From 2e200cde9a58a64f3df5f1c69dcdd57ef9452c3d Mon Sep 17 00:00:00 2001 From: Stefan Reinauer Date: Tue, 30 Oct 2012 14:02:45 -0700 Subject: cbfstool: Update LZMA encoder to LZMA SDK 9.12 This removes almost all C++ code (except the wrapper) Change-Id: I0f84070e3b6dc57c98d49a53150a140479b3221f Signed-off-by: Stefan Reinauer Reviewed-on: http://review.coreboot.org/1799 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich --- util/cbfstool/lzma/lzma.cc | 842 +++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 842 insertions(+) create mode 100644 util/cbfstool/lzma/lzma.cc (limited to 'util/cbfstool/lzma/lzma.cc') diff --git a/util/cbfstool/lzma/lzma.cc b/util/cbfstool/lzma/lzma.cc new file mode 100644 index 0000000000..4e555ff23e --- /dev/null +++ b/util/cbfstool/lzma/lzma.cc @@ -0,0 +1,842 @@ +#include "endian.hh" /* For R64 */ + +extern "C" { +#include "C/LzmaDec.h" +#include "C/LzmaEnc.h" +} + +#include "lzma.hh" + +#include // min,max,swap +#include +#include +#include // std::memcpy + + +#include + +#include + +/* We don't want threads */ +#ifdef linux +#include +#define ForceSwitchThread() sched_yield() +#else +#define ForceSwitchThread() +#endif + + +int LZMA_verbose = 0; + +// -fb +unsigned LZMA_NumFastBytes = 273; +/*from lzma.txt: + Set number of fast bytes - [5, 273], default: 273 + Usually big number gives a little bit better compression ratio + and slower compression process. + from anonymous: +This one is hard to explain... To my knowledge (please correct me if I +am wrong), this refers to the optimal parsing algorithm. The algorithm +tries many different combinations of matches to find the best one. If a +match is found that is over the fb value, then it will not be optimised, +and will just be used straight. +This speeds up corner cases such as pic. +*/ + +/* apparently, 0 and 1 are valid values. 0 = fast mode */ +unsigned LZMA_AlgorithmNo = 1; + +unsigned LZMA_MatchFinderCycles = 0; // default: 0 + +// -pb +unsigned LZMA_PosStateBits = 0; // default: 2, range: 0..4 +/*from lzma.txt: + pb switch is intended for periodical data + when period is equal 2^N. +*/ + + +// -lp +unsigned LZMA_LiteralPosStateBits = 0; // default: 0, range: 0..4 +/*from lzma.txt: + lp switch is intended for periodical data when period is + equal 2^N. For example, for 32-bit (4 bytes) + periodical data you can use lp=2. + Often it's better to set lc0, if you change lp switch. +*/ + +// -lc +unsigned LZMA_LiteralContextBits = 1; // default: 3, range: 0..8 +/*from lzma.txt: + Sometimes lc=4 gives gain for big files. + from anonymous: +The context for the literal coder is 2^(lc) long. The longer it is, the +better the statistics, but also the slower it adapts. A tradeoff, which +is why 3 or 4 is reccommended. +*/ + +/* + +Discoveries: + + INODES: + Best LZMA for raw_inotab_inode(40->48): pb0 lp0 lc0 + Best LZMA for raw_root_inode(28->32): pb0 lp0 lc0 + + Start LZMA(rootdir, 736 bytes) + Yay result with pb0 lp0 lc0: 218 + Yay result with pb0 lp0 lc1: 217 + Best LZMA for rootdir(736->217): pb0 lp0 lc1 + + Start LZMA(inotab, 379112 bytes) + Yay result with pb0 lp0 lc0: 24504 + Best LZMA for inotab(379112->24504): pb0 lp0 lc0 + + BLKTAB: + Best LZMA for raw_blktab(10068->2940): pb2 lp2 lc0 + + ---with fastbytes=128--- + Start LZMA(blktab, 12536608 bytes) + Yay result with pb0 lp0 lc0: 1386141 + Yay result with pb0 lp1 lc0: 1308137 + Yay result with pb0 lp2 lc0: 1305403 + Yay result with pb0 lp3 lc0: 1303072 + Yay result with pb1 lp1 lc0: 1238990 + Yay result with pb1 lp2 lc0: 1227973 + Yay result with pb1 lp3 lc0: 1221205 + Yay result with pb2 lp1 lc0: 1197035 + Yay result with pb2 lp2 lc0: 1188979 + Yay result with pb2 lp3 lc0: 1184531 + Yay result with pb3 lp1 lc0: 1183866 + Yay result with pb3 lp2 lc0: 1172994 + Yay result with pb3 lp3 lc0: 1169048 + Best LZMA for blktab(12536608->1169048): pb3 lp3 lc0 + + It seems, lc=0 and pb=lp=N is a wise choice, + where N is 2 for packed blktab and 3 for unpacked. + + FBLOCKS: + For SPC sound+code data, the best results + are between: + pb0 lp0 lc0 (10%) + pb0 lp0 lc1 (90%) + For inotab, these were observed: + pb1 lp0 lc1 + pb2 lp0 lc0 + pb1 lp1 lc0 + pb3 lp1 lc0 + pb1 lp2 lc0 + pb2 lp1 lc0 + + For C source code data, the best results + are between: + pb1 lp0 lc3 (10%) + pb0 lp0 lc3 (90%) + Occasionally: + pb0 lp1 lc0 + pb0 lp0 lc3 (mostly) + pb0 lp0 lc2 + pb0 lp0 lc4 + Occasionally 2: + pb0 lp0 lc8 + pb0 lp0 lc4 + + BUT: + Best LZMA for fblock(204944->192060): pb0 lp4 lc8 -- surprise! (INOTAB PROBABLY) + +*/ + +static UInt32 SelectDictionarySizeFor(unsigned datasize) +{ + #if 1 + if(datasize >= (1 << 30U)) return 1 << 30U; + return datasize; + #else +#ifdef __GNUC__ + /* gnu c can optimize this switch statement into a fast binary + * search, but it cannot do so for the list of the if statements. + */ + switch(datasize) + { + case 0 ... 512 : return 512; + case 513 ... 1024: return 2048; + case 1025 ... 4096: return 8192; + case 4097 ... 16384: return 32768; + case 16385 ... 65536: return 528288; + case 65537 ... 528288: return 1048576*4; + case 528289 ... 786432: return 1048576*16; + default: return 1048576*32; + } +#else + if(datasize <= 512) return 512; + if(datasize <= 1024) return 1024; + if(datasize <= 4096) return 4096; + if(datasize <= 16384) return 32768; + if(datasize <= 65536) return 528288; + if(datasize <= 528288) return 1048576*4; + if(datasize <= 786432) reutrn 1048576*16; + return 32*1048576; +#endif + #endif +} + +static void *SzAlloc(void*, size_t size) + { return new unsigned char[size]; } +static void SzFree(void*, void *address) + { unsigned char*a = (unsigned char*)address; delete[] a; } +static ISzAlloc LZMAalloc = { SzAlloc, SzFree }; + +class MemReader: public ISeqInStream +{ +public: + const unsigned char* const indata; + const size_t inlength; + size_t pos; +public: + MemReader(const unsigned char* d, size_t l) + : ISeqInStream(), indata(d), inlength(l), pos(0) + { + Read = ReadMethod; + } + static SRes ReadMethod(void *pp, void *buf, size_t *size) + { + MemReader& p = *(MemReader*)pp; + size_t rem = p.inlength-p.pos; + size_t read = *size; + if(read > rem) read= rem; + std::memcpy(buf, &p.indata[p.pos], read); + *size = read; + p.pos += read; + return SZ_OK; + } +}; +class MemWriter: public ISeqOutStream +{ +public: + std::vector buf; +public: + MemWriter(): ISeqOutStream(), buf() { Write = WriteMethod; } + + static size_t WriteMethod(void*pp, const void* from, size_t size) + { + MemWriter& p = *(MemWriter*)pp; + const unsigned char* i = (const unsigned char*)from; + p.buf.insert(p.buf.end(), i, i+size); + return size; + } +}; + +const std::vector LZMACompress(const unsigned char* data, size_t length, + unsigned pb, + unsigned lp, + unsigned lc) +{ + return LZMACompress(data,length, pb,lp,lc, + SelectDictionarySizeFor(length)); +} + +const std::vector LZMACompress( + const unsigned char* data, size_t length, + unsigned pb, + unsigned lp, + unsigned lc, + unsigned dictionarysize) +{ + if(!length) return std::vector(); + + CLzmaEncProps props; + LzmaEncProps_Init(&props); + props.dictSize = dictionarysize; + props.pb = pb; + props.lp = lp; + props.lc = lc; + props.fb = LZMA_NumFastBytes; + props.mc = LZMA_MatchFinderCycles; + props.algo = LZMA_AlgorithmNo; + props.numThreads = 1; + + switch(LZMA_AlgorithmNo) + { + case 0: // quick: HC4 + props.btMode = 0; + props.level = 1; + break; + case 1: // full: BT4 + default: + props.level = 9; + props.btMode = 1; + props.numHashBytes = 4; + break; + } + + CLzmaEncHandle p = LzmaEnc_Create(&LZMAalloc); + struct AutoReleaseLzmaEnc + { + AutoReleaseLzmaEnc(CLzmaEncHandle pp) : p(pp) { } + ~AutoReleaseLzmaEnc() + { LzmaEnc_Destroy(p, &LZMAalloc, &LZMAalloc); } + CLzmaEncHandle p; + + + AutoReleaseLzmaEnc(const AutoReleaseLzmaEnc&); + void operator=(const AutoReleaseLzmaEnc&); + + } AutoReleaser(p); // Create a destructor that ensures + // that the CLzmaEncHandle is not leaked, even if an + // exception happens + + int res = LzmaEnc_SetProps(p, &props); + if(res != SZ_OK) + { + Error: + return std::vector (); + } + + unsigned char propsEncoded[LZMA_PROPS_SIZE + 8]; + size_t propsSize = sizeof propsEncoded; + res = LzmaEnc_WriteProperties(p, propsEncoded, &propsSize); + if(res != SZ_OK) goto Error; + + MemReader is(data, length); + MemWriter os; + put_64(propsEncoded+LZMA_PROPS_SIZE, length); + os.buf.insert(os.buf.end(), propsEncoded, propsEncoded+LZMA_PROPS_SIZE+8); + + res = LzmaEnc_Encode(p, &os, &is, 0, &LZMAalloc, &LZMAalloc); + if(res != SZ_OK) goto Error; + + return os.buf; +} + +const std::vector LZMACompress(const unsigned char* data, size_t length) +{ + return LZMACompress(data, length, + LZMA_PosStateBits, + LZMA_LiteralPosStateBits, + LZMA_LiteralContextBits); +} + +#undef RC_NORMALIZE + +const std::vector LZMADeCompress + (const unsigned char* data, size_t length, bool& ok) +{ + if(length <= LZMA_PROPS_SIZE+8) + { + /*clearly_not_ok:*/ + ok = false; + return std::vector (); + } + + uint_least64_t out_sizemax = get_64(&data[LZMA_PROPS_SIZE]); + + /*if(out_sizemax >= (size_t)~0ULL) + { + // cannot even allocate a vector this large. + goto clearly_not_ok; + }*/ + + std::vector result(out_sizemax); + + ELzmaStatus status; + SizeT destlen = result.size(); + SizeT srclen = length-(LZMA_PROPS_SIZE+8); + int res = LzmaDecode( + &result[0], &destlen, + &data[LZMA_PROPS_SIZE+8], &srclen, + &data[0], LZMA_PROPS_SIZE, + LZMA_FINISH_END, + &status, + &LZMAalloc); + + /* + std::fprintf(stderr, "res=%d, status=%d, in_done=%d (buf=%d), out_done=%d (max=%d)\n", + res, + (int)status, + (int)srclen, (int)length, + (int)destlen, (int)out_sizemax); + */ + + ok = res == SZ_OK && (status == LZMA_STATUS_FINISHED_WITH_MARK + || status == LZMA_STATUS_MAYBE_FINISHED_WITHOUT_MARK) + && srclen == (length-(LZMA_PROPS_SIZE+8)) + && destlen == out_sizemax; + return result; +} + +const std::vector LZMADeCompress + (const unsigned char* data, size_t length) +{ + bool ok_unused; + return LZMADeCompress(data, length, ok_unused); +} + +#if 0 +#include +int main(void) +{ + char Buf[2048*2048]; + int s = fread(Buf,1,sizeof(Buf),stdin); + std::vector result = LZMADeCompress(std::vector(Buf,Buf+s)); + fwrite(&result[0],1,result.size(),stdout); +} +#endif + +const std::vector LZMACompressHeavy(const unsigned char* data, size_t length, + const char* why) +{ + std::vector bestresult; + char best[512]; + bool first = true; + if(LZMA_verbose >= 1) + { + std::fprintf(stderr, "Start LZMA(%s, %u bytes)\n", why, (unsigned)length); + std::fflush(stderr); + } + + unsigned minresultsize=0, maxresultsize=0; + unsigned sizemap[5][5][9] = {{{0}}}; + + bool use_small_dict = false; + + for(int compress_mode = 0; compress_mode < (5*5*9); ++compress_mode) + { + const unsigned pb = compress_mode % 5; + const unsigned lp = (compress_mode / 5) % 5; + const unsigned lc = (compress_mode / 5 / 5) % 9; + + std::vector + result = use_small_dict + ? LZMACompress(data,length,pb,lp,lc, 4096) + : LZMACompress(data,length,pb,lp,lc); + + { + sizemap[pb][lp][lc] = result.size(); + + if(first || result.size() < minresultsize) minresultsize = result.size(); + if(first || result.size() > maxresultsize) maxresultsize = result.size(); + if(first || result.size() < bestresult.size()) + { + sprintf(best, "pb%u lp%u lc%u", + pb,lp,lc); + if(LZMA_verbose >= 1) + std::fprintf(stderr, "Yay result with %s: %u\n", best, (unsigned)result.size()); + bestresult.swap(result); + first = false; + } + else + { + char tmp[512]; + sprintf(tmp, "pb%u lp%u lc%u", + pb,lp,lc); + if(LZMA_verbose >= 2) + std::fprintf(stderr, "Blaa result with %s: %u\n", tmp, (unsigned)result.size()); + } + if(LZMA_verbose >= 2) + { + std::fprintf(stderr, "%*s\n", (5 * (4+9+2)), ""); + /* Visualize the size map: */ + std::string lines[6] = {}; + for(unsigned pbt = 0; pbt <= 4; ++pbt) + { + char buf[64]; sprintf(buf, "pb%u:%11s", pbt,""); + lines[0] += buf; + + for(unsigned lpt = 0; lpt <= 4; ++lpt) + { + char buf[64]; sprintf(buf, "lp%u:", lpt); + std::string line; + line += buf; + for(unsigned lct = 0; lct <= 8; ++lct) + { + unsigned s = sizemap[pbt][lpt][lct]; + char c; + if(!s) c = '.'; + else c = 'a' + ('z'-'a'+1) + * (s - minresultsize) + / (maxresultsize-minresultsize+1); + line += c; + } + lines[1 + lpt] += line + " "; + } + } + for(unsigned a=0; a<6; ++a) std::fprintf(stderr, "%s\n", lines[a].c_str()); + std::fprintf(stderr, "\33[%uA", 7); + } + } + } + if(LZMA_verbose >= 2) + std::fprintf(stderr, "\n\n\n\n\n\n\n\n"); + + if(LZMA_verbose >= 1) + { + std::fprintf(stderr, "Best LZMA for %s(%u->%u): %s\n", + why, + (unsigned)length, + (unsigned)bestresult.size(), + best); + } + std::fflush(stderr); + return bestresult; +} + +/* + +The LZMA compression power is controlled by these parameters: + Dictionary size (we use the maximum) + Compression algorithm (we use BT4, the heaviest available) + Number of fast bytes (we use the maximum) + pb (0..4), lp (0..4) and lc (0..8) -- the effect of these depends on data. + +Since the only parameters whose effect depends on the data to be compressed +are the three (pb, lp, lc), the "auto" and "full" compression algorithms +only try to find the optimal values for those. + +The "auto" LZMA compression algorithm is based on these two assumptions: + - It is possible to find the best value for each component (pb, lp, lc) + by individually testing the most effective one of them while keeping + the others static. + I.e., step 1: pb=, lp=0, lc=0 + step 2: pb=, lp=, lc=0 + step 3: pb=, lp=, lc= + final: pb=, lp=, lc= + - That the effect of each of these components forms a parabolic function + that has a starting point, ending point, and possibly a mountain or a + valley somewhere in the middle, but never a valley _and_ a mountain, nor + two valleys nor two mountains. +These assumptions are not always true, but it gets very close to the optimum. + +The ParabolicFinder class below finds the lowest point in a parabolic curve +with a small number of tests, determining the shape of the curve by sampling +a few cue values as needed. + +The algorithm is like this: + Never check any value more than once. + Check the first two values. + If they differ, then check the last in sequence. + If not, then check everything in sequential order. + If the first two values and the last form an ascending sequence, accept the first value. + If they form a descending sequence, start Focus Mode + such that the focus lower limit is index 2 and upper + limit is the second last. Then check the second last. + If they don't, then check the third value of sequence, + and everything else in sequential order. + If in Focus Mode, check if being in the lower or upper end of the focus. + If in upper end, check if the current value is bigger than the next one. + If it is, end the process, because the smallest value has already been found. + If not, next check the value at focus_low, and increase focus_low. + If in lower end, check if the current value is bigger than the previous one. + If it is, end the process, because the smallest value has already been found. + If not, next check the value at focus_high, and decrease focus_high. + +For any sample space, it generally does 3 tests, but if it detects a curve +forming a valley, it may do more. + +Note that ParabolicFinder does not _indicate_ the lowest value. It leaves that +to the caller. It just stops searching when it thinks that no lower value will +be found. + +Note: The effect of pb, lp and lc depend also on the dictionary size setting +and compression algorithm. You cannot estimate the optimal value for those +parameters reliably using different compression settings than in the actual case. + +*/ +class ParabolicFinder +{ +public: + enum QueryState { Unknown, Pending, Done }; + enum InstructionType { HereYouGo, WaitingResults, End }; +public: + ParabolicFinder(unsigned Start, unsigned End) + : begin(Start), + results(End-Start+1, 0), + state (End-Start+1, Unknown), + LeftRightSwap(false) + { + } + + InstructionType GetNextInstruction(unsigned& attempt) + { + InstructionType result = End; + + const int Last = begin + results.size()-1; + + #define RetIns(n) do{ result = (n); goto DoneCrit; }while(0) + #define RetVal(n) do{ state[attempt = (n)] = Pending; RetIns(HereYouGo); }while(0) + + { + /* + std::fprintf(stderr, "NextInstruction..."); + for(unsigned a=0; a results[c-1]) + { + // Left side stopped descending. + if(state[Last] != Unknown) RetIns(End); + goto ExitLeftSideFor; + } + else if(results[c] == results[c-1]) + LeftSideFirst = true; + } + ExitLeftSideFor: ; + + // Check right side descend type + int RightSideNext = -1; bool RightSideDoable = false; + for(int c=Last; c>=0; --c) + switch(state[c]) + { + case Unknown: RightSideNext = c; RightSideDoable = true; goto ExitRightSideFor; + case Pending: RightSideNext = c; RightSideDoable = false; goto ExitRightSideFor; + case Done: + if(c == Last) continue; + if(results[c] > results[c+1]) + { + // Right side stopped descending. + if(state[0] != Unknown) RetIns(End); + goto ExitRightSideFor; + } + else if(results[c] == results[c+1]) + LeftSideFirst = false; + } + ExitRightSideFor: ; + + if(!LeftSideFirst) + { std::swap(LeftSideDoable, RightSideDoable); + std::swap(LeftSideNext, RightSideNext); } + + if(LeftSideDoable) RetVal(LeftSideNext); + if(RightSideDoable) RetVal(RightSideNext); + + // If we have excess threads and work to do, give them something + if(CountHandled() > 2) if(LeftSideNext >= 0) RetVal(LeftSideNext); + if(CountHandled() > 3) if(RightSideNext >= 0) RetVal(RightSideNext); + + RetIns(WaitingResults); + } + + DoneCrit: ; + } + return result; + } + + void GotResult(unsigned attempt, unsigned value) + { + { + results[attempt] = value; + state[attempt] = Done; + } + } + +private: + unsigned CountUnknown() const + { + unsigned result=0; + for(size_t a=0, b=state.size(); a results; + std::vector state; + bool LeftRightSwap; +}; + +static void LZMACompressAutoHelper( + const unsigned char* data, size_t length, + bool use_small_dict, + const char* why, + unsigned& pb, unsigned& lp, unsigned& lc, + unsigned& which_iterate, ParabolicFinder& finder, + bool&first, std::vector& bestresult) +{ + for(;;) + { + unsigned t=0; + switch(finder.GetNextInstruction(t)) + { + case ParabolicFinder::End: + return; + case ParabolicFinder::HereYouGo: + break; + case ParabolicFinder::WaitingResults: + ForceSwitchThread(); + continue; + } + + const unsigned try_pb = &which_iterate == &pb ? t : pb; + const unsigned try_lp = &which_iterate == &lp ? t : lp; + const unsigned try_lc = &which_iterate == &lc ? t : lc; + + if(LZMA_verbose >= 2) + std::fprintf(stderr, "%s:Trying pb%u lp%u lc%u\n", + why,try_pb,try_lp,try_lc); + + std::vector result = use_small_dict + ? LZMACompress(data,length,try_pb,try_lp,try_lc, 65536) + : LZMACompress(data,length,try_pb,try_lp,try_lc); + + if(LZMA_verbose >= 2) + std::fprintf(stderr, "%s: pb%u lp%u lc%u -> %u\n", + why,try_pb,try_lp,try_lc, (unsigned)result.size()); + + finder.GotResult(t, result.size()); + + { + if(first || result.size() <= bestresult.size()) + { + first = false; + bestresult.swap(result); + which_iterate = t; + } + } + } +} + + +const std::vector LZMACompressAuto(const unsigned char* data, size_t length, + const char* why) +{ + if(LZMA_verbose >= 1) + { + std::fprintf(stderr, "Start LZMA(%s, %u bytes)\n", why, (unsigned)length); + std::fflush(stderr); + } + + unsigned backup_algorithm = LZMA_AlgorithmNo; + + bool use_small_dict = false;//length >= 1048576; + + if(use_small_dict) LZMA_AlgorithmNo = 0; + + unsigned pb=0, lp=0, lc=0; + + std::vector bestresult; + + { + ParabolicFinder pb_finder(0,4); + ParabolicFinder lp_finder(0,4); + ParabolicFinder lc_finder(0,8); + bool first=true; + { + /* Using parallelism here. However, we need barriers after + * each step, because the comparisons are made based on the + * result size, and if the pb/lp/lc values other than the + * one being focused change, it won't work. Only one parameter + * must change in the loop. + */ + + /* step 1: find best value in pb axis */ + LZMACompressAutoHelper(data,length,use_small_dict,why, + pb, lp, lc, + pb, pb_finder, first, bestresult); + + + lp_finder.GotResult(lp, bestresult.size()); + + /* step 2: find best value in lp axis */ + LZMACompressAutoHelper(data,length,use_small_dict,why, + pb, lp, lc, + lp, lp_finder, first, bestresult); + + lc_finder.GotResult(lc, bestresult.size()); + + /* step 3: find best value in lc axis */ + LZMACompressAutoHelper(data,length,use_small_dict,why, + pb, lp, lc, + lc, lc_finder, first, bestresult); + } + } + + if(use_small_dict || LZMA_AlgorithmNo != backup_algorithm) + { + LZMA_AlgorithmNo = backup_algorithm; + bestresult = LZMACompress(data,length, pb,lp,lc); + } + + if(LZMA_verbose >= 1) + { + std::fprintf(stderr, "Best LZMA for %s(%u->%u): pb%u lp%u lc%u\n", + why, + (unsigned)length, + (unsigned)bestresult.size(), + pb,lp,lc); + } + std::fflush(stderr); + + return bestresult; +} + +const std::vector + DoLZMACompress(int HeavyLevel, + const unsigned char* data, size_t length, + const char* why) +{ + if(HeavyLevel >= 2) return LZMACompressHeavy(data,length, why); + if(HeavyLevel >= 1) return LZMACompressAuto(data,length, why); + return LZMACompress(data,length); +} + +extern "C" { + +/** + * Compress a buffer with lzma + * Don't copy the result back if it is too large. + * @param in a pointer to the buffer + * @param in_len the length in bytes + * @param out a pointer to a buffer of at least size in_len + * @param out_len a pointer to the compressed length of in + */ + +void do_lzma_compress(char *in, int in_len, char *out, int *out_len) { + std::vector result; + result = LZMACompress(std::vector(in, in + in_len)); + *out_len = result.size(); + if (*out_len < in_len) + std::memcpy(out, &result[0], *out_len); +} + +void do_lzma_uncompress(char *dst, int dst_len, char *src, int src_len) { + std::vector result; + result = LZMADeCompress(std::vector(src, src + src_len)); + if (result.size() <= (SizeT)dst_len) + std::memcpy(dst, &result[0], result.size()); + else + { + fprintf(stderr, "Not copying %d bytes to %d-byte buffer!\n", + (unsigned int)result.size(), dst_len); + exit(1); + } +} + +} + -- cgit v1.2.3