/* * elf header parsing. * * Copyright (C) 2013 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 "elfparsing.h" #include "common.h" #include "cbfs.h" /* * Short form: this is complicated, but we've tried making it simple * and we keep hitting problems with our ELF parsing. * * The ELF parsing situation has always been a bit tricky. In fact, * we (and most others) have been getting it wrong in small ways for * years. Recently this has caused real trouble for the ARM V8 build. * In this file we attempt to finally get it right for all variations * of endian-ness and word size and target architectures and * architectures we might get run on. Phew!. To do this we borrow a * page from the FreeBSD NFS xdr model (see elf_ehdr and elf_phdr), * the Plan 9 endianness functions (see xdr.c), and Go interfaces (see * how we use buffer structs in this file). This ends up being a bit * wordy at the lowest level, but greatly simplifies the elf parsing * code and removes a common source of bugs, namely, forgetting to * flip type endianness when referencing a struct member. * * ELF files can have four combinations of data layout: 32/64, and * big/little endian. Further, to add to the fun, depending on the * word size, the size of the ELF structs varies. The coreboot SELF * format is simpler in theory: it's supposed to be always BE, and the * various struct members allow room for growth: the entry point is * always 64 bits, for example, so the size of a SELF struct is * constant, regardless of target architecture word size. Hence, we * need to do some transformation of the ELF files. * * A given architecture, realistically, only supports one of the four * combinations at a time as the 'native' format. Hence, our code has * been sprinkled with every variation of [nh]to[hn][sll] over the * years. We've never quite gotten it all right, however, and a quick * pass over this code revealed another bug. It's all worked because, * until now, all the working platforms that had CBFS were 32 LE. Even then, * however, bugs crept in: we recently realized that we're not * transforming the entry point to big format when we store into the * SELF image. * * The problem is essentially an XDR operation: * we have something in a foreign format and need to transform it. * It's most like XDR because: * 1) the byte order can be wrong * 2) the word size can be wrong * 3) the size of elements in the stream depends on the value * of other elements in the stream * it's not like XDR because: * 1) the byte order can be right * 2) the word size can be right * 3) the struct members are all on a natural alignment * * Hence, this new approach. To cover word size issues, we *always* * transform the two structs we care about, the file header and * program header, into a native struct in the 64 bit format: * * [32,little] -> [Elf64_Ehdr, Elf64_Phdr] * [64,little] -> [Elf64_Ehdr, Elf64_Phdr] * [32,big] -> [Elf64_Ehdr, Elf64_Phdr] * [64,big] -> [Elf64_Ehdr, Elf64_Phdr] * Then we just use those structs, and all the need for inline ntoh* goes away, * as well as all the chances for error. * This works because all the SELF structs have fields large enough for * the largest ELF 64 struct members, and all the Elf64 struct members * are at least large enough for all ELF 32 struct members. * We end up with one function to do all our ELF parsing, and two functions * to transform the headers. For the put case, we also have * XDR functions, and hopefully we'll never again spend 5 years with the * wrong endian-ness on an output value :-) * This should work for all word sizes and endianness we hope to target. * I *really* don't want to be here for 128 bit addresses. * * The parse functions are called with a pointer to an input buffer * struct. One might ask: are there enough bytes in the input buffer? * We know there need to be at *least* sizeof(Elf32_Ehdr) + * sizeof(Elf32_Phdr) bytes. Realistically, there has to be some data * too. If we start to worry, though we have not in the past, we * might apply the simple test: the input buffer needs to be at least * sizeof(Elf64_Ehdr) + sizeof(Elf64_Phdr) bytes because, even if it's * ELF 32, there's got to be *some* data! This is not theoretically * accurate but it is actually good enough in practice. It allows the * header transformation code to ignore the possibility of underrun. * * We also must accomodate different ELF files, and hence formats, * in the same cbfs invocation. We might load a 64-bit payload * on a 32-bit machine; we might even have a mixed armv7/armv8 * SOC or even a system with an x86/ARM! * * A possibly problematic (though unlikely to be so) assumption * is that we expect the BIOS to remain in the lowest 32 bits * of the physical address space. Since ARMV8 has standardized * on that, and x86_64 also has, this seems a safe assumption. * * To repeat, ELF structs are different sizes because ELF struct * members are different sizes, depending on values in the ELF file * header. For this we use the functions defined in xdr.c, which * consume bytes, convert the endianness, and advance the data pointer * in the buffer struct. */ static int iself(const void *input) { const Elf32_Ehdr *ehdr = input; return !memcmp(ehdr->e_ident, ELFMAG, 4); } /* Get the ident array, so we can figure out * endian-ness, word size, and in future other useful * parameters */ static void elf_eident(struct buffer *input, Elf64_Ehdr *ehdr) { bgets(input, ehdr->e_ident, sizeof(ehdr->e_ident)); } static int check_size(const struct buffer *b, size_t offset, size_t size, const char *desc) { if (size == 0) return 0; if (offset >= buffer_size(b) || (offset + size) > buffer_size(b)) { ERROR("The file is not large enough for the '%s'. " "%ld bytes @ offset %zu, input %zu bytes.\n", desc, size, offset, buffer_size(b)); return -1; } return 0; } static void elf_ehdr(struct buffer *input, Elf64_Ehdr *ehdr, struct xdr *xdr, int bit64) { ehdr->e_type = xdr->get16(input); ehdr->e_machine = xdr->get16(input); ehdr->e_version = xdr->get32(input); if (bit64){ ehdr->e_entry = xdr->get64(input); ehdr->e_phoff = xdr->get64(input); ehdr->e_shoff = xdr->get64(input); } else { ehdr->e_entry = xdr->get32(input); ehdr->e_phoff = xdr->get32(input); ehdr->e_shoff = xdr->get32(input); } ehdr->e_flags = xdr->get32(input); ehdr->e_ehsize = xdr->get16(input); ehdr->e_phentsize = xdr->get16(input); ehdr->e_phnum = xdr->get16(input); ehdr->e_shentsize = xdr->get16(input); ehdr->e_shnum = xdr->get16(input); ehdr->e_shstrndx = xdr->get16(input); } static void elf_phdr(struct buffer *pinput, Elf64_Phdr *phdr, int entsize, struct xdr *xdr, int bit64) { /* * The entsize need not be sizeof(*phdr). * Hence, it is easier to keep a copy of the input, * as the xdr functions may not advance the input * pointer the full entsize; rather than get tricky * we just advance it below. */ struct buffer input; buffer_clone(&input, pinput); if (bit64){ phdr->p_type = xdr->get32(&input); phdr->p_flags = xdr->get32(&input); phdr->p_offset = xdr->get64(&input); phdr->p_vaddr = xdr->get64(&input); phdr->p_paddr = xdr->get64(&input); phdr->p_filesz = xdr->get64(&input); phdr->p_memsz = xdr->get64(&input); phdr->p_align = xdr->get64(&input); } else { phdr->p_type = xdr->get32(&input); phdr->p_offset = xdr->get32(&input); phdr->p_vaddr = xdr->get32(&input); phdr->p_paddr = xdr->get32(&input); phdr->p_filesz = xdr->get32(&input); phdr->p_memsz = xdr->get32(&input); phdr->p_flags = xdr->get32(&input); phdr->p_align = xdr->get32(&input); } buffer_seek(pinput, entsize); } static void elf_shdr(struct buffer *pinput, Elf64_Shdr *shdr, int entsize, struct xdr *xdr, int bit64) { /* * The entsize need not be sizeof(*shdr). * Hence, it is easier to keep a copy of the input, * as the xdr functions may not advance the input * pointer the full entsize; rather than get tricky * we just advance it below. */ struct buffer input = *pinput; if (bit64){ shdr->sh_name = xdr->get32(&input); shdr->sh_type = xdr->get32(&input); shdr->sh_flags = xdr->get64(&input); shdr->sh_addr = xdr->get64(&input); shdr->sh_offset = xdr->get64(&input); shdr->sh_size= xdr->get64(&input); shdr->sh_link = xdr->get32(&input); shdr->sh_info = xdr->get32(&input); shdr->sh_addralign = xdr->get64(&input); shdr->sh_entsize = xdr->get64(&input); } else { shdr->sh_name = xdr->get32(&input); shdr->sh_type = xdr->get32(&input); shdr->sh_flags = xdr->get32(&input); shdr->sh_addr = xdr->get32(&input); shdr->sh_offset = xdr->get32(&input); shdr->sh_size = xdr->get32(&input); shdr->sh_link = xdr->get32(&input); shdr->sh_info = xdr->get32(&input); shdr->sh_addralign = xdr->get32(&input); shdr->sh_entsize = xdr->get32(&input); } buffer_seek(pinput, entsize); } static int phdr_read(const struct buffer *in, struct parsed_elf *pelf, struct xdr *xdr, int bit64) { struct buffer b; Elf64_Phdr *phdr; Elf64_Ehdr *ehdr; int i; ehdr = &pelf->ehdr; /* cons up an input buffer for the headers. * Note that the program headers can be anywhere, * per the ELF spec, You'd be surprised how many ELF * readers miss this little detail. */ buffer_splice(&b, in, ehdr->e_phoff, ehdr->e_phentsize * ehdr->e_phnum); if (check_size(in, ehdr->e_phoff, buffer_size(&b), "program headers")) return -1; /* gather up all the phdrs. * We do them all at once because there is more * than one loop over all the phdrs. */ phdr = calloc(ehdr->e_phnum, sizeof(*phdr)); for (i = 0; i < ehdr->e_phnum; i++) { DEBUG("Parsing segment %d\n", i); elf_phdr(&b, &phdr[i], ehdr->e_phentsize, xdr, bit64); /* Ensure the contents are valid within the elf file. */ if (check_size(in, phdr[i].p_offset, phdr[i].p_filesz, "segment contents")) return -1; } pelf->phdr = phdr; return 0; } static int shdr_read(const struct buffer *in, struct parsed_elf *pelf, struct xdr *xdr, int bit64) { struct buffer b; Elf64_Shdr *shdr; Elf64_Ehdr *ehdr; int i; ehdr = &pelf->ehdr; /* cons up an input buffer for the section headers. * Note that the section headers can be anywhere, * per the ELF spec, You'd be surprised how many ELF * readers miss this little detail. */ buffer_splice(&b, in, ehdr->e_shoff, ehdr->e_shentsize * ehdr->e_shnum); if (check_size(in, ehdr->e_shoff, buffer_size(&b), "section headers")) return -1; /* gather up all the shdrs. */ shdr = calloc(ehdr->e_shnum, sizeof(*shdr)); for (i = 0; i < ehdr->e_shnum; i++) { DEBUG("Parsing section %d\n", i); elf_shdr(&b, &shdr[i], ehdr->e_shentsize, xdr, bit64); } pelf->shdr = shdr; return 0; } static int reloc_read(const struct buffer *in, struct parsed_elf *pelf, struct xdr *xdr, int bit64) { struct buffer b; Elf64_Word i; Elf64_Ehdr *ehdr; ehdr = &pelf->ehdr; pelf->relocs = calloc(ehdr->e_shnum, sizeof(Elf64_Rela *)); /* Allocate array for each section that contains relocation entries. */ for (i = 0; i < ehdr->e_shnum; i++) { Elf64_Shdr *shdr; Elf64_Rela *rela; Elf64_Xword j; Elf64_Xword nrelocs; int is_rela; shdr = &pelf->shdr[i]; /* Only process REL and RELA sections. */ if (shdr->sh_type != SHT_REL && shdr->sh_type != SHT_RELA) continue; DEBUG("Checking relocation section %u\n", i); /* Ensure the section that relocations apply is a valid. */ if (shdr->sh_info >= ehdr->e_shnum || shdr->sh_info == SHN_UNDEF) { ERROR("Relocations apply to an invalid section: %u\n", shdr[i].sh_info); return -1; } is_rela = shdr->sh_type == SHT_RELA; /* Determine the number relocations in this section. */ nrelocs = shdr->sh_size / shdr->sh_entsize; pelf->relocs[i] = calloc(nrelocs, sizeof(Elf64_Rela)); buffer_splice(&b, in, shdr->sh_offset, shdr->sh_size); if (check_size(in, shdr->sh_offset, buffer_size(&b), "relocation section")) { ERROR("Relocation section %u failed.\n", i); return -1; } rela = pelf->relocs[i]; for (j = 0; j < nrelocs; j++) { if (bit64) { rela->r_offset = xdr->get64(&b); rela->r_info = xdr->get64(&b); if (is_rela) rela->r_addend = xdr->get64(&b); } else { uint32_t r_info; rela->r_offset = xdr->get32(&b); r_info = xdr->get32(&b); rela->r_info = ELF64_R_INFO(ELF32_R_SYM(r_info), ELF32_R_TYPE(r_info)); if (is_rela) rela->r_addend = xdr->get32(&b); } rela++; } } return 0; } static int strtab_read(const struct buffer *in, struct parsed_elf *pelf) { Elf64_Ehdr *ehdr; Elf64_Word i; ehdr = &pelf->ehdr; if (ehdr->e_shstrndx >= ehdr->e_shnum) { ERROR("Section header string table index out of range: %d\n", ehdr->e_shstrndx); return -1; } /* For each section of type SHT_STRTAB create a symtab buffer. */ pelf->strtabs = calloc(ehdr->e_shnum, sizeof(struct buffer *)); for (i = 0; i < ehdr->e_shnum; i++) { struct buffer *b; Elf64_Shdr *shdr = &pelf->shdr[i]; if (shdr->sh_type != SHT_STRTAB) continue; b = calloc(1, sizeof(*b)); buffer_splice(b, in, shdr->sh_offset, shdr->sh_size); if (check_size(in, shdr->sh_offset, buffer_size(b), "strtab")) { ERROR("STRTAB section not within bounds: %d\n", i); return -1; } pelf->strtabs[i] = b; } return 0; } static int symtab_read(const struct buffer *in, struct parsed_elf *pelf, struct xdr *xdr, int bit64) { Elf64_Ehdr *ehdr; Elf64_Shdr *shdr; Elf64_Half i; Elf64_Xword nsyms; Elf64_Sym *sym; struct buffer b; ehdr = &pelf->ehdr; shdr = NULL; for (i = 0; i < ehdr->e_shnum; i++) { if (pelf->shdr[i].sh_type != SHT_SYMTAB) continue; if (shdr != NULL) { ERROR("Multiple symbol sections found. %u and %u\n", (unsigned int)(shdr - pelf->shdr), i); return -1; } shdr = &pelf->shdr[i]; } if (shdr == NULL) { ERROR("No symbol table found.\n"); return -1; } buffer_splice(&b, in, shdr->sh_offset, shdr->sh_size); if (check_size(in, shdr->sh_offset, buffer_size(&b), "symtab")) return -1; nsyms = shdr->sh_size / shdr->sh_entsize; pelf->syms = calloc(nsyms, sizeof(Elf64_Sym)); for (i = 0; i < nsyms; i++) { sym = &pelf->syms[i]; if (bit64) { sym->st_name = xdr->get32(&b); sym->st_info = xdr->get8(&b); sym->st_other = xdr->get8(&b); sym->st_shndx = xdr->get16(&b); sym->st_value = xdr->get64(&b); sym->st_size = xdr->get64(&b); } else { sym->st_name = xdr->get32(&b); sym->st_value = xdr->get32(&b); sym->st_size = xdr->get32(&b); sym->st_info = xdr->get8(&b); sym->st_other = xdr->get8(&b); sym->st_shndx = xdr->get16(&b); } } return 0; } int parse_elf(const struct buffer *pinput, struct parsed_elf *pelf, int flags) { struct xdr *xdr = &xdr_le; int bit64 = 0; struct buffer input; Elf64_Ehdr *ehdr; /* Zero out the parsed elf structure. */ memset(pelf, 0, sizeof(*pelf)); if (!iself(buffer_get(pinput))) { ERROR("The stage file is not in ELF format!\n"); return -1; } buffer_clone(&input, pinput); ehdr = &pelf->ehdr; elf_eident(&input, ehdr); bit64 = ehdr->e_ident[EI_CLASS] == ELFCLASS64; /* Assume LE unless we are sure otherwise. * We're not going to take on the task of * fully validating the ELF file. That way * lies madness. */ if (ehdr->e_ident[EI_DATA] == ELFDATA2MSB) xdr = &xdr_be; elf_ehdr(&input, ehdr, xdr, bit64); /* Relocation processing requires section header parsing. */ if (flags & ELF_PARSE_RELOC) flags |= ELF_PARSE_SHDR; /* String table processing requires section header parsing. */ if (flags & ELF_PARSE_STRTAB) flags |= ELF_PARSE_SHDR; /* Symbole table processing requires section header parsing. */ if (flags & ELF_PARSE_SYMTAB) flags |= ELF_PARSE_SHDR; if ((flags & ELF_PARSE_PHDR) && phdr_read(pinput, pelf, xdr, bit64)) goto fail; if ((flags & ELF_PARSE_SHDR) && shdr_read(pinput, pelf, xdr, bit64)) goto fail; if ((flags & ELF_PARSE_RELOC) && reloc_read(pinput, pelf, xdr, bit64)) goto fail; if ((flags & ELF_PARSE_STRTAB) && strtab_read(pinput, pelf)) goto fail; if ((flags & ELF_PARSE_SYMTAB) && symtab_read(pinput, pelf, xdr, bit64)) goto fail; return 0; fail: parsed_elf_destroy(pelf); return -1; } void parsed_elf_destroy(struct parsed_elf *pelf) { Elf64_Half i; free(pelf->phdr); free(pelf->shdr); if (pelf->relocs != NULL) { for (i = 0; i < pelf->ehdr.e_shnum; i++) free(pelf->relocs[i]); } free(pelf->relocs); if (pelf->strtabs != NULL) { for (i = 0; i < pelf->ehdr.e_shnum; i++) free(pelf->strtabs[i]); } free(pelf->strtabs); free(pelf->syms); } /* Get the headers from the buffer. * Return -1 in the event of an error. * The section headers are optional; if NULL * is passed in for pshdr they won't be parsed. * We don't (yet) make payload parsing optional * because we've never seen a use case. */ int elf_headers(const struct buffer *pinput, uint32_t arch, Elf64_Ehdr *ehdr, Elf64_Phdr **pphdr, Elf64_Shdr **pshdr) { struct parsed_elf pelf; int flags; flags = ELF_PARSE_PHDR; if (pshdr != NULL) flags |= ELF_PARSE_SHDR; if (parse_elf(pinput, &pelf, flags)) return -1; /* Copy out the parsed elf header. */ memcpy(ehdr, &pelf.ehdr, sizeof(*ehdr)); // The tool may work in architecture-independent way. if (arch != CBFS_ARCHITECTURE_UNKNOWN && !((ehdr->e_machine == EM_ARM) && (arch == CBFS_ARCHITECTURE_ARMV7)) && !((ehdr->e_machine == EM_386) && (arch == CBFS_ARCHITECTURE_X86))) { ERROR("The stage file has the wrong architecture\n"); return -1; } *pphdr = calloc(ehdr->e_phnum, sizeof(Elf64_Phdr)); memcpy(*pphdr, pelf.phdr, ehdr->e_phnum * sizeof(Elf64_Phdr)); if (pshdr != NULL) { *pshdr = calloc(ehdr->e_shnum, sizeof(Elf64_Shdr)); memcpy(*pshdr, pelf.shdr, ehdr->e_shnum * sizeof(Elf64_Shdr)); } parsed_elf_destroy(&pelf); return 0; }