/* * CBFS Image Manipulation * * Copyright (C) 2013 The Chromium OS Authors. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc. */ #include #include #include #include #include #include #include #include "common.h" #include "cbfs_image.h" /* Even though the file-adding functions---cbfs_add_entry() and * cbfs_add_entry_at()---perform their sizing checks against the beginning of * the subsequent section rather than a stable recorded value such as an empty * file header's len field, it's possible to prove two interesting properties * about their behavior: * - Placing a new file within an empty entry located below an existing file * entry will never leave an aligned flash address containing neither the * beginning of a file header nor part of a file. * - Placing a new file in an empty entry at the very end of the image such * that it fits, but leaves no room for a final header, is guaranteed not to * change the total amount of space for entries, even if that new file is * later removed from the CBFS. * These properties are somewhat nonobvious from the implementation, so the * reader is encouraged to blame this comment and examine the full proofs * in the commit message before making significant changes that would risk * removing said guarantees. */ /* The file name align is not defined in CBFS spec -- only a preference by * (old) cbfstool. */ #define CBFS_FILENAME_ALIGN (16) /* Type and format */ struct typedesc_t { uint32_t type; const char *name; }; static const struct typedesc_t types_cbfs_entry[] = { {CBFS_COMPONENT_STAGE, "stage"}, {CBFS_COMPONENT_PAYLOAD, "payload"}, {CBFS_COMPONENT_OPTIONROM, "optionrom"}, {CBFS_COMPONENT_BOOTSPLASH, "bootsplash"}, {CBFS_COMPONENT_RAW, "raw"}, {CBFS_COMPONENT_VSA, "vsa"}, {CBFS_COMPONENT_MBI, "mbi"}, {CBFS_COMPONENT_MICROCODE, "microcode"}, {CBFS_COMPONENT_FSP, "fsp"}, {CBFS_COMPONENT_MRC, "mrc"}, {CBFS_COMPONENT_CMOS_DEFAULT, "cmos_default"}, {CBFS_COMPONENT_CMOS_LAYOUT, "cmos_layout"}, {CBFS_COMPONENT_SPD, "spd"}, {CBFS_COMPONENT_MRC_CACHE, "mrc_cache"}, {CBFS_COMPONENT_DELETED, "deleted"}, {CBFS_COMPONENT_NULL, "null"}, {0, NULL} }; static const struct typedesc_t types_cbfs_compression[] = { {CBFS_COMPRESS_NONE, "none"}, {CBFS_COMPRESS_LZMA, "LZMA"}, {0, NULL} }; static const char *lookup_name_by_type(const struct typedesc_t *desc, uint32_t type, const char *default_value) { int i; for (i = 0; desc[i].name; i++) if (desc[i].type == type) return desc[i].name; return default_value; } static int lookup_type_by_name(const struct typedesc_t *desc, const char *name) { int i; for (i = 0; desc[i].name && strcasecmp(name, desc[i].name); ++i); return desc[i].name ? (int)desc[i].type : -1; } static const char *get_cbfs_entry_type_name(uint32_t type) { return lookup_name_by_type(types_cbfs_entry, type, "(unknown)"); } int cbfs_parse_comp_algo(const char *name) { return lookup_type_by_name(types_cbfs_compression, name); } /* CBFS image */ size_t cbfs_calculate_file_header_size(const char *name) { return (sizeof(struct cbfs_file) + align_up(strlen(name) + 1, CBFS_FILENAME_ALIGN)); } /* Only call on legacy CBFSes possessing a master header. */ static int cbfs_fix_legacy_size(struct cbfs_image *image, char *hdr_loc) { assert(image); assert(cbfs_is_legacy_cbfs(image)); // A bug in old cbfstool may produce extra few bytes (by alignment) and // cause cbfstool to overwrite things after free space -- which is // usually CBFS header on x86. We need to workaround that. struct cbfs_file *entry, *first = NULL, *last = NULL; for (first = entry = cbfs_find_first_entry(image); entry && cbfs_is_valid_entry(image, entry); entry = cbfs_find_next_entry(image, entry)) { last = entry; } if ((char *)first < (char *)hdr_loc && (char *)entry > (char *)hdr_loc) { WARN("CBFS image was created with old cbfstool with size bug. " "Fixing size in last entry...\n"); last->len = htonl(ntohl(last->len) - image->header.align); DEBUG("Last entry has been changed from 0x%x to 0x%x.\n", cbfs_get_entry_addr(image, entry), cbfs_get_entry_addr(image, cbfs_find_next_entry(image, last))); } return 0; } void cbfs_put_header(void *dest, const struct cbfs_header *header) { struct buffer outheader; outheader.data = dest; outheader.size = 0; xdr_be.put32(&outheader, header->magic); xdr_be.put32(&outheader, header->version); xdr_be.put32(&outheader, header->romsize); xdr_be.put32(&outheader, header->bootblocksize); xdr_be.put32(&outheader, header->align); xdr_be.put32(&outheader, header->offset); xdr_be.put32(&outheader, header->architecture); } static void cbfs_decode_payload_segment(struct cbfs_payload_segment *output, struct cbfs_payload_segment *input) { struct buffer seg = { .data = (void *)input, .size = sizeof(*input), }; output->type = xdr_be.get32(&seg); output->compression = xdr_be.get32(&seg); output->offset = xdr_be.get32(&seg); output->load_addr = xdr_be.get64(&seg); output->len = xdr_be.get32(&seg); output->mem_len = xdr_be.get32(&seg); assert(seg.size == 0); } void cbfs_get_header(struct cbfs_header *header, void *src) { struct buffer outheader; outheader.data = src; /* We're not modifying the data */ outheader.size = 0; header->magic = xdr_be.get32(&outheader); header->version = xdr_be.get32(&outheader); header->romsize = xdr_be.get32(&outheader); header->bootblocksize = xdr_be.get32(&outheader); header->align = xdr_be.get32(&outheader); header->offset = xdr_be.get32(&outheader); header->architecture = xdr_be.get32(&outheader); } int cbfs_image_create(struct cbfs_image *image, size_t entries_size) { assert(image); assert(image->buffer.data); size_t empty_header_len = cbfs_calculate_file_header_size(""); uint32_t entries_offset = 0; uint32_t align = CBFS_ENTRY_ALIGNMENT; if (image->has_header) { entries_offset = image->header.offset; if (entries_offset > image->buffer.size) { ERROR("CBFS file entries are located outside CBFS itself\n"); return -1; } align = image->header.align; } // This attribute must be given in order to prove that this module // correctly preserves certain CBFS properties. See the block comment // near the top of this file (and the associated commit message). if (align < empty_header_len) { ERROR("CBFS must be aligned to at least %zu bytes\n", empty_header_len); return -1; } if (entries_size > image->buffer.size - entries_offset) { ERROR("CBFS doesn't have enough space to fit its file entries\n"); return -1; } if (empty_header_len > entries_size) { ERROR("CBFS is too small to fit any header\n"); return -1; } struct cbfs_file *entry_header = (struct cbfs_file *)(image->buffer.data + entries_offset); // This alignment is necessary in order to prove that this module // correctly preserves certain CBFS properties. See the block comment // near the top of this file (and the associated commit message). entries_size -= entries_size % align; size_t capacity = entries_size - empty_header_len; LOG("Created CBFS (capacity = %zu bytes)\n", capacity); return cbfs_create_empty_entry(entry_header, CBFS_COMPONENT_NULL, capacity, ""); } int cbfs_legacy_image_create(struct cbfs_image *image, uint32_t architecture, uint32_t align, struct buffer *bootblock, uint32_t bootblock_offset, uint32_t header_offset, uint32_t entries_offset) { assert(image); assert(image->buffer.data); assert(bootblock); int32_t *rel_offset; uint32_t cbfs_len; void *header_loc; size_t size = image->buffer.size; DEBUG("cbfs_image_create: bootblock=0x%x+0x%zx, " "header=0x%x+0x%zx, entries_offset=0x%x\n", bootblock_offset, bootblock->size, header_offset, sizeof(image->header), entries_offset); // Adjust legacy top-aligned address to ROM offset. if (IS_TOP_ALIGNED_ADDRESS(entries_offset)) entries_offset = size + (int32_t)entries_offset; if (IS_TOP_ALIGNED_ADDRESS(bootblock_offset)) bootblock_offset = size + (int32_t)bootblock_offset; if (IS_TOP_ALIGNED_ADDRESS(header_offset)) header_offset = size + (int32_t)header_offset; DEBUG("cbfs_create_image: (real offset) bootblock=0x%x, " "header=0x%x, entries_offset=0x%x\n", bootblock_offset, header_offset, entries_offset); // Prepare bootblock if (bootblock_offset + bootblock->size > size) { ERROR("Bootblock (0x%x+0x%zx) exceed ROM size (0x%zx)\n", bootblock_offset, bootblock->size, size); return -1; } if (entries_offset > bootblock_offset && entries_offset < bootblock->size) { ERROR("Bootblock (0x%x+0x%zx) overlap CBFS data (0x%x)\n", bootblock_offset, bootblock->size, entries_offset); return -1; } memcpy(image->buffer.data + bootblock_offset, bootblock->data, bootblock->size); // Prepare header if (header_offset + sizeof(image->header) > size - sizeof(int32_t)) { ERROR("Header (0x%x+0x%zx) exceed ROM size (0x%zx)\n", header_offset, sizeof(image->header), size); return -1; } image->header.magic = CBFS_HEADER_MAGIC; image->header.version = CBFS_HEADER_VERSION; image->header.romsize = size; image->header.bootblocksize = bootblock->size; image->header.align = align; image->header.offset = entries_offset; image->header.architecture = architecture; header_loc = (image->buffer.data + header_offset); cbfs_put_header(header_loc, &image->header); image->has_header = true; // The last 4 byte of the image contain the relative offset from the end // of the image to the master header as a 32-bit signed integer. x86 // relies on this also being its (memory-mapped, top-aligned) absolute // 32-bit address by virtue of how two's complement numbers work. assert(size % sizeof(int32_t) == 0); rel_offset = (int32_t *)(image->buffer.data + size - sizeof(int32_t)); *rel_offset = header_offset - size; // Prepare entries if (align_up(entries_offset, align) != entries_offset) { ERROR("Offset (0x%x) must be aligned to 0x%x.\n", entries_offset, align); return -1; } // To calculate available length, find // e = min(bootblock, header, rel_offset) where e > entries_offset. cbfs_len = size - sizeof(int32_t); if (bootblock_offset > entries_offset && bootblock_offset < cbfs_len) cbfs_len = bootblock_offset; if (header_offset > entries_offset && header_offset < cbfs_len) cbfs_len = header_offset; if (cbfs_image_create(image, cbfs_len - entries_offset)) return -1; return 0; } int cbfs_image_from_buffer(struct cbfs_image *out, struct buffer *in, uint32_t offset) { assert(out); assert(in); assert(in->data); buffer_clone(&out->buffer, in); out->has_header = false; void *header_loc = cbfs_find_header(in->data, in->size, offset); if (header_loc) { cbfs_get_header(&out->header, header_loc); out->has_header = true; cbfs_fix_legacy_size(out, header_loc); } else if (offset != ~0u) { ERROR("The -H switch is only valid on legacy images having CBFS master headers.\n"); return 1; } else if (!cbfs_is_valid_cbfs(out)) { ERROR("Selected image region is not a valid CBFS.\n"); return 1; } return 0; } int cbfs_copy_instance(struct cbfs_image *image, size_t copy_offset, size_t copy_size) { assert(image); if (!cbfs_is_legacy_cbfs(image)) return -1; struct cbfs_file *src_entry, *dst_entry; struct cbfs_header *copy_header; size_t align, entry_offset; ssize_t last_entry_size; size_t cbfs_offset, cbfs_end; size_t copy_end = copy_offset + copy_size; align = image->header.align; cbfs_offset = image->header.offset; cbfs_end = image->header.romsize; if (copy_end > image->buffer.size) { ERROR("Copy offset out of range: [%zx:%zx)\n", copy_offset, copy_end); return 1; } /* Range check requested copy region with source cbfs. */ if ((copy_offset >= cbfs_offset && copy_offset < cbfs_end) || (copy_end >= cbfs_offset && copy_end <= cbfs_end)) { ERROR("New image would overlap old one.\n"); return 1; } /* This will work, let's create a copy. */ copy_header = (struct cbfs_header *)(image->buffer.data + copy_offset); cbfs_put_header(copy_header, &image->header); copy_header->bootblocksize = 0; /* Romsize is a misnomer. It's the absolute limit of cbfs content.*/ copy_header->romsize = htonl(copy_end); entry_offset = align_up(copy_offset + sizeof(*copy_header), align); copy_header->offset = htonl(entry_offset); dst_entry = (struct cbfs_file *)(image->buffer.data + entry_offset); /* Copy non-empty files */ for (src_entry = cbfs_find_first_entry(image); src_entry && cbfs_is_valid_entry(image, src_entry); src_entry = cbfs_find_next_entry(image, src_entry)) { size_t entry_size; if ((src_entry->type == htonl(CBFS_COMPONENT_NULL)) || (src_entry->type == htonl(CBFS_COMPONENT_DELETED))) continue; entry_size = htonl(src_entry->len) + htonl(src_entry->offset); memcpy(dst_entry, src_entry, entry_size); dst_entry = (struct cbfs_file *)( (uintptr_t)dst_entry + align_up(entry_size, align)); if ((size_t)((char *)dst_entry - image->buffer.data) >= copy_end) { ERROR("Ran out of room in copy region.\n"); return 1; } } /* Last entry size is all the room above it. */ last_entry_size = copy_end - ((char *)dst_entry - image->buffer.data) - cbfs_calculate_file_header_size(""); if (last_entry_size < 0) WARN("No room to create the last entry!\n") else cbfs_create_empty_entry(dst_entry, CBFS_COMPONENT_NULL, last_entry_size, ""); return 0; } int cbfs_image_delete(struct cbfs_image *image) { if (image == NULL) return 0; buffer_delete(&image->buffer); return 0; } /* Tries to add an entry with its data (CBFS_SUBHEADER) at given offset. */ static int cbfs_add_entry_at(struct cbfs_image *image, struct cbfs_file *entry, const void *data, uint32_t content_offset, const void *header_data, uint32_t header_size) { struct cbfs_file *next = cbfs_find_next_entry(image, entry); uint32_t addr = cbfs_get_entry_addr(image, entry), addr_next = cbfs_get_entry_addr(image, next); uint32_t min_entry_size = cbfs_calculate_file_header_size(""); uint32_t len, header_offset; uint32_t align = image->has_header ? image->header.align : CBFS_ENTRY_ALIGNMENT; header_offset = content_offset - header_size; if (header_offset % align) header_offset -= header_offset % align; if (header_offset < addr) { ERROR("No space to hold cbfs_file header."); return -1; } // Process buffer BEFORE content_offset. if (header_offset - addr > min_entry_size) { DEBUG("|min|...|header|content|... \n"); len = header_offset - addr - min_entry_size; cbfs_create_empty_entry(entry, CBFS_COMPONENT_NULL, len, ""); if (verbose > 1) cbfs_print_entry_info(image, entry, stderr); entry = cbfs_find_next_entry(image, entry); addr = cbfs_get_entry_addr(image, entry); } len = content_offset - addr - header_size; memcpy(entry, header_data, header_size); if (len != 0) { /* the header moved backwards a bit to accomodate cbfs_file * alignment requirements, so patch up ->offset to still point * to file data. */ DEBUG("|..|header|content|... \n"); DEBUG("before: offset=0x%x\n", ntohl(entry->offset)); // TODO reset expanded name buffer to 0xFF. entry->offset = htonl(ntohl(entry->offset) + len); DEBUG("after: offset=0x%x\n", ntohl(entry->len)); } // Ready to fill data into entry. DEBUG("content_offset: 0x%x, entry location: %x\n", content_offset, (int)((char*)CBFS_SUBHEADER(entry) - image->buffer.data)); assert((char*)CBFS_SUBHEADER(entry) - image->buffer.data == (ptrdiff_t)content_offset); memcpy(CBFS_SUBHEADER(entry), data, ntohl(entry->len)); if (verbose > 1) cbfs_print_entry_info(image, entry, stderr); // Process buffer AFTER entry. entry = cbfs_find_next_entry(image, entry); addr = cbfs_get_entry_addr(image, entry); if (addr == addr_next) return 0; assert(addr < addr_next); if (addr_next - addr < min_entry_size) { DEBUG("No need for new \"empty\" entry\n"); /* No need to increase the size of the just * stored file to extend to next file. Alignment * of next file takes care of this. */ return 0; } len = addr_next - addr - min_entry_size; cbfs_create_empty_entry(entry, CBFS_COMPONENT_NULL, len, ""); if (verbose > 1) cbfs_print_entry_info(image, entry, stderr); return 0; } int cbfs_add_entry(struct cbfs_image *image, struct buffer *buffer, const char *name, uint32_t type, uint32_t content_offset, void *header, uint32_t header_size) { assert(image); assert(buffer); assert(buffer->data); assert(name); type = type; assert(!IS_TOP_ALIGNED_ADDRESS(content_offset)); uint32_t entry_type; uint32_t addr, addr_next; struct cbfs_file *entry, *next; uint32_t need_size; if (header_size == 0) header_size = cbfs_calculate_file_header_size(name); need_size = header_size + buffer->size; DEBUG("cbfs_add_entry('%s'@0x%x) => need_size = %u+%zu=%u\n", name, content_offset, header_size, buffer->size, need_size); // Merge empty entries. DEBUG("(trying to merge empty entries...)\n"); cbfs_walk(image, cbfs_merge_empty_entry, NULL); for (entry = cbfs_find_first_entry(image); entry && cbfs_is_valid_entry(image, entry); entry = cbfs_find_next_entry(image, entry)) { entry_type = ntohl(entry->type); if (entry_type != CBFS_COMPONENT_NULL) continue; addr = cbfs_get_entry_addr(image, entry); next = cbfs_find_next_entry(image, entry); addr_next = cbfs_get_entry_addr(image, next); DEBUG("cbfs_add_entry: space at 0x%x+0x%x(%d) bytes\n", addr, addr_next - addr, addr_next - addr); /* Will the file fit? Don't yet worry if we have space for a new * "empty" entry. We take care of that later. */ if (addr + need_size > addr_next) continue; // Test for complicated cases if (content_offset > 0) { if (addr_next < content_offset) { DEBUG("Not for specified offset yet"); continue; } else if (addr > content_offset) { DEBUG("Exceed specified content_offset."); break; } else if (addr + header_size > content_offset) { ERROR("Not enough space for header.\n"); break; } else if (content_offset + buffer->size > addr_next) { ERROR("Not enough space for content.\n"); break; } } // TODO there are more few tricky cases that we may // want to fit by altering offset. if (content_offset == 0) { // we tested every condition earlier under which // placing the file there might fail content_offset = addr + header_size; } DEBUG("section 0x%x+0x%x for content_offset 0x%x.\n", addr, addr_next - addr, content_offset); if (cbfs_add_entry_at(image, entry, buffer->data, content_offset, header, header_size) == 0) { return 0; } break; } ERROR("Could not add [%s, %zd bytes (%zd KB)@0x%x]; too big?\n", buffer->name, buffer->size, buffer->size / 1024, content_offset); return -1; } struct cbfs_file *cbfs_get_entry(struct cbfs_image *image, const char *name) { struct cbfs_file *entry; for (entry = cbfs_find_first_entry(image); entry && cbfs_is_valid_entry(image, entry); entry = cbfs_find_next_entry(image, entry)) { if (strcasecmp(entry->filename, name) == 0) { DEBUG("cbfs_get_entry: found %s\n", name); return entry; } } return NULL; } int cbfs_export_entry(struct cbfs_image *image, const char *entry_name, const char *filename) { struct cbfs_file *entry = cbfs_get_entry(image, entry_name); struct buffer buffer; if (!entry) { ERROR("File not found: %s\n", entry_name); return -1; } LOG("Found file %.30s at 0x%x, type %.12s, size %d\n", entry_name, cbfs_get_entry_addr(image, entry), get_cbfs_entry_type_name(ntohl(entry->type)), ntohl(entry->len)); if (ntohl(entry->type) != CBFS_COMPONENT_RAW) { WARN("Only 'raw' files are safe to extract.\n"); } buffer.data = CBFS_SUBHEADER(entry); buffer.size = ntohl(entry->len); buffer.name = strdup("(cbfs_export_entry)"); if (buffer_write_file(&buffer, filename) != 0) { ERROR("Failed to write %s into %s.\n", entry_name, filename); free(buffer.name); return -1; } free(buffer.name); INFO("Successfully dumped the file to: %s\n", filename); return 0; } int cbfs_remove_entry(struct cbfs_image *image, const char *name) { struct cbfs_file *entry; entry = cbfs_get_entry(image, name); if (!entry) { ERROR("CBFS file %s not found.\n", name); return -1; } DEBUG("cbfs_remove_entry: Removed %s @ 0x%x\n", entry->filename, cbfs_get_entry_addr(image, entry)); entry->type = htonl(CBFS_COMPONENT_DELETED); cbfs_walk(image, cbfs_merge_empty_entry, NULL); return 0; } int cbfs_print_header_info(struct cbfs_image *image) { char *name = strdup(image->buffer.name); assert(image); printf("%s: %zd kB, bootblocksize %d, romsize %d, offset 0x%x\n" "alignment: %d bytes, architecture: %s\n\n", basename(name), image->buffer.size / 1024, image->header.bootblocksize, image->header.romsize, image->header.offset, image->header.align, arch_to_string(image->header.architecture)); free(name); return 0; } static int cbfs_print_stage_info(struct cbfs_stage *stage, FILE* fp) { fprintf(fp, " %s compression, entry: 0x%" PRIx64 ", load: 0x%" PRIx64 ", " "length: %d/%d\n", lookup_name_by_type(types_cbfs_compression, stage->compression, "(unknown)"), stage->entry, stage->load, stage->len, stage->memlen); return 0; } static int cbfs_print_decoded_payload_segment_info( struct cbfs_payload_segment *seg, FILE *fp) { /* The input (seg) must be already decoded by * cbfs_decode_payload_segment. */ switch (seg->type) { case PAYLOAD_SEGMENT_CODE: case PAYLOAD_SEGMENT_DATA: fprintf(fp, " %s (%s compression, offset: 0x%x, " "load: 0x%" PRIx64 ", length: %d/%d)\n", (seg->type == PAYLOAD_SEGMENT_CODE ? "code " : "data"), lookup_name_by_type(types_cbfs_compression, seg->compression, "(unknown)"), seg->offset, seg->load_addr, seg->len, seg->mem_len); break; case PAYLOAD_SEGMENT_ENTRY: fprintf(fp, " entry (0x%" PRIx64 ")\n", seg->load_addr); break; case PAYLOAD_SEGMENT_BSS: fprintf(fp, " BSS (address 0x%016" PRIx64 ", " "length 0x%x)\n", seg->load_addr, seg->len); break; case PAYLOAD_SEGMENT_PARAMS: fprintf(fp, " parameters\n"); break; default: fprintf(fp, " 0x%x (%s compression, offset: 0x%x, " "load: 0x%" PRIx64 ", length: %d/%d\n", seg->type, lookup_name_by_type(types_cbfs_compression, seg->compression, "(unknown)"), seg->offset, seg->load_addr, seg->len, seg->mem_len); break; } return 0; } int cbfs_print_entry_info(struct cbfs_image *image, struct cbfs_file *entry, void *arg) { const char *name = entry->filename; struct cbfs_payload_segment *payload; FILE *fp = (FILE *)arg; if (!cbfs_is_valid_entry(image, entry)) { ERROR("cbfs_print_entry_info: Invalid entry at 0x%x\n", cbfs_get_entry_addr(image, entry)); return -1; } if (!fp) fp = stdout; fprintf(fp, "%-30s 0x%-8x %-12s %d\n", *name ? name : "(empty)", cbfs_get_entry_addr(image, entry), get_cbfs_entry_type_name(ntohl(entry->type)), ntohl(entry->len)); if (!verbose) return 0; DEBUG(" cbfs_file=0x%x, offset=0x%x, content_address=0x%x+0x%x\n", cbfs_get_entry_addr(image, entry), ntohl(entry->offset), cbfs_get_entry_addr(image, entry) + ntohl(entry->offset), ntohl(entry->len)); /* note the components of the subheader may be in host order ... */ switch (ntohl(entry->type)) { case CBFS_COMPONENT_STAGE: cbfs_print_stage_info((struct cbfs_stage *) CBFS_SUBHEADER(entry), fp); break; case CBFS_COMPONENT_PAYLOAD: payload = (struct cbfs_payload_segment *) CBFS_SUBHEADER(entry); while (payload) { struct cbfs_payload_segment seg; cbfs_decode_payload_segment(&seg, payload); cbfs_print_decoded_payload_segment_info( &seg, fp); if (seg.type == PAYLOAD_SEGMENT_ENTRY) break; else payload ++; } break; default: break; } return 0; } int cbfs_print_directory(struct cbfs_image *image) { if (cbfs_is_legacy_cbfs(image)) cbfs_print_header_info(image); printf("%-30s %-10s %-12s Size\n", "Name", "Offset", "Type"); cbfs_walk(image, cbfs_print_entry_info, NULL); return 0; } int cbfs_merge_empty_entry(struct cbfs_image *image, struct cbfs_file *entry, unused void *arg) { struct cbfs_file *next; uint32_t type, addr, last_addr; type = ntohl(entry->type); if (type == CBFS_COMPONENT_DELETED) { // Ready to be recycled. type = CBFS_COMPONENT_NULL; entry->type = htonl(type); } if (type != CBFS_COMPONENT_NULL) return 0; next = cbfs_find_next_entry(image, entry); while (next && cbfs_is_valid_entry(image, next)) { type = ntohl(next->type); if (type == CBFS_COMPONENT_DELETED) { type = CBFS_COMPONENT_NULL; next->type = htonl(type); } if (type != CBFS_COMPONENT_NULL) return 0; addr = cbfs_get_entry_addr(image, entry); last_addr = cbfs_get_entry_addr( image, cbfs_find_next_entry(image, next)); // Now, we find two deleted/empty entries; try to merge now. DEBUG("join_empty_entry: combine 0x%x+0x%x and 0x%x+0x%x.\n", cbfs_get_entry_addr(image, entry), ntohl(entry->len), cbfs_get_entry_addr(image, next), ntohl(next->len)); cbfs_create_empty_entry(entry, CBFS_COMPONENT_NULL, (last_addr - addr - cbfs_calculate_file_header_size("")), ""); DEBUG("new empty entry: length=0x%x\n", ntohl(entry->len)); next = cbfs_find_next_entry(image, entry); } return 0; } int cbfs_walk(struct cbfs_image *image, cbfs_entry_callback callback, void *arg) { int count = 0; struct cbfs_file *entry; for (entry = cbfs_find_first_entry(image); entry && cbfs_is_valid_entry(image, entry); entry = cbfs_find_next_entry(image, entry)) { count ++; if (callback(image, entry, arg) != 0) break; } return count; } static int cbfs_header_valid(struct cbfs_header *header, size_t size) { if ((ntohl(header->magic) == CBFS_HEADER_MAGIC) && ((ntohl(header->version) == CBFS_HEADER_VERSION1) || (ntohl(header->version) == CBFS_HEADER_VERSION2)) && (ntohl(header->romsize) <= size) && (ntohl(header->offset) < ntohl(header->romsize))) return 1; return 0; } struct cbfs_header *cbfs_find_header(char *data, size_t size, uint32_t forced_offset) { size_t offset; int found = 0; int32_t rel_offset; struct cbfs_header *header, *result = NULL; if (forced_offset < (size - sizeof(struct cbfs_header))) { /* Check if the forced header is valid. */ header = (struct cbfs_header *)(data + forced_offset); if (cbfs_header_valid(header, size)) return header; return NULL; } // Try finding relative offset of master header at end of file first. rel_offset = *(int32_t *)(data + size - sizeof(int32_t)); offset = size + rel_offset; DEBUG("relative offset: %#zx(-%#zx), offset: %#zx\n", (size_t)rel_offset, (size_t)-rel_offset, offset); if (offset >= size - sizeof(*header) || !cbfs_header_valid((struct cbfs_header *)(data + offset), size)) { // Some use cases append non-CBFS data to the end of the ROM. DEBUG("relative offset seems wrong, scanning whole image...\n"); offset = 0; } for (; offset + sizeof(*header) < size; offset++) { header = (struct cbfs_header *)(data + offset); if (!cbfs_header_valid(header, size)) continue; if (!found++) result = header; } if (found > 1) // Top-aligned images usually have a working relative offset // field, so this is more likely to happen on bottom-aligned // ones (where the first header is the "outermost" one) WARN("Multiple (%d) CBFS headers found, using the first one.\n", found); return result; } struct cbfs_file *cbfs_find_first_entry(struct cbfs_image *image) { assert(image); return image->has_header ? (struct cbfs_file *)(image->buffer.data + image->header.offset) : (struct cbfs_file *)image->buffer.data; } struct cbfs_file *cbfs_find_next_entry(struct cbfs_image *image, struct cbfs_file *entry) { uint32_t addr = cbfs_get_entry_addr(image, entry); int align = image->has_header ? image->header.align : CBFS_ENTRY_ALIGNMENT; assert(entry && cbfs_is_valid_entry(image, entry)); addr += ntohl(entry->offset) + ntohl(entry->len); addr = align_up(addr, align); return (struct cbfs_file *)(image->buffer.data + addr); } uint32_t cbfs_get_entry_addr(struct cbfs_image *image, struct cbfs_file *entry) { assert(image && image->buffer.data && entry); return (int32_t)((char *)entry - image->buffer.data); } int cbfs_is_valid_cbfs(struct cbfs_image *image) { return buffer_check_magic(&image->buffer, CBFS_FILE_MAGIC, strlen(CBFS_FILE_MAGIC)); } int cbfs_is_legacy_cbfs(struct cbfs_image *image) { return image->has_header; } int cbfs_is_valid_entry(struct cbfs_image *image, struct cbfs_file *entry) { uint32_t offset = cbfs_get_entry_addr(image, entry); if (offset >= image->buffer.size) return 0; struct buffer entry_data; buffer_clone(&entry_data, &image->buffer); buffer_seek(&entry_data, offset); return buffer_check_magic(&entry_data, CBFS_FILE_MAGIC, strlen(CBFS_FILE_MAGIC)); } struct cbfs_file *cbfs_create_file_header(int type, size_t len, const char *name) { // assume that there won't be file names of ~1000 bytes const int bufsize = 1024; struct cbfs_file *entry = malloc(bufsize); memset(entry, CBFS_CONTENT_DEFAULT_VALUE, bufsize); memcpy(entry->magic, CBFS_FILE_MAGIC, sizeof(entry->magic)); entry->type = htonl(type); entry->len = htonl(len); entry->attributes_offset = 0; entry->offset = htonl(cbfs_calculate_file_header_size(name)); memset(entry->filename, 0, ntohl(entry->offset) - sizeof(*entry)); strcpy(entry->filename, name); return entry; } int cbfs_create_empty_entry(struct cbfs_file *entry, int type, size_t len, const char *name) { struct cbfs_file *tmp = cbfs_create_file_header(type, len, name); memcpy(entry, tmp, ntohl(tmp->offset)); free(tmp); memset(CBFS_SUBHEADER(entry), CBFS_CONTENT_DEFAULT_VALUE, len); return 0; } /* Finds a place to hold whole data in same memory page. */ static int is_in_same_page(uint32_t start, uint32_t size, uint32_t page) { if (!page) return 1; return (start / page) == (start + size - 1) / page; } /* Tests if data can fit in a range by given offset: * start ->| header_len | offset (+ size) |<- end */ static int is_in_range(uint32_t start, uint32_t end, uint32_t header_len, uint32_t offset, uint32_t size) { return (offset >= start + header_len && offset + size <= end); } int32_t cbfs_locate_entry(struct cbfs_image *image, const char *name, uint32_t size, uint32_t page_size, uint32_t align) { struct cbfs_file *entry; size_t need_len; uint32_t addr, addr_next, addr2, addr3, offset, header_len; /* Default values: allow fitting anywhere in ROM. */ if (!page_size) page_size = image->has_header ? image->header.romsize : image->buffer.size; if (!align) align = 1; if (size > page_size) ERROR("Input file size (%d) greater than page size (%d).\n", size, page_size); uint32_t image_align = image->has_header ? image->header.align : CBFS_ENTRY_ALIGNMENT; if (page_size % image_align) WARN("%s: Page size (%#x) not aligned with CBFS image (%#x).\n", __func__, page_size, image_align); /* TODO Old cbfstool always assume input is a stage file (and adding * sizeof(cbfs_stage) for header. We should fix that by adding "-t" * (type) param in future. For right now, we assume cbfs_stage is the * largest structure and add it into header size. */ assert(sizeof(struct cbfs_stage) >= sizeof(struct cbfs_payload)); header_len = (cbfs_calculate_file_header_size(name) + sizeof(struct cbfs_stage)); need_len = header_len + size; // Merge empty entries to build get max available space. cbfs_walk(image, cbfs_merge_empty_entry, NULL); /* Three cases of content location on memory page: * case 1. * | PAGE 1 | PAGE 2 | * |
| Fit. Return start of content. * * case 2. * | PAGE 1 | PAGE 2 | * |
| Fits when we shift content to align * shift-> |
| | at starting of PAGE 2. * * case 3. (large content filling whole page) * | PAGE 1 | PAGE 2 | PAGE 3 | * |
< content > | Can't fit. If we shift content to * |trial->
< content > | PAGE 2, header can't fit in free * | shift->
space, so we must use PAGE 3. * * The returned address can be then used as "base-address" (-b) in add-* * commands (will be re-calculated and positioned by cbfs_add_entry_at). * For stage targets, the address is also used to re-link stage before * being added into CBFS. */ for (entry = cbfs_find_first_entry(image); entry && cbfs_is_valid_entry(image, entry); entry = cbfs_find_next_entry(image, entry)) { uint32_t type = ntohl(entry->type); if (type != CBFS_COMPONENT_NULL) continue; addr = cbfs_get_entry_addr(image, entry); addr_next = cbfs_get_entry_addr(image, cbfs_find_next_entry( image, entry)); if (addr_next - addr < need_len) continue; offset = align_up(addr + header_len, align); if (is_in_same_page(offset, size, page_size) && is_in_range(addr, addr_next, header_len, offset, size)) { DEBUG("cbfs_locate_entry: FIT (PAGE1)."); return offset; } addr2 = align_up(addr, page_size); offset = align_up(addr2, align); if (is_in_range(addr, addr_next, header_len, offset, size)) { DEBUG("cbfs_locate_entry: OVERLAP (PAGE2)."); return offset; } /* Assume page_size >= header_len so adding one page will * definitely provide the space for header. */ assert(page_size >= header_len); addr3 = addr2 + page_size; offset = align_up(addr3, align); if (is_in_range(addr, addr_next, header_len, offset, size)) { DEBUG("cbfs_locate_entry: OVERLAP+ (PAGE3)."); return offset; } } return -1; }