/* * common utility functions for cbfstool * * Copyright (C) 2009 coresystems GmbH * written by Patrick Georgi * Copyright (C) 2012 Google, Inc. * * 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., 51 Franklin St, Fifth Floor, Boston, MA, 02110-1301 USA */ #include #include #include #include #include "common.h" #include "cbfs.h" #include "elf.h" #define dprintf(x...) size_t getfilesize(const char *filename) { size_t size; FILE *file = fopen(filename, "rb"); if (file == NULL) return -1; fseek(file, 0, SEEK_END); size = ftell(file); fclose(file); return size; } void *loadfile(const char *filename, uint32_t * romsize_p, void *content, int place) { FILE *file = fopen(filename, "rb"); if (file == NULL) return NULL; fseek(file, 0, SEEK_END); *romsize_p = ftell(file); fseek(file, 0, SEEK_SET); if (!content) { content = malloc(*romsize_p); if (!content) { fprintf(stderr, "E: Could not get %d bytes for file %s\n", *romsize_p, filename); exit(1); } } else if (place == SEEK_END) content -= *romsize_p; if (!fread(content, *romsize_p, 1, file)) { fprintf(stderr, "E: Failed to read %s\n", filename); return NULL; } fclose(file); return content; } static struct cbfs_header *master_header; static uint32_t phys_start, phys_end, align; uint32_t romsize; void *offset; uint32_t arch = CBFS_ARCHITECTURE_UNKNOWN; static struct { uint32_t arch; const char *name; } arch_names[] = { { CBFS_ARCHITECTURE_ARMV7, "armv7" }, { CBFS_ARCHITECTURE_X86, "x86" }, { CBFS_ARCHITECTURE_UNKNOWN, "unknown" } }; uint32_t string_to_arch(const char *arch_string) { int i; uint32_t ret = CBFS_ARCHITECTURE_UNKNOWN; for (i = 0; i < ARRAY_SIZE(arch_names); i++) { if (!strcasecmp(arch_string, arch_names[i].name)) { ret = arch_names[i].arch; break; } } return ret; } const char *arch_to_string(uint32_t a) { int i; const char *ret = NULL; for (i = 0; i < ARRAY_SIZE(arch_names); i++) { if (a == arch_names[i].arch) { ret = arch_names[i].name; break; } } return ret; } int find_master_header(void *romarea, size_t size) { size_t offset; if (master_header) return 0; for (offset = 0; offset < size - sizeof(struct cbfs_header); offset++) { struct cbfs_header *tmp = romarea + offset; if (tmp->magic == ntohl(CBFS_HEADER_MAGIC)) { master_header = tmp; break; } } return master_header ? 0 : 1; } void recalculate_rom_geometry(void *romarea) { if (find_master_header(romarea, romsize)) { fprintf(stderr, "E: Cannot find master header\n"); exit(1); } /* Update old headers */ if (master_header->version == CBFS_HEADER_VERSION1 && ntohl(master_header->architecture) == CBFS_ARCHITECTURE_UNKNOWN) { dprintf("Updating CBFS master header to version 2\n"); master_header->architecture = htonl(CBFS_ARCHITECTURE_X86); } arch = ntohl(master_header->architecture); switch (arch) { case CBFS_ARCHITECTURE_ARMV7: offset = romarea; phys_start = (0 + ntohl(master_header->offset)) & 0xffffffff; phys_end = romsize & 0xffffffff; break; case CBFS_ARCHITECTURE_X86: offset = romarea + romsize - 0x100000000ULL; phys_start = (0 - romsize + ntohl(master_header->offset)) & 0xffffffff; phys_end = (0 - ntohl(master_header->bootblocksize) - sizeof(struct cbfs_header)) & 0xffffffff; break; default: fprintf(stderr, "E: Unknown architecture\n"); exit(1); } align = ntohl(master_header->align); } void *loadrom(const char *filename) { void *romarea = loadfile(filename, &romsize, 0, SEEK_SET); if (romarea == NULL) return NULL; recalculate_rom_geometry(romarea); return romarea; } int writerom(const char *filename, void *start, uint32_t size) { FILE *file = fopen(filename, "wb"); if (!file) { fprintf(stderr, "Could not open '%s' for writing: ", filename); perror(""); return 1; } if (fwrite(start, size, 1, file) != 1) { fprintf(stderr, "Could not write to '%s': ", filename); perror(""); return 1; } fclose(file); return 0; } int cbfs_file_header(unsigned long physaddr) { /* maybe improve this test */ return (strncmp(phys_to_virt(physaddr), "LARCHIVE", 8) == 0); } struct cbfs_file *cbfs_create_empty_file(uint32_t physaddr, uint32_t size) { struct cbfs_file *nextfile = (struct cbfs_file *)phys_to_virt(physaddr); strncpy((char *)(nextfile->magic), "LARCHIVE", 8); nextfile->len = htonl(size); nextfile->type = htonl(0xffffffff); nextfile->checksum = 0; // FIXME? nextfile->offset = htonl(sizeof(struct cbfs_file) + 16); memset(((void *)nextfile) + sizeof(struct cbfs_file), 0, 16); return nextfile; } int iself(unsigned char *input) { Elf32_Ehdr *ehdr = (Elf32_Ehdr *) input; return !memcmp(ehdr->e_ident, ELFMAG, 4); } static struct filetypes_t { uint32_t type; const char *name; } filetypes[] = { {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_CMOS_DEFAULT, "cmos default"}, {CBFS_COMPONENT_CMOS_LAYOUT, "cmos layout"}, {CBFS_COMPONENT_DELETED, "deleted"}, {CBFS_COMPONENT_NULL, "null"} }; void print_supported_filetypes(void) { int i, number = ARRAY_SIZE(filetypes); for (i=0; ibootblocksize), romsize, ntohl(master_header->offset), align, arch_to_string(arch)); printf("%-30s %-10s %-12s Size\n", "Name", "Offset", "Type"); uint32_t current = phys_start; while (current < phys_end) { if (!cbfs_file_header(current)) { current += align; continue; } struct cbfs_file *thisfile = (struct cbfs_file *)phys_to_virt(current); uint32_t length = ntohl(thisfile->len); char *fname = (char *)(phys_to_virt(current) + sizeof(struct cbfs_file)); if (strlen(fname) == 0) fname = "(empty)"; printf("%-30s 0x%-8x %-12s %d\n", fname, current - phys_start + ntohl(master_header->offset), strfiletype(ntohl(thisfile->type)), length); current = ALIGN(current + ntohl(thisfile->len) + ntohl(thisfile->offset), align); } } int extract_file_from_cbfs(const char *filename, const char *payloadname, const char *outpath) { FILE *outfile = NULL; uint32_t current = phys_start; while (current < phys_end) { if (!cbfs_file_header(current)) { current += align; continue; } // Locate the file start struct struct cbfs_file *thisfile = (struct cbfs_file *)phys_to_virt(current); // And its length uint32_t length = ntohl(thisfile->len); // Locate the file name char *fname = (char *)(phys_to_virt(current) + sizeof(struct cbfs_file)); // It's not the file we are looking for.. if (strcmp(fname, payloadname) != 0) { current = ALIGN(current + ntohl(thisfile->len) + ntohl(thisfile->offset), align); continue; } // Else, it's our file. printf("Found file %.30s at 0x%x, type %.12s, size %d\n", fname, current - phys_start, strfiletype(ntohl(thisfile->type)), length); // If we are not dumping to stdout, open the out file. outfile = fopen(outpath, "wb"); if (!outfile) { fprintf(stderr, "E: Could not open the file %s for writing.\n", outpath); return 1; } if (ntohl(thisfile->type) != CBFS_COMPONENT_RAW) { fprintf(stderr, "W: Only 'raw' files are safe to extract.\n"); } fwrite(((char *)thisfile) + ntohl(thisfile->offset), length, 1, outfile); fclose(outfile); printf("Successfully dumped the file.\n"); // We'll only dump one file. return 0; } fprintf(stderr, "E: File %s not found.\n", payloadname); return 1; } int add_file_to_cbfs(void *content, uint32_t contentsize, uint32_t location) { uint32_t current = phys_start; while (current < phys_end) { if (!cbfs_file_header(current)) { current += align; continue; } struct cbfs_file *thisfile = (struct cbfs_file *)phys_to_virt(current); uint32_t length = ntohl(thisfile->len); dprintf("at %x, %x bytes\n", current, length); /* Is this a free chunk? */ if ((thisfile->type == CBFS_COMPONENT_DELETED) || (thisfile->type == CBFS_COMPONENT_NULL)) { dprintf("null||deleted at %x, %x bytes\n", current, length); /* if this is the right size, and if specified, the right location, use it */ if ((contentsize <= length) && ((location == 0) || (current == location))) { if (contentsize < length) { dprintf ("this chunk is %x bytes, we need %x. create a new chunk at %x with %x bytes\n", length, contentsize, ALIGN(current + contentsize, align), length - contentsize); uint32_t start = ALIGN(current + contentsize, align); uint32_t size = current + ntohl(thisfile->offset) + length - start - 16 - sizeof(struct cbfs_file); cbfs_create_empty_file(start, size); } dprintf("copying data\n"); memcpy(phys_to_virt(current), content, contentsize); return 0; } if (location != 0) { /* CBFS has the constraint that the chain always moves up in memory. so once we're past the place we seek, we don't need to look any further */ if (current > location) { fprintf (stderr, "E: The requested space is not available\n"); return 1; } /* Is the requested location inside the current chunk? */ if ((current < location) && ((location + contentsize) <= (current + length))) { /* Split it up. In the next iteration the code will be at the right place. */ dprintf("split up. new length: %x\n", location - current - ntohl(thisfile->offset)); thisfile->len = htonl(location - current - ntohl(thisfile->offset)); cbfs_create_empty_file(location, length - (location - current)); } } } current = ALIGN(current + ntohl(thisfile->len) + ntohl(thisfile->offset), align); } fprintf(stderr, "E: Could not add the file to CBFS, it's probably too big.\n"); fprintf(stderr, "E: File size: %d bytes (%d KB).\n", contentsize, contentsize/1024); return 1; } static struct cbfs_file *merge_adjacent_files(struct cbfs_file *first, struct cbfs_file *second) { uint32_t new_length = ntohl(first->len) + ntohl(second->len) + ntohl(second->offset); first->len = htonl(new_length); first->checksum = 0; // FIXME? return first; } static struct cbfs_file *next_file(struct cbfs_file *prev) { uint32_t pos = (prev == NULL) ? phys_start : ALIGN(virt_to_phys(prev) + ntohl(prev->len) + ntohl(prev->offset), align); for (; pos < phys_end; pos += align) { if (cbfs_file_header(pos)) return (struct cbfs_file *)phys_to_virt(pos); } return NULL; } int remove_file_from_cbfs(const char *filename) { struct cbfs_file *prev = NULL; struct cbfs_file *cur = next_file(prev); struct cbfs_file *next = next_file(cur); for (; cur; prev = cur, cur = next, next = next_file(next)) { /* Check if this is the file to remove. */ char *name = (char *)cur + sizeof(*cur); if (strcmp(name, filename)) continue; /* Mark the file as free space and erase its name. */ cur->type = CBFS_COMPONENT_NULL; name[0] = '\0'; /* Merge it with the previous file if possible. */ if (prev && prev->type == CBFS_COMPONENT_NULL) cur = merge_adjacent_files(prev, cur); /* Merge it with the next file if possible. */ if (next && next->type == CBFS_COMPONENT_NULL) merge_adjacent_files(cur, next); return 0; } fprintf(stderr, "E: CBFS file %s not found.\n", filename); return 1; } /* returns new data block with cbfs_file header, suitable to dump into the ROM. location returns the new location that points to the cbfs_file header */ void *create_cbfs_file(const char *filename, void *data, uint32_t * datasize, uint32_t type, uint32_t * location) { uint32_t filename_len = ALIGN(strlen(filename) + 1, 16); uint32_t headersize = sizeof(struct cbfs_file) + filename_len; if ((location != 0) && (*location != 0)) { uint32_t offset = *location % align; /* If offset >= (headersize % align), we can stuff the header into the offset. Otherwise the header has to be aligned itself, and put before the offset data */ if (offset >= (headersize % align)) { offset -= (headersize % align); } else { offset += align - (headersize % align); } headersize += offset; *location -= headersize; } void *newdata = malloc(*datasize + headersize); if (!newdata) { fprintf(stderr, "E: Could not get %d bytes for CBFS file.\n", *datasize + headersize); exit(1); } memset(newdata, 0xff, *datasize + headersize); struct cbfs_file *nextfile = (struct cbfs_file *)newdata; strncpy((char *)(nextfile->magic), "LARCHIVE", 8); nextfile->len = htonl(*datasize); nextfile->type = htonl(type); nextfile->checksum = 0; // FIXME? nextfile->offset = htonl(headersize); strcpy(newdata + sizeof(struct cbfs_file), filename); memcpy(newdata + headersize, data, *datasize); *datasize += headersize; return newdata; } int create_cbfs_image(const char *romfile, uint32_t _romsize, const char *bootblock, uint32_t align, uint32_t offs) { uint32_t bootblocksize = 0; struct cbfs_header *master_header; unsigned char *romarea, *bootblk; romsize = _romsize; romarea = malloc(romsize); if (!romarea) { fprintf(stderr, "E: Could not get %d bytes of memory" " for CBFS image.\n", romsize); exit(1); } memset(romarea, 0xff, romsize); if (align == 0) align = 64; bootblk = loadfile(bootblock, &bootblocksize, romarea + romsize, SEEK_END); if (!bootblk) { fprintf(stderr, "E: Could not load bootblock %s.\n", bootblock); free(romarea); return 1; } // TODO(hungte) Replace magic numbers by named constants. switch (arch) { case CBFS_ARCHITECTURE_ARMV7: /* Set up physical/virtual mapping */ offset = romarea; // should be aligned to align uint32_t *arm_vec = (uint32_t *)(romarea + offs); master_header = (struct cbfs_header *)(romarea + offs + 0x20); loadfile(bootblock, &bootblocksize, romarea + offs + 0x20 + sizeof(struct cbfs_header), SEEK_SET); /* * Encoding for this branch instruction is: * 31:28 - condition (0xe for always/unconditional) * 27:24 - Branch (0xa, encoding A1) * 23: 0 - sign-extended offset (in multiples of 4) * * When executing the branch, the PC will read as the address * of current instruction + 8. */ uint32_t imm = ((0x20 + sizeof(struct cbfs_header)) - 8) / 4; arm_vec[0] = imm | (0xa << 24) | (0xe << 28); master_header->magic = ntohl(CBFS_HEADER_MAGIC); master_header->version = ntohl(CBFS_HEADER_VERSION); master_header->romsize = htonl(romsize); master_header->bootblocksize = htonl(bootblocksize); master_header->align = htonl(align); master_header->offset = htonl( ALIGN((0x40 + bootblocksize), align)); master_header->architecture = htonl(CBFS_ARCHITECTURE_ARMV7); ((uint32_t *) phys_to_virt(0x4 + offs))[0] = virt_to_phys(master_header); recalculate_rom_geometry(romarea); cbfs_create_empty_file( offs + ALIGN((0x40 + bootblocksize), align), romsize - offs - sizeof(struct cbfs_file) - ALIGN((bootblocksize + 0x40), align)); break; case CBFS_ARCHITECTURE_X86: // Set up physical/virtual mapping offset = romarea + romsize - 0x100000000ULL; loadfile(bootblock, &bootblocksize, romarea + romsize, SEEK_END); master_header = (struct cbfs_header *)(romarea + romsize - bootblocksize - sizeof(struct cbfs_header)); master_header->magic = ntohl(CBFS_HEADER_MAGIC); master_header->version = ntohl(CBFS_HEADER_VERSION); master_header->romsize = htonl(romsize); master_header->bootblocksize = htonl(bootblocksize); master_header->align = htonl(align); master_header->offset = htonl(offs); master_header->architecture = htonl(CBFS_ARCHITECTURE_X86); ((uint32_t *) phys_to_virt(CBFS_HEADPTR_ADDR_X86))[0] = virt_to_phys(master_header); recalculate_rom_geometry(romarea); cbfs_create_empty_file((0 - romsize + offs) & 0xffffffff, romsize - offs - bootblocksize - sizeof(struct cbfs_header) - sizeof(struct cbfs_file) - 16); break; default: // Should not happen. fprintf(stderr, "E: You found a bug in cbfstool.\n"); exit(1); } writerom(romfile, romarea, romsize); free(romarea); return 0; } static int in_segment(int addr, int size, int gran) { return ((addr & ~(gran - 1)) == ((addr + size) & ~(gran - 1))); } uint32_t cbfs_find_location(const char *romfile, uint32_t filesize, const char *filename, uint32_t alignment) { void *rom; size_t filename_size, headersize, totalsize; int ret = 0; uint32_t current; rom = loadrom(romfile); if (rom == NULL) { fprintf(stderr, "E: Could not load ROM image '%s'.\n", romfile); return 0; } filename_size = strlen(filename); headersize = sizeof(struct cbfs_file) + ALIGN(filename_size + 1, 16) + sizeof(struct cbfs_stage); totalsize = headersize + filesize; current = phys_start; while (current < phys_end) { uint32_t top; struct cbfs_file *thisfile; if (!cbfs_file_header(current)) { current += align; continue; } thisfile = (struct cbfs_file *)phys_to_virt(current); top = current + ntohl(thisfile->len) + ntohl(thisfile->offset); if (((ntohl(thisfile->type) == 0x0) || (ntohl(thisfile->type) == 0xffffffff)) && (ntohl(thisfile->len) + ntohl(thisfile->offset) >= totalsize)) { if (in_segment (current + headersize, filesize, alignment)) { ret = current + headersize; break; } if ((ALIGN(current, alignment) + filesize < top) && (ALIGN(current, alignment) - headersize > current) && in_segment(ALIGN(current, alignment), filesize, alignment)) { ret = ALIGN(current, alignment); break; } if ((ALIGN(current, alignment) + alignment + filesize < top) && (ALIGN(current, alignment) + alignment - headersize > current) && in_segment(ALIGN(current, alignment) + alignment, filesize, alignment)) { ret = ALIGN(current, alignment) + alignment; break; } } current = ALIGN(current + ntohl(thisfile->len) + ntohl(thisfile->offset), align); } free(rom); return ret; }