw_passthrough__range(); if (r.is_empty()) { break; } uint64_t num_to_copy = r.length(); if (num_to_copy > (raw.m_max_incl - raw.m_buf.meta.wi)) { return error_messages.resolve( error_messages.max_incl_metadata_length_exceeded); } else if (num_to_copy > (raw.m_buf.data.len - raw.m_buf.meta.wi)) { switch (raw.grow(num_to_copy + raw.m_buf.meta.wi)) { case sync_io::DynIOBuffer::GrowResult::OK: break; case sync_io::DynIOBuffer::GrowResult::FailedMaxInclExceeded: return error_messages.resolve( error_messages.max_incl_metadata_length_exceeded); case sync_io::DynIOBuffer::GrowResult::FailedOutOfMemory: return error_messages.resolve(error_messages.out_of_memory); } } if (io_buf.reader_position() > r.min_incl) { return error_messages.resolve(error_messages.unsupported_metadata); } else { std::string error_message = AdvanceIOBufferTo(error_messages, input, io_buf, r.min_incl); if (!error_message.empty()) { return error_message; } } while (true) { uint64_t n = wuffs_base__u64__min(num_to_copy, io_buf.reader_length()); memcpy(raw.m_buf.writer_pointer(), io_buf.reader_pointer(), n); raw.m_buf.meta.wi += n; io_buf.meta.ri += n; num_to_copy -= n; if (num_to_copy == 0) { break; } else if (io_buf.meta.closed) { return error_messages.resolve( error_messages.unexpected_end_of_file); } else if (!input.BringsItsOwnIOBuffer()) { io_buf.compact(); } std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return error_message; } } break; } default: return error_messages.resolve(error_messages.unsupported_metadata); } if (status.repr == nullptr) { break; } else if (status.repr != wuffs_base__suspension__even_more_information) { if (status.repr != wuffs_base__suspension__short_write) { return status.message(); } switch (raw.grow(wuffs_base__u64__sat_add(raw.m_buf.data.len, 1))) { case sync_io::DynIOBuffer::GrowResult::OK: break; case sync_io::DynIOBuffer::GrowResult::FailedMaxInclExceeded: return error_messages.resolve( error_messages.max_incl_metadata_length_exceeded); case sync_io::DynIOBuffer::GrowResult::FailedOutOfMemory: return error_messages.resolve(error_messages.out_of_memory); } } } return (*handle_metadata_func)(handle_metadata_receiver, &minfo, raw.m_buf.reader_slice()); } } // namespace private_impl } // namespace wuffs_aux #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__AUX__BASE) // ---------------- Auxiliary - CBOR #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__AUX__CBOR) #include namespace wuffs_aux { DecodeCborResult::DecodeCborResult(std::string&& error_message0, uint64_t cursor_position0) : error_message(std::move(error_message0)), cursor_position(cursor_position0) {} DecodeCborCallbacks::~DecodeCborCallbacks() {} void // DecodeCborCallbacks::Done(DecodeCborResult& result, sync_io::Input& input, IOBuffer& buffer) {} DecodeCborArgQuirks::DecodeCborArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0) : ptr(ptr0), len(len0) {} DecodeCborArgQuirks // DecodeCborArgQuirks::DefaultValue() { return DecodeCborArgQuirks(nullptr, 0); } DecodeCborResult // DecodeCbor(DecodeCborCallbacks& callbacks, sync_io::Input& input, DecodeCborArgQuirks quirks) { // Prepare the wuffs_base__io_buffer and the resultant error_message. wuffs_base__io_buffer* io_buf = input.BringsItsOwnIOBuffer(); wuffs_base__io_buffer fallback_io_buf = wuffs_base__empty_io_buffer(); std::unique_ptr fallback_io_array(nullptr); if (!io_buf) { fallback_io_array = std::unique_ptr(new uint8_t[4096]); fallback_io_buf = wuffs_base__ptr_u8__writer(fallback_io_array.get(), 4096); io_buf = &fallback_io_buf; } // cursor_index is discussed at // https://nigeltao.github.io/blog/2020/jsonptr.html#the-cursor-index size_t cursor_index = 0; std::string ret_error_message; std::string io_error_message; do { // Prepare the low-level CBOR decoder. wuffs_cbor__decoder::unique_ptr dec = wuffs_cbor__decoder::alloc(); if (!dec) { ret_error_message = "wuffs_aux::DecodeCbor: out of memory"; goto done; } for (size_t i = 0; i < quirks.len; i++) { dec->set_quirk(quirks.ptr[i].first, quirks.ptr[i].second); } // Prepare the wuffs_base__tok_buffer. 256 tokens is 2KiB. wuffs_base__token tok_array[256]; wuffs_base__token_buffer tok_buf = wuffs_base__slice_token__writer(wuffs_base__make_slice_token( &tok_array[0], (sizeof(tok_array) / sizeof(tok_array[0])))); wuffs_base__status tok_status = wuffs_base__make_status(nullptr); // Prepare other state. int32_t depth = 0; std::string str; int64_t extension_category = 0; uint64_t extension_detail = 0; // Valid token's VBCs range in 0 ..= 15. Values over that are for tokens // from outside of the base package, such as the CBOR package. constexpr int64_t EXT_CAT__CBOR_TAG = 16; // Loop, doing these two things: // 1. Get the next token. // 2. Process that token. while (true) { // 1. Get the next token. while (tok_buf.meta.ri >= tok_buf.meta.wi) { if (tok_status.repr == nullptr) { // No-op. } else if (tok_status.repr == wuffs_base__suspension__short_write) { tok_buf.compact(); } else if (tok_status.repr == wuffs_base__suspension__short_read) { // Read from input to io_buf. if (!io_error_message.empty()) { ret_error_message = std::move(io_error_message); goto done; } else if (cursor_index != io_buf->meta.ri) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad cursor_index"; goto done; } else if (io_buf->meta.closed) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: io_buf is closed"; goto done; } io_buf->compact(); if (io_buf->meta.wi >= io_buf->data.len) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: io_buf is full"; goto done; } cursor_index = io_buf->meta.ri; io_error_message = input.CopyIn(io_buf); } else { ret_error_message = tok_status.message(); goto done; } if (WUFFS_CBOR__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE != 0) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad WORKBUF_LEN"; goto done; } wuffs_base__slice_u8 work_buf = wuffs_base__empty_slice_u8(); tok_status = dec->decode_tokens(&tok_buf, io_buf, work_buf); if ((tok_buf.meta.ri > tok_buf.meta.wi) || (tok_buf.meta.wi > tok_buf.data.len) || (io_buf->meta.ri > io_buf->meta.wi) || (io_buf->meta.wi > io_buf->data.len)) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad buffer indexes"; goto done; } } wuffs_base__token token = tok_buf.data.ptr[tok_buf.meta.ri++]; uint64_t token_len = token.length(); if ((io_buf->meta.ri < cursor_index) || ((io_buf->meta.ri - cursor_index) < token_len)) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad token indexes"; goto done; } uint8_t* token_ptr = io_buf->data.ptr + cursor_index; cursor_index += static_cast(token_len); // 2. Process that token. uint64_t vbd = token.value_base_detail(); if (extension_category != 0) { int64_t ext = token.value_extension(); if ((ext >= 0) && !token.continued()) { extension_detail = (extension_detail << WUFFS_BASE__TOKEN__VALUE_EXTENSION__NUM_BITS) | static_cast(ext); switch (extension_category) { case WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_SIGNED: extension_category = 0; ret_error_message = callbacks.AppendI64(static_cast(extension_detail)); goto parsed_a_value; case WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_UNSIGNED: extension_category = 0; ret_error_message = callbacks.AppendU64(extension_detail); goto parsed_a_value; case EXT_CAT__CBOR_TAG: extension_category = 0; ret_error_message = callbacks.AppendCborTag(extension_detail); if (!ret_error_message.empty()) { goto done; } continue; } } ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad extended token"; goto done; } switch (token.value_base_category()) { case WUFFS_BASE__TOKEN__VBC__FILLER: continue; case WUFFS_BASE__TOKEN__VBC__STRUCTURE: { if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH) { ret_error_message = callbacks.Push(static_cast(vbd)); if (!ret_error_message.empty()) { goto done; } depth++; if (depth > (int32_t)WUFFS_CBOR__DECODER_DEPTH_MAX_INCL) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad depth"; goto done; } continue; } ret_error_message = callbacks.Pop(static_cast(vbd)); depth--; if (depth < 0) { ret_error_message = "wuffs_aux::DecodeCbor: internal error: bad depth"; goto done; } goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__STRING: { if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_0_DST_1_SRC_DROP) { // No-op. } else if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_1_SRC_COPY) { const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(token_ptr)); str.append(ptr, static_cast(token_len)); } else { goto fail; } if (token.continued()) { continue; } ret_error_message = (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CHAIN_MUST_BE_UTF_8) ? callbacks.AppendTextString(std::move(str)) : callbacks.AppendByteString(std::move(str)); str.clear(); goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__UNICODE_CODE_POINT: { uint8_t u[WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL]; size_t n = wuffs_base__utf_8__encode( wuffs_base__make_slice_u8( &u[0], WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL), static_cast(vbd)); const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(&u[0])); str.append(ptr, n); if (token.continued()) { continue; } goto fail; } case WUFFS_BASE__TOKEN__VBC__LITERAL: { if (vbd & WUFFS_BASE__TOKEN__VBD__LITERAL__NULL) { ret_error_message = callbacks.AppendNull(); } else if (vbd & WUFFS_BASE__TOKEN__VBD__LITERAL__UNDEFINED) { ret_error_message = callbacks.AppendUndefined(); } else { ret_error_message = callbacks.AppendBool( vbd & WUFFS_BASE__TOKEN__VBD__LITERAL__TRUE); } goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__NUMBER: { const uint64_t cfp_fbbe_fifb = WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_FLOATING_POINT | WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_BINARY_BIG_ENDIAN | WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_IGNORE_FIRST_BYTE; if ((vbd & cfp_fbbe_fifb) == cfp_fbbe_fifb) { double f; switch (token_len) { case 3: f = wuffs_base__ieee_754_bit_representation__from_u16_to_f64( wuffs_base__peek_u16be__no_bounds_check(token_ptr + 1)); break; case 5: f = wuffs_base__ieee_754_bit_representation__from_u32_to_f64( wuffs_base__peek_u32be__no_bounds_check(token_ptr + 1)); break; case 9: f = wuffs_base__ieee_754_bit_representation__from_u64_to_f64( wuffs_base__peek_u64be__no_bounds_check(token_ptr + 1)); break; default: goto fail; } ret_error_message = callbacks.AppendF64(f); goto parsed_a_value; } goto fail; } case WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_SIGNED: { if (token.continued()) { extension_category = WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_SIGNED; extension_detail = static_cast(token.value_base_detail__sign_extended()); continue; } ret_error_message = callbacks.AppendI64(token.value_base_detail__sign_extended()); goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_UNSIGNED: { if (token.continued()) { extension_category = WUFFS_BASE__TOKEN__VBC__INLINE_INTEGER_UNSIGNED; extension_detail = vbd; continue; } ret_error_message = callbacks.AppendU64(vbd); goto parsed_a_value; } } if (token.value_major() == WUFFS_CBOR__TOKEN_VALUE_MAJOR) { uint64_t value_minor = token.value_minor(); if (value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__MINUS_1_MINUS_X) { if (token_len == 9) { ret_error_message = callbacks.AppendMinus1MinusX( wuffs_base__peek_u64be__no_bounds_check(token_ptr + 1)); goto parsed_a_value; } } else if (value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__SIMPLE_VALUE) { ret_error_message = callbacks.AppendCborSimpleValue(static_cast( value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__DETAIL_MASK)); goto parsed_a_value; } else if (value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__TAG) { if (token.continued()) { extension_category = EXT_CAT__CBOR_TAG; extension_detail = value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__DETAIL_MASK; continue; } ret_error_message = callbacks.AppendCborTag( value_minor & WUFFS_CBOR__TOKEN_VALUE_MINOR__DETAIL_MASK); if (!ret_error_message.empty()) { goto done; } continue; } } fail: ret_error_message = "wuffs_aux::DecodeCbor: internal error: unexpected token"; goto done; parsed_a_value: if (!ret_error_message.empty() || (depth == 0)) { goto done; } } } while (false); done: DecodeCborResult result( std::move(ret_error_message), wuffs_base__u64__sat_add(io_buf->meta.pos, cursor_index)); callbacks.Done(result, input, *io_buf); return result; } } // namespace wuffs_aux #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__AUX__CBOR) // ---------------- Auxiliary - Image #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__AUX__IMAGE) #include namespace wuffs_aux { DecodeImageResult::DecodeImageResult(MemOwner&& pixbuf_mem_owner0, wuffs_base__pixel_buffer pixbuf0, std::string&& error_message0) : pixbuf_mem_owner(std::move(pixbuf_mem_owner0)), pixbuf(pixbuf0), error_message(std::move(error_message0)) {} DecodeImageResult::DecodeImageResult(std::string&& error_message0) : pixbuf_mem_owner(nullptr, &free), pixbuf(wuffs_base__null_pixel_buffer()), error_message(std::move(error_message0)) {} DecodeImageCallbacks::~DecodeImageCallbacks() {} DecodeImageCallbacks::AllocPixbufResult::AllocPixbufResult( MemOwner&& mem_owner0, wuffs_base__pixel_buffer pixbuf0) : mem_owner(std::move(mem_owner0)), pixbuf(pixbuf0), error_message("") {} DecodeImageCallbacks::AllocPixbufResult::AllocPixbufResult( std::string&& error_message0) : mem_owner(nullptr, &free), pixbuf(wuffs_base__null_pixel_buffer()), error_message(std::move(error_message0)) {} DecodeImageCallbacks::AllocWorkbufResult::AllocWorkbufResult( MemOwner&& mem_owner0, wuffs_base__slice_u8 workbuf0) : mem_owner(std::move(mem_owner0)), workbuf(workbuf0), error_message("") {} DecodeImageCallbacks::AllocWorkbufResult::AllocWorkbufResult( std::string&& error_message0) : mem_owner(nullptr, &free), workbuf(wuffs_base__empty_slice_u8()), error_message(std::move(error_message0)) {} wuffs_base__image_decoder::unique_ptr // DecodeImageCallbacks::SelectDecoder(uint32_t fourcc, wuffs_base__slice_u8 prefix_data, bool prefix_closed) { switch (fourcc) { #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__BMP) case WUFFS_BASE__FOURCC__BMP: return wuffs_bmp__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__GIF) case WUFFS_BASE__FOURCC__GIF: return wuffs_gif__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__JPEG) case WUFFS_BASE__FOURCC__JPEG: return wuffs_jpeg__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NIE) case WUFFS_BASE__FOURCC__NIE: return wuffs_nie__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__NETPBM) case WUFFS_BASE__FOURCC__NPBM: return wuffs_netpbm__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__PNG) case WUFFS_BASE__FOURCC__PNG: { auto dec = wuffs_png__decoder::alloc_as__wuffs_base__image_decoder(); // Favor faster decodes over rejecting invalid checksums. dec->set_quirk(WUFFS_BASE__QUIRK_IGNORE_CHECKSUM, 1); return dec; } #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__QOI) case WUFFS_BASE__FOURCC__QOI: return wuffs_qoi__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__TGA) case WUFFS_BASE__FOURCC__TGA: return wuffs_tga__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WBMP) case WUFFS_BASE__FOURCC__WBMP: return wuffs_wbmp__decoder::alloc_as__wuffs_base__image_decoder(); #endif #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__WEBP) case WUFFS_BASE__FOURCC__WEBP: return wuffs_webp__decoder::alloc_as__wuffs_base__image_decoder(); #endif } return wuffs_base__image_decoder::unique_ptr(nullptr); } std::string // DecodeImageCallbacks::HandleMetadata(const wuffs_base__more_information& minfo, wuffs_base__slice_u8 raw) { return ""; } wuffs_base__pixel_format // DecodeImageCallbacks::SelectPixfmt( const wuffs_base__image_config& image_config) { return wuffs_base__make_pixel_format(WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL); } DecodeImageCallbacks::AllocPixbufResult // DecodeImageCallbacks::AllocPixbuf(const wuffs_base__image_config& image_config, bool allow_uninitialized_memory) { uint32_t w = image_config.pixcfg.width(); uint32_t h = image_config.pixcfg.height(); if ((w == 0) || (h == 0)) { return AllocPixbufResult(""); } uint64_t len = image_config.pixcfg.pixbuf_len(); if ((len == 0) || (SIZE_MAX < len)) { return AllocPixbufResult(DecodeImage_UnsupportedPixelConfiguration); } void* ptr = allow_uninitialized_memory ? malloc((size_t)len) : calloc(1, (size_t)len); if (!ptr) { return AllocPixbufResult(DecodeImage_OutOfMemory); } wuffs_base__pixel_buffer pixbuf; wuffs_base__status status = pixbuf.set_from_slice( &image_config.pixcfg, wuffs_base__make_slice_u8((uint8_t*)ptr, (size_t)len)); if (!status.is_ok()) { free(ptr); return AllocPixbufResult(status.message()); } return AllocPixbufResult(MemOwner(ptr, &free), pixbuf); } DecodeImageCallbacks::AllocWorkbufResult // DecodeImageCallbacks::AllocWorkbuf(wuffs_base__range_ii_u64 len_range, bool allow_uninitialized_memory) { uint64_t len = len_range.max_incl; if (len == 0) { return AllocWorkbufResult(""); } else if (SIZE_MAX < len) { return AllocWorkbufResult(DecodeImage_OutOfMemory); } void* ptr = allow_uninitialized_memory ? malloc((size_t)len) : calloc(1, (size_t)len); if (!ptr) { return AllocWorkbufResult(DecodeImage_OutOfMemory); } return AllocWorkbufResult( MemOwner(ptr, &free), wuffs_base__make_slice_u8((uint8_t*)ptr, (size_t)len)); } void // DecodeImageCallbacks::Done( DecodeImageResult& result, sync_io::Input& input, IOBuffer& buffer, wuffs_base__image_decoder::unique_ptr image_decoder) {} const char DecodeImage_BufferIsTooShort[] = // "wuffs_aux::DecodeImage: buffer is too short"; const char DecodeImage_MaxInclDimensionExceeded[] = // "wuffs_aux::DecodeImage: max_incl_dimension exceeded"; const char DecodeImage_MaxInclMetadataLengthExceeded[] = // "wuffs_aux::DecodeImage: max_incl_metadata_length exceeded"; const char DecodeImage_OutOfMemory[] = // "wuffs_aux::DecodeImage: out of memory"; const char DecodeImage_UnexpectedEndOfFile[] = // "wuffs_aux::DecodeImage: unexpected end of file"; const char DecodeImage_UnsupportedImageFormat[] = // "wuffs_aux::DecodeImage: unsupported image format"; const char DecodeImage_UnsupportedMetadata[] = // "wuffs_aux::DecodeImage: unsupported metadata"; const char DecodeImage_UnsupportedPixelBlend[] = // "wuffs_aux::DecodeImage: unsupported pixel blend"; const char DecodeImage_UnsupportedPixelConfiguration[] = // "wuffs_aux::DecodeImage: unsupported pixel configuration"; const char DecodeImage_UnsupportedPixelFormat[] = // "wuffs_aux::DecodeImage: unsupported pixel format"; DecodeImageArgQuirks::DecodeImageArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0) : ptr(ptr0), len(len0) {} DecodeImageArgQuirks // DecodeImageArgQuirks::DefaultValue() { return DecodeImageArgQuirks(nullptr, 0); } DecodeImageArgFlags::DecodeImageArgFlags(uint64_t repr0) : repr(repr0) {} DecodeImageArgFlags // DecodeImageArgFlags::DefaultValue() { return DecodeImageArgFlags(0); } DecodeImageArgPixelBlend::DecodeImageArgPixelBlend( wuffs_base__pixel_blend repr0) : repr(repr0) {} DecodeImageArgPixelBlend // DecodeImageArgPixelBlend::DefaultValue() { return DecodeImageArgPixelBlend(WUFFS_BASE__PIXEL_BLEND__SRC); } DecodeImageArgBackgroundColor::DecodeImageArgBackgroundColor( wuffs_base__color_u32_argb_premul repr0) : repr(repr0) {} DecodeImageArgBackgroundColor // DecodeImageArgBackgroundColor::DefaultValue() { return DecodeImageArgBackgroundColor(1); } DecodeImageArgMaxInclDimension::DecodeImageArgMaxInclDimension(uint32_t repr0) : repr(repr0) {} DecodeImageArgMaxInclDimension // DecodeImageArgMaxInclDimension::DefaultValue() { return DecodeImageArgMaxInclDimension(1048575); } DecodeImageArgMaxInclMetadataLength::DecodeImageArgMaxInclMetadataLength( uint64_t repr0) : repr(repr0) {} DecodeImageArgMaxInclMetadataLength // DecodeImageArgMaxInclMetadataLength::DefaultValue() { return DecodeImageArgMaxInclMetadataLength(16777215); } // -------- namespace { const private_impl::ErrorMessages DecodeImageErrorMessages = { DecodeImage_MaxInclMetadataLengthExceeded, // DecodeImage_OutOfMemory, // DecodeImage_UnexpectedEndOfFile, // DecodeImage_UnsupportedMetadata, // DecodeImage_UnsupportedImageFormat, // }; std::string // DecodeImageAdvanceIOBufferTo(sync_io::Input& input, wuffs_base__io_buffer& io_buf, uint64_t absolute_position) { return private_impl::AdvanceIOBufferTo(DecodeImageErrorMessages, input, io_buf, absolute_position); } wuffs_base__status // DIHM0(void* self, wuffs_base__io_buffer* a_dst, wuffs_base__more_information* a_minfo, wuffs_base__io_buffer* a_src) { return wuffs_base__image_decoder__tell_me_more( static_cast(self), a_dst, a_minfo, a_src); } std::string // DIHM1(void* self, const wuffs_base__more_information* minfo, wuffs_base__slice_u8 raw) { return static_cast(self)->HandleMetadata(*minfo, raw); } std::string // DecodeImageHandleMetadata(wuffs_base__image_decoder::unique_ptr& image_decoder, DecodeImageCallbacks& callbacks, sync_io::Input& input, wuffs_base__io_buffer& io_buf, sync_io::DynIOBuffer& raw_metadata_buf) { return private_impl::HandleMetadata(DecodeImageErrorMessages, input, io_buf, raw_metadata_buf, DIHM0, static_cast(image_decoder.get()), DIHM1, static_cast(&callbacks)); } DecodeImageResult // DecodeImage0(wuffs_base__image_decoder::unique_ptr& image_decoder, DecodeImageCallbacks& callbacks, sync_io::Input& input, wuffs_base__io_buffer& io_buf, const QuirkKeyValuePair* quirks_ptr, const size_t quirks_len, uint64_t flags, wuffs_base__pixel_blend pixel_blend, wuffs_base__color_u32_argb_premul background_color, uint32_t max_incl_dimension, uint64_t max_incl_metadata_length) { // Check args. switch (pixel_blend) { case WUFFS_BASE__PIXEL_BLEND__SRC: case WUFFS_BASE__PIXEL_BLEND__SRC_OVER: break; default: return DecodeImageResult(DecodeImage_UnsupportedPixelBlend); } wuffs_base__image_config image_config = wuffs_base__null_image_config(); sync_io::DynIOBuffer raw_metadata_buf(max_incl_metadata_length); uint64_t start_pos = io_buf.reader_position(); bool interested_in_metadata_after_the_frame = false; bool redirected = false; int32_t fourcc = 0; redirect: do { // Determine the image format. if (!redirected) { while (true) { fourcc = wuffs_base__magic_number_guess_fourcc(io_buf.reader_slice(), io_buf.meta.closed); if (fourcc > 0) { break; } else if ((fourcc == 0) && (io_buf.reader_length() >= 64)) { // Having (fourcc == 0) means that Wuffs' built in MIME sniffer // didn't recognize the image format. Nonetheless, custom callbacks // may still be able to do their own MIME sniffing, for exotic image // types. We try to give them at least 64 bytes of prefix data when // one-shot-calling callbacks.SelectDecoder. There is no mechanism // for the callbacks to request a longer prefix. break; } else if (io_buf.meta.closed || (io_buf.writer_length() == 0)) { fourcc = 0; break; } std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } } else { wuffs_base__io_buffer empty = wuffs_base__empty_io_buffer(); wuffs_base__more_information minfo = wuffs_base__empty_more_information(); wuffs_base__status tmm_status = image_decoder->tell_me_more(&empty, &minfo, &io_buf); if (tmm_status.repr != nullptr) { return DecodeImageResult(tmm_status.message()); } if (minfo.flavor != WUFFS_BASE__MORE_INFORMATION__FLAVOR__IO_REDIRECT) { return DecodeImageResult(DecodeImage_UnsupportedImageFormat); } uint64_t pos = minfo.io_redirect__range().min_incl; if (pos <= start_pos) { // Redirects must go forward. return DecodeImageResult(DecodeImage_UnsupportedImageFormat); } std::string error_message = DecodeImageAdvanceIOBufferTo(input, io_buf, pos); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } fourcc = (int32_t)(minfo.io_redirect__fourcc()); if (fourcc == 0) { return DecodeImageResult(DecodeImage_UnsupportedImageFormat); } image_decoder.reset(); } // Select the image decoder. image_decoder = callbacks.SelectDecoder( (uint32_t)fourcc, io_buf.reader_slice(), io_buf.meta.closed); if (!image_decoder) { return DecodeImageResult(DecodeImage_UnsupportedImageFormat); } // Apply quirks. for (size_t i = 0; i < quirks_len; i++) { image_decoder->set_quirk(quirks_ptr[i].first, quirks_ptr[i].second); } // Apply flags. if (flags != 0) { if (flags & DecodeImageArgFlags::REPORT_METADATA_CHRM) { image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__CHRM, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_EXIF) { interested_in_metadata_after_the_frame = true; image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__EXIF, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_GAMA) { image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__GAMA, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_ICCP) { image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__ICCP, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_KVP) { interested_in_metadata_after_the_frame = true; image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__KVP, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_SRGB) { image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__SRGB, true); } if (flags & DecodeImageArgFlags::REPORT_METADATA_XMP) { interested_in_metadata_after_the_frame = true; image_decoder->set_report_metadata(WUFFS_BASE__FOURCC__XMP, true); } } // Decode the image config. while (true) { wuffs_base__status id_dic_status = image_decoder->decode_image_config(&image_config, &io_buf); if (id_dic_status.repr == nullptr) { break; } else if (id_dic_status.repr == wuffs_base__note__i_o_redirect) { if (redirected) { return DecodeImageResult(DecodeImage_UnsupportedImageFormat); } redirected = true; goto redirect; } else if (id_dic_status.repr == wuffs_base__note__metadata_reported) { std::string error_message = DecodeImageHandleMetadata( image_decoder, callbacks, input, io_buf, raw_metadata_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } else if (id_dic_status.repr != wuffs_base__suspension__short_read) { return DecodeImageResult(id_dic_status.message()); } else if (io_buf.meta.closed) { return DecodeImageResult(DecodeImage_UnexpectedEndOfFile); } else { std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } } } while (false); if (!interested_in_metadata_after_the_frame) { raw_metadata_buf.drop(); } // Select the pixel format. uint32_t w = image_config.pixcfg.width(); uint32_t h = image_config.pixcfg.height(); if ((w > max_incl_dimension) || (h > max_incl_dimension)) { return DecodeImageResult(DecodeImage_MaxInclDimensionExceeded); } wuffs_base__pixel_format pixel_format = callbacks.SelectPixfmt(image_config); if (pixel_format.repr != image_config.pixcfg.pixel_format().repr) { switch (pixel_format.repr) { case WUFFS_BASE__PIXEL_FORMAT__BGR_565: case WUFFS_BASE__PIXEL_FORMAT__BGR: case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__BGRA_NONPREMUL_4X16LE: case WUFFS_BASE__PIXEL_FORMAT__BGRA_PREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGB: case WUFFS_BASE__PIXEL_FORMAT__RGBA_NONPREMUL: case WUFFS_BASE__PIXEL_FORMAT__RGBA_PREMUL: break; default: return DecodeImageResult(DecodeImage_UnsupportedPixelFormat); } image_config.pixcfg.set(pixel_format.repr, WUFFS_BASE__PIXEL_SUBSAMPLING__NONE, w, h); } // Allocate the pixel buffer. bool valid_background_color = wuffs_base__color_u32_argb_premul__is_valid(background_color); DecodeImageCallbacks::AllocPixbufResult alloc_pixbuf_result = callbacks.AllocPixbuf(image_config, valid_background_color); if (!alloc_pixbuf_result.error_message.empty()) { return DecodeImageResult(std::move(alloc_pixbuf_result.error_message)); } wuffs_base__pixel_buffer pixel_buffer = alloc_pixbuf_result.pixbuf; if (valid_background_color) { wuffs_base__status pb_scufr_status = pixel_buffer.set_color_u32_fill_rect( pixel_buffer.pixcfg.bounds(), background_color); if (pb_scufr_status.repr != nullptr) { return DecodeImageResult(pb_scufr_status.message()); } } // Allocate the work buffer. Wuffs' decoders conventionally assume that this // can be uninitialized memory. wuffs_base__range_ii_u64 workbuf_len = image_decoder->workbuf_len(); DecodeImageCallbacks::AllocWorkbufResult alloc_workbuf_result = callbacks.AllocWorkbuf(workbuf_len, true); if (!alloc_workbuf_result.error_message.empty()) { return DecodeImageResult(std::move(alloc_workbuf_result.error_message)); } else if (alloc_workbuf_result.workbuf.len < workbuf_len.min_incl) { return DecodeImageResult(DecodeImage_BufferIsTooShort); } // Decode the frame config. wuffs_base__frame_config frame_config = wuffs_base__null_frame_config(); while (true) { wuffs_base__status id_dfc_status = image_decoder->decode_frame_config(&frame_config, &io_buf); if (id_dfc_status.repr == nullptr) { break; } else if (id_dfc_status.repr == wuffs_base__note__metadata_reported) { std::string error_message = DecodeImageHandleMetadata( image_decoder, callbacks, input, io_buf, raw_metadata_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } else if (id_dfc_status.repr != wuffs_base__suspension__short_read) { return DecodeImageResult(id_dfc_status.message()); } else if (io_buf.meta.closed) { return DecodeImageResult(DecodeImage_UnexpectedEndOfFile); } else { std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } } // Decode the frame (the pixels). // // From here on, always returns the pixel_buffer. If we get this far, we can // still display a partial image, even if we encounter an error. std::string message(""); if ((pixel_blend == WUFFS_BASE__PIXEL_BLEND__SRC_OVER) && frame_config.overwrite_instead_of_blend()) { pixel_blend = WUFFS_BASE__PIXEL_BLEND__SRC; } while (true) { wuffs_base__status id_df_status = image_decoder->decode_frame(&pixel_buffer, &io_buf, pixel_blend, alloc_workbuf_result.workbuf, nullptr); if (id_df_status.repr == nullptr) { break; } else if (id_df_status.repr != wuffs_base__suspension__short_read) { message = id_df_status.message(); break; } else if (io_buf.meta.closed) { message = DecodeImage_UnexpectedEndOfFile; break; } else { std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { message = std::move(error_message); break; } } } // Decode any metadata after the frame. if (interested_in_metadata_after_the_frame) { while (true) { wuffs_base__status id_dfc_status = image_decoder->decode_frame_config(NULL, &io_buf); if (id_dfc_status.repr == wuffs_base__note__end_of_data) { break; } else if (id_dfc_status.repr == nullptr) { continue; } else if (id_dfc_status.repr == wuffs_base__note__metadata_reported) { std::string error_message = DecodeImageHandleMetadata( image_decoder, callbacks, input, io_buf, raw_metadata_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } else if (id_dfc_status.repr != wuffs_base__suspension__short_read) { return DecodeImageResult(id_dfc_status.message()); } else if (io_buf.meta.closed) { return DecodeImageResult(DecodeImage_UnexpectedEndOfFile); } else { std::string error_message = input.CopyIn(&io_buf); if (!error_message.empty()) { return DecodeImageResult(std::move(error_message)); } } } } return DecodeImageResult(std::move(alloc_pixbuf_result.mem_owner), pixel_buffer, std::move(message)); } } // namespace DecodeImageResult // DecodeImage(DecodeImageCallbacks& callbacks, sync_io::Input& input, DecodeImageArgQuirks quirks, DecodeImageArgFlags flags, DecodeImageArgPixelBlend pixel_blend, DecodeImageArgBackgroundColor background_color, DecodeImageArgMaxInclDimension max_incl_dimension, DecodeImageArgMaxInclMetadataLength max_incl_metadata_length) { wuffs_base__io_buffer* io_buf = input.BringsItsOwnIOBuffer(); wuffs_base__io_buffer fallback_io_buf = wuffs_base__empty_io_buffer(); std::unique_ptr fallback_io_array(nullptr); if (!io_buf) { fallback_io_array = std::unique_ptr(new uint8_t[32768]); fallback_io_buf = wuffs_base__ptr_u8__writer(fallback_io_array.get(), 32768); io_buf = &fallback_io_buf; } wuffs_base__image_decoder::unique_ptr image_decoder(nullptr); DecodeImageResult result = DecodeImage0( image_decoder, callbacks, input, *io_buf, quirks.ptr, quirks.len, flags.repr, pixel_blend.repr, background_color.repr, max_incl_dimension.repr, max_incl_metadata_length.repr); callbacks.Done(result, input, *io_buf, std::move(image_decoder)); return result; } } // namespace wuffs_aux #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__AUX__IMAGE) // ---------------- Auxiliary - JSON #if !defined(WUFFS_CONFIG__MODULES) || defined(WUFFS_CONFIG__MODULE__AUX__JSON) #include namespace wuffs_aux { DecodeJsonResult::DecodeJsonResult(std::string&& error_message0, uint64_t cursor_position0) : error_message(std::move(error_message0)), cursor_position(cursor_position0) {} DecodeJsonCallbacks::~DecodeJsonCallbacks() {} void // DecodeJsonCallbacks::Done(DecodeJsonResult& result, sync_io::Input& input, IOBuffer& buffer) {} const char DecodeJson_BadJsonPointer[] = // "wuffs_aux::DecodeJson: bad JSON Pointer"; const char DecodeJson_NoMatch[] = // "wuffs_aux::DecodeJson: no match"; DecodeJsonArgQuirks::DecodeJsonArgQuirks(const QuirkKeyValuePair* ptr0, const size_t len0) : ptr(ptr0), len(len0) {} DecodeJsonArgQuirks // DecodeJsonArgQuirks::DefaultValue() { return DecodeJsonArgQuirks(nullptr, 0); } DecodeJsonArgJsonPointer::DecodeJsonArgJsonPointer(std::string repr0) : repr(repr0) {} DecodeJsonArgJsonPointer // DecodeJsonArgJsonPointer::DefaultValue() { return DecodeJsonArgJsonPointer(std::string()); } // -------- #define WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN \ while (tok_buf.meta.ri >= tok_buf.meta.wi) { \ if (tok_status.repr == nullptr) { \ goto done; \ } else if (tok_status.repr == wuffs_base__suspension__short_write) { \ tok_buf.compact(); \ } else if (tok_status.repr == wuffs_base__suspension__short_read) { \ if (!io_error_message.empty()) { \ ret_error_message = std::move(io_error_message); \ goto done; \ } else if (cursor_index != io_buf->meta.ri) { \ ret_error_message = \ "wuffs_aux::DecodeJson: internal error: bad cursor_index"; \ goto done; \ } else if (io_buf->meta.closed) { \ ret_error_message = \ "wuffs_aux::DecodeJson: internal error: io_buf is closed"; \ goto done; \ } \ io_buf->compact(); \ if (io_buf->meta.wi >= io_buf->data.len) { \ ret_error_message = \ "wuffs_aux::DecodeJson: internal error: io_buf is full"; \ goto done; \ } \ cursor_index = io_buf->meta.ri; \ io_error_message = input.CopyIn(io_buf); \ } else { \ ret_error_message = tok_status.message(); \ goto done; \ } \ tok_status = \ dec->decode_tokens(&tok_buf, io_buf, wuffs_base__empty_slice_u8()); \ if ((tok_buf.meta.ri > tok_buf.meta.wi) || \ (tok_buf.meta.wi > tok_buf.data.len) || \ (io_buf->meta.ri > io_buf->meta.wi) || \ (io_buf->meta.wi > io_buf->data.len)) { \ ret_error_message = \ "wuffs_aux::DecodeJson: internal error: bad buffer indexes"; \ goto done; \ } \ } \ wuffs_base__token token = tok_buf.data.ptr[tok_buf.meta.ri++]; \ uint64_t token_len = token.length(); \ if ((io_buf->meta.ri < cursor_index) || \ ((io_buf->meta.ri - cursor_index) < token_len)) { \ ret_error_message = \ "wuffs_aux::DecodeJson: internal error: bad token indexes"; \ goto done; \ } \ uint8_t* token_ptr = io_buf->data.ptr + cursor_index; \ (void)(token_ptr); \ cursor_index += static_cast(token_len) // -------- namespace { // DecodeJson_SplitJsonPointer returns ("bar", 8) for ("/foo/bar/b~1z/qux", 5, // etc). It returns a 0 size_t when s has invalid JSON Pointer syntax or i is // out of bounds. // // The string returned is unescaped. If calling it again, this time with i=8, // the "b~1z" substring would be returned as "b/z". std::pair // DecodeJson_SplitJsonPointer(std::string& s, size_t i, bool allow_tilde_n_tilde_r_tilde_t) { std::string fragment; if (i > s.size()) { return std::make_pair(std::string(), 0); } while (i < s.size()) { char c = s[i]; if (c == '/') { break; } else if (c != '~') { fragment.push_back(c); i++; continue; } i++; if (i >= s.size()) { return std::make_pair(std::string(), 0); } c = s[i]; if (c == '0') { fragment.push_back('~'); i++; continue; } else if (c == '1') { fragment.push_back('/'); i++; continue; } else if (allow_tilde_n_tilde_r_tilde_t) { if (c == 'n') { fragment.push_back('\n'); i++; continue; } else if (c == 'r') { fragment.push_back('\r'); i++; continue; } else if (c == 't') { fragment.push_back('\t'); i++; continue; } } return std::make_pair(std::string(), 0); } return std::make_pair(std::move(fragment), i); } // -------- std::string // DecodeJson_WalkJsonPointerFragment(wuffs_base__token_buffer& tok_buf, wuffs_base__status& tok_status, wuffs_json__decoder::unique_ptr& dec, wuffs_base__io_buffer* io_buf, std::string& io_error_message, size_t& cursor_index, sync_io::Input& input, std::string& json_pointer_fragment) { std::string ret_error_message; while (true) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); if (vbc == WUFFS_BASE__TOKEN__VBC__FILLER) { continue; } else if ((vbc != WUFFS_BASE__TOKEN__VBC__STRUCTURE) || !(vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH)) { return DecodeJson_NoMatch; } else if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__TO_LIST) { goto do_list; } goto do_dict; } do_dict: // Alternate between these two things: // 1. Decode the next dict key (a string). If it matches the fragment, we're // done (success). If we've reached the dict's end (VBD__STRUCTURE__POP) // so that there was no next dict key, we're done (failure). // 2. Otherwise, skip the next dict value. while (true) { for (std::string str; true;) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); switch (vbc) { case WUFFS_BASE__TOKEN__VBC__FILLER: continue; case WUFFS_BASE__TOKEN__VBC__STRUCTURE: if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH) { goto fail; } return DecodeJson_NoMatch; case WUFFS_BASE__TOKEN__VBC__STRING: { if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_0_DST_1_SRC_DROP) { // No-op. } else if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_1_SRC_COPY) { const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(token_ptr)); str.append(ptr, static_cast(token_len)); } else { goto fail; } break; } case WUFFS_BASE__TOKEN__VBC__UNICODE_CODE_POINT: { uint8_t u[WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL]; size_t n = wuffs_base__utf_8__encode( wuffs_base__make_slice_u8( &u[0], WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL), static_cast(vbd)); const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(&u[0])); str.append(ptr, n); break; } default: goto fail; } if (token.continued()) { continue; } if (str == json_pointer_fragment) { return ""; } goto skip_the_next_dict_value; } skip_the_next_dict_value: for (uint32_t skip_depth = 0; true;) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); if (token.continued() || (vbc == WUFFS_BASE__TOKEN__VBC__FILLER)) { continue; } else if (vbc == WUFFS_BASE__TOKEN__VBC__STRUCTURE) { if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH) { skip_depth++; continue; } skip_depth--; } if (skip_depth == 0) { break; } } // skip_the_next_dict_value } // do_dict do_list: do { wuffs_base__result_u64 result_u64 = wuffs_base__parse_number_u64( wuffs_base__make_slice_u8( static_cast(static_cast( const_cast(json_pointer_fragment.data()))), json_pointer_fragment.size()), WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS); if (!result_u64.status.is_ok()) { return DecodeJson_NoMatch; } uint64_t remaining = result_u64.value; if (remaining == 0) { goto check_that_a_value_follows; } for (uint32_t skip_depth = 0; true;) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); if (token.continued() || (vbc == WUFFS_BASE__TOKEN__VBC__FILLER)) { continue; } else if (vbc == WUFFS_BASE__TOKEN__VBC__STRUCTURE) { if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH) { skip_depth++; continue; } if (skip_depth == 0) { return DecodeJson_NoMatch; } skip_depth--; } if (skip_depth > 0) { continue; } remaining--; if (remaining == 0) { goto check_that_a_value_follows; } } } while (false); // do_list check_that_a_value_follows: while (true) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); if (vbc == WUFFS_BASE__TOKEN__VBC__FILLER) { continue; } // Undo the last part of WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN, so // that we're only peeking at the next token. tok_buf.meta.ri--; cursor_index -= static_cast(token_len); if ((vbc == WUFFS_BASE__TOKEN__VBC__STRUCTURE) && (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__POP)) { return DecodeJson_NoMatch; } return ""; } // check_that_a_value_follows fail: return "wuffs_aux::DecodeJson: internal error: unexpected token"; done: return ret_error_message; } } // namespace // -------- DecodeJsonResult // DecodeJson(DecodeJsonCallbacks& callbacks, sync_io::Input& input, DecodeJsonArgQuirks quirks, DecodeJsonArgJsonPointer json_pointer) { // Prepare the wuffs_base__io_buffer and the resultant error_message. wuffs_base__io_buffer* io_buf = input.BringsItsOwnIOBuffer(); wuffs_base__io_buffer fallback_io_buf = wuffs_base__empty_io_buffer(); std::unique_ptr fallback_io_array(nullptr); if (!io_buf) { fallback_io_array = std::unique_ptr(new uint8_t[4096]); fallback_io_buf = wuffs_base__ptr_u8__writer(fallback_io_array.get(), 4096); io_buf = &fallback_io_buf; } // cursor_index is discussed at // https://nigeltao.github.io/blog/2020/jsonptr.html#the-cursor-index size_t cursor_index = 0; std::string ret_error_message; std::string io_error_message; do { // Prepare the low-level JSON decoder. wuffs_json__decoder::unique_ptr dec = wuffs_json__decoder::alloc(); if (!dec) { ret_error_message = "wuffs_aux::DecodeJson: out of memory"; goto done; } else if (WUFFS_JSON__DECODER_WORKBUF_LEN_MAX_INCL_WORST_CASE != 0) { ret_error_message = "wuffs_aux::DecodeJson: internal error: bad WORKBUF_LEN"; goto done; } bool allow_tilde_n_tilde_r_tilde_t = false; for (size_t i = 0; i < quirks.len; i++) { dec->set_quirk(quirks.ptr[i].first, quirks.ptr[i].second); if (quirks.ptr[i].first == WUFFS_JSON__QUIRK_JSON_POINTER_ALLOW_TILDE_N_TILDE_R_TILDE_T) { allow_tilde_n_tilde_r_tilde_t = (quirks.ptr[i].second != 0); } } // Prepare the wuffs_base__tok_buffer. 256 tokens is 2KiB. wuffs_base__token tok_array[256]; wuffs_base__token_buffer tok_buf = wuffs_base__slice_token__writer(wuffs_base__make_slice_token( &tok_array[0], (sizeof(tok_array) / sizeof(tok_array[0])))); wuffs_base__status tok_status = dec->decode_tokens(&tok_buf, io_buf, wuffs_base__empty_slice_u8()); // Prepare other state. int32_t depth = 0; std::string str; // Walk the (optional) JSON Pointer. for (size_t i = 0; i < json_pointer.repr.size();) { if (json_pointer.repr[i] != '/') { ret_error_message = DecodeJson_BadJsonPointer; goto done; } std::pair split = DecodeJson_SplitJsonPointer( json_pointer.repr, i + 1, allow_tilde_n_tilde_r_tilde_t); i = split.second; if (i == 0) { ret_error_message = DecodeJson_BadJsonPointer; goto done; } ret_error_message = DecodeJson_WalkJsonPointerFragment( tok_buf, tok_status, dec, io_buf, io_error_message, cursor_index, input, split.first); if (!ret_error_message.empty()) { goto done; } } // Loop, doing these two things: // 1. Get the next token. // 2. Process that token. while (true) { WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN; int64_t vbc = token.value_base_category(); uint64_t vbd = token.value_base_detail(); switch (vbc) { case WUFFS_BASE__TOKEN__VBC__FILLER: continue; case WUFFS_BASE__TOKEN__VBC__STRUCTURE: { if (vbd & WUFFS_BASE__TOKEN__VBD__STRUCTURE__PUSH) { ret_error_message = callbacks.Push(static_cast(vbd)); if (!ret_error_message.empty()) { goto done; } depth++; if (depth > (int32_t)WUFFS_JSON__DECODER_DEPTH_MAX_INCL) { ret_error_message = "wuffs_aux::DecodeJson: internal error: bad depth"; goto done; } continue; } ret_error_message = callbacks.Pop(static_cast(vbd)); depth--; if (depth < 0) { ret_error_message = "wuffs_aux::DecodeJson: internal error: bad depth"; goto done; } goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__STRING: { if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_0_DST_1_SRC_DROP) { // No-op. } else if (vbd & WUFFS_BASE__TOKEN__VBD__STRING__CONVERT_1_DST_1_SRC_COPY) { const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(token_ptr)); str.append(ptr, static_cast(token_len)); } else { goto fail; } if (token.continued()) { continue; } ret_error_message = callbacks.AppendTextString(std::move(str)); str.clear(); goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__UNICODE_CODE_POINT: { uint8_t u[WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL]; size_t n = wuffs_base__utf_8__encode( wuffs_base__make_slice_u8( &u[0], WUFFS_BASE__UTF_8__BYTE_LENGTH__MAX_INCL), static_cast(vbd)); const char* ptr = // Convert from (uint8_t*). static_cast(static_cast(&u[0])); str.append(ptr, n); if (token.continued()) { continue; } goto fail; } case WUFFS_BASE__TOKEN__VBC__LITERAL: { ret_error_message = (vbd & WUFFS_BASE__TOKEN__VBD__LITERAL__NULL) ? callbacks.AppendNull() : callbacks.AppendBool(vbd & WUFFS_BASE__TOKEN__VBD__LITERAL__TRUE); goto parsed_a_value; } case WUFFS_BASE__TOKEN__VBC__NUMBER: { if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__FORMAT_TEXT) { if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_INTEGER_SIGNED) { wuffs_base__result_i64 r = wuffs_base__parse_number_i64( wuffs_base__make_slice_u8(token_ptr, static_cast(token_len)), WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS); if (r.status.is_ok()) { ret_error_message = callbacks.AppendI64(r.value); goto parsed_a_value; } } if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_FLOATING_POINT) { wuffs_base__result_f64 r = wuffs_base__parse_number_f64( wuffs_base__make_slice_u8(token_ptr, static_cast(token_len)), WUFFS_BASE__PARSE_NUMBER_XXX__DEFAULT_OPTIONS); if (r.status.is_ok()) { ret_error_message = callbacks.AppendF64(r.value); goto parsed_a_value; } } } else if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_NEG_INF) { ret_error_message = callbacks.AppendF64( wuffs_base__ieee_754_bit_representation__from_u64_to_f64( 0xFFF0000000000000ul)); goto parsed_a_value; } else if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_POS_INF) { ret_error_message = callbacks.AppendF64( wuffs_base__ieee_754_bit_representation__from_u64_to_f64( 0x7FF0000000000000ul)); goto parsed_a_value; } else if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_NEG_NAN) { ret_error_message = callbacks.AppendF64( wuffs_base__ieee_754_bit_representation__from_u64_to_f64( 0xFFFFFFFFFFFFFFFFul)); goto parsed_a_value; } else if (vbd & WUFFS_BASE__TOKEN__VBD__NUMBER__CONTENT_POS_NAN) { ret_error_message = callbacks.AppendF64( wuffs_base__ieee_754_bit_representation__from_u64_to_f64( 0x7FFFFFFFFFFFFFFFul)); goto parsed_a_value; } goto fail; } } fail: ret_error_message = "wuffs_aux::DecodeJson: internal error: unexpected token"; goto done; parsed_a_value: // If an error was encountered, we are done. Otherwise, (depth == 0) // after parsing a value is equivalent to having decoded the entire JSON // value (for an empty json_pointer query) or having decoded the // pointed-to JSON value (for a non-empty json_pointer query). In the // latter case, we are also done. // // However, if quirks like WUFFS_JSON__QUIRK_ALLOW_TRAILING_FILLER or // WUFFS_JSON__QUIRK_EXPECT_TRAILING_NEW_LINE_OR_EOF are passed, decoding // the entire JSON value should also consume any trailing filler, in case // the DecodeJson caller wants to subsequently check that the input is // completely exhausted (and otherwise raise "valid JSON followed by // further (unexpected) data"). We aren't done yet. Instead, keep the // loop running until WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN's // decode_tokens returns an ok status. if (!ret_error_message.empty() || ((depth == 0) && !json_pointer.repr.empty())) { goto done; } } } while (false); done: DecodeJsonResult result( std::move(ret_error_message), wuffs_base__u64__sat_add(io_buf->meta.pos, cursor_index)); callbacks.Done(result, input, *io_buf); return result; } #undef WUFFS_AUX__DECODE_JSON__GET_THE_NEXT_TOKEN } // namespace wuffs_aux #endif // !defined(WUFFS_CONFIG__MODULES) || // defined(WUFFS_CONFIG__MODULE__AUX__JSON) #endif // defined(__cplusplus) && defined(WUFFS_BASE__HAVE_UNIQUE_PTR) #endif // WUFFS_IMPLEMENTATION #if defined(__GNUC__) #pragma GCC diagnostic pop #elif defined(__clang__) #pragma clang diagnostic pop #endif #endif // WUFFS_INCLUDE_GUARD