/* * 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. */ #include #include #include #include #include "elfparsing.h" #include "common.h" #include "cbfs.h" #include "rmodule.h" #include /* Checks if program segment contains the ignored section */ static int is_phdr_ignored(Elf64_Phdr *phdr, Elf64_Shdr *shdr) { /* If no ignored section, return false. */ if (shdr == NULL) return 0; Elf64_Addr sh_start = shdr->sh_addr; Elf64_Addr sh_end = shdr->sh_addr + shdr->sh_size; Elf64_Addr ph_start = phdr->p_vaddr; Elf64_Addr ph_end = phdr->p_vaddr + phdr->p_memsz; /* Return true only if section occupies whole of segment. */ if ((sh_start == ph_start) && (sh_end == ph_end)) { DEBUG("Ignoring program segment at 0x%" PRIx64 "\n", ph_start); return 1; } /* If shdr intersects phdr at all, its a conflict */ if (((sh_start >= ph_start) && (sh_start <= ph_end)) || ((sh_end >= ph_start) && (sh_end <= ph_end))) { ERROR("Conflicting sections in segment\n"); exit(1); } /* Program header doesn't need to be ignored. */ return 0; } /* Find section header based on ignored section name */ static Elf64_Shdr *find_ignored_section_header(struct parsed_elf *pelf, const char *ignore_section) { int i; const char *shstrtab; /* No section needs to be ignored */ if (ignore_section == NULL) return NULL; DEBUG("Section to be ignored: %s\n", ignore_section); /* Get pointer to string table */ shstrtab = buffer_get(pelf->strtabs[pelf->ehdr.e_shstrndx]); for (i = 0; i < pelf->ehdr.e_shnum; i++) { Elf64_Shdr *shdr; const char *section_name; shdr = &pelf->shdr[i]; section_name = &shstrtab[shdr->sh_name]; /* If section name matches ignored string, return shdr */ if (strcmp(section_name, ignore_section) == 0) return shdr; } /* No section matches ignore string */ return NULL; } static void fill_cbfs_stage(struct buffer *outheader, enum comp_algo algo, uint64_t entry, uint64_t loadaddr, uint32_t filesize, uint32_t memsize) { /* N.B. The original plan was that SELF data was B.E. * but: this is all L.E. * Maybe we should just change the spec. */ xdr_le.put32(outheader, algo); xdr_le.put64(outheader, entry); xdr_le.put64(outheader, loadaddr); xdr_le.put32(outheader, filesize); xdr_le.put32(outheader, memsize); } /* returns size of result, or -1 if error. * Note that, with the new code, this function * works for all elf files, not just the restricted set. */ int parse_elf_to_stage(const struct buffer *input, struct buffer *output, enum comp_algo algo, uint32_t *location, const char *ignore_section) { struct parsed_elf pelf; Elf64_Phdr *phdr; Elf64_Ehdr *ehdr; Elf64_Shdr *shdr_ignored; Elf64_Addr virt_to_phys; char *buffer; struct buffer outheader; int ret = -1; int headers; int i, outlen; uint64_t data_start, data_end, mem_end; comp_func_ptr compress = compression_function(algo); if (!compress) return -1; DEBUG("start: parse_elf_to_stage(location=0x%x)\n", *location); int flags = ELF_PARSE_PHDR | ELF_PARSE_SHDR | ELF_PARSE_STRTAB; if (parse_elf(input, &pelf, flags)) { ERROR("Couldn't parse ELF\n"); return -1; } ehdr = &pelf.ehdr; phdr = &pelf.phdr[0]; /* Find the section header corresponding to ignored-section */ shdr_ignored = find_ignored_section_header(&pelf, ignore_section); if (ignore_section && (shdr_ignored == NULL)) WARN("Ignore section not found\n"); headers = ehdr->e_phnum; /* Ignore the program header containing ignored section */ for (i = 0; i < headers; i++) { if (is_phdr_ignored(&phdr[i], shdr_ignored)) phdr[i].p_type = PT_NULL; } data_start = ~0; data_end = 0; mem_end = 0; virt_to_phys = 0; for (i = 0; i < headers; i++) { uint64_t start, mend, rend; if (phdr[i].p_type != PT_LOAD) continue; /* Empty segments are never interesting */ if (phdr[i].p_memsz == 0) continue; /* BSS */ start = phdr[i].p_paddr; mend = start + phdr[i].p_memsz; rend = start + phdr[i].p_filesz; if (start < data_start) data_start = start; if (rend > data_end) data_end = rend; if (mend > mem_end) mem_end = mend; if (virt_to_phys == 0) virt_to_phys = phdr[i].p_paddr - phdr[i].p_vaddr; } if (data_start < *location) { data_start = *location; } if (data_end <= data_start) { ERROR("data ends (%08lx) before it starts (%08lx). Make sure " "the ELF file is correct and resides in ROM space.\n", (unsigned long)data_end, (unsigned long)data_start); exit(1); } /* allocate an intermediate buffer for the data */ buffer = calloc(data_end - data_start, 1); if (buffer == NULL) { ERROR("Unable to allocate memory: %m\n"); goto err; } /* Copy the file data into the buffer */ for (i = 0; i < headers; i++) { uint64_t l_start, l_offset = 0; if (phdr[i].p_type != PT_LOAD) continue; if (phdr[i].p_memsz == 0) continue; l_start = phdr[i].p_paddr; if (l_start < *location) { l_offset = *location - l_start; l_start = *location; } /* A legal ELF file can have a program header with * non-zero length but zero-length file size and a * non-zero offset which, added together, are > than * input->size (i.e. the total file size). So we need * to not even test in the case that p_filesz is zero. */ if (! phdr[i].p_filesz) continue; if (input->size < (phdr[i].p_offset + phdr[i].p_filesz)){ ERROR("Underflow copying out the segment." "File has %zu bytes left, segment end is %zu\n", input->size, (size_t)(phdr[i].p_offset + phdr[i].p_filesz)); free(buffer); goto err; } memcpy(buffer + (l_start - data_start), &input->data[phdr[i].p_offset + l_offset], phdr[i].p_filesz - l_offset); } /* Now make the output buffer */ if (buffer_create(output, sizeof(struct cbfs_stage) + data_end - data_start, input->name) != 0) { ERROR("Unable to allocate memory: %m\n"); free(buffer); goto err; } memset(output->data, 0, output->size); /* Compress the data, at which point we'll know information * to fill out the header. This seems backward but it works because * - the output header is a known size (not always true in many xdr's) * - we do need to know the compressed output size first * If compression fails or makes the data bigger, we'll warn about it * and use the original data. */ if (compress(buffer, data_end - data_start, (output->data + sizeof(struct cbfs_stage)), &outlen) < 0 || (unsigned)outlen > data_end - data_start) { WARN("Compression failed or would make the data bigger " "- disabled.\n"); memcpy(output->data + sizeof(struct cbfs_stage), buffer, data_end - data_start); outlen = data_end - data_start; algo = CBFS_COMPRESS_NONE; } /* Check for enough BSS scratch space to decompress LZ4 in-place. */ if (algo == CBFS_COMPRESS_LZ4) { size_t result; size_t memlen = mem_end - data_start; size_t compressed_size = outlen; char *compare_buffer = malloc(memlen); char *start = compare_buffer + memlen - compressed_size; if (compare_buffer == NULL) { ERROR("Can't allocate memory!\n"); free(buffer); goto err; } memcpy(start, output->data + sizeof(struct cbfs_stage), compressed_size); result = ulz4fn(start, compressed_size, compare_buffer, memlen); if (result == 0) { ERROR("Not enough scratch space to decompress LZ4 in-place -- increase BSS size or disable compression!\n"); free(compare_buffer); free(buffer); goto err; } if (result != data_end - data_start || memcmp(compare_buffer, buffer, data_end - data_start)) { ERROR("LZ4 compression BUG! Report to mailing list.\n"); free(compare_buffer); free(buffer); goto err; } free(compare_buffer); } free(buffer); /* Set up for output marshaling. */ outheader.data = output->data; outheader.size = 0; /* coreboot expects entry point to be physical address. Thus, adjust the * entry point accordingly. */ fill_cbfs_stage(&outheader, algo, ehdr->e_entry + virt_to_phys, data_start, outlen, mem_end - data_start); if (*location) *location -= sizeof(struct cbfs_stage); output->size = sizeof(struct cbfs_stage) + outlen; ret = 0; err: parsed_elf_destroy(&pelf); return ret; } struct xip_context { struct rmod_context rmodctx; size_t ignored_section_idx; Elf64_Shdr *ignored_section; }; static int rmod_filter(struct reloc_filter *f, const Elf64_Rela *r) { size_t symbol_index; int reloc_type; struct parsed_elf *pelf; Elf64_Sym *sym; struct xip_context *xipctx; xipctx = f->context; pelf = &xipctx->rmodctx.pelf; /* Allow everything through if there isn't an ignored section. */ if (xipctx->ignored_section == NULL) return 1; reloc_type = ELF64_R_TYPE(r->r_info); symbol_index = ELF64_R_SYM(r->r_info); sym = &pelf->syms[symbol_index]; /* Nothing to filter. Relocation is not being applied to the * ignored section. */ if (sym->st_shndx != xipctx->ignored_section_idx) return 1; /* If there is any relocation to the ignored section that isn't * absolute fail as current assumptions are that all relocations * are absolute. */ if ((reloc_type != R_386_32) && (reloc_type != R_AMD64_64) && (reloc_type != R_AMD64_32)) { ERROR("Invalid reloc to ignored section: %x\n", reloc_type); return -1; } /* Relocation referencing ignored section. Don't emit it. */ return 0; } int parse_elf_to_xip_stage(const struct buffer *input, struct buffer *output, uint32_t *location, const char *ignore_section) { struct xip_context xipctx; struct rmod_context *rmodctx; struct reloc_filter filter; struct parsed_elf *pelf; size_t output_sz; uint32_t adjustment; struct buffer binput; struct buffer boutput; Elf64_Xword i; int ret = -1; xipctx.ignored_section_idx = 0; rmodctx = &xipctx.rmodctx; pelf = &rmodctx->pelf; if (rmodule_init(rmodctx, input)) return -1; /* Only support x86 / x86_64 XIP currently. */ if ((rmodctx->pelf.ehdr.e_machine != EM_386) && (rmodctx->pelf.ehdr.e_machine != EM_X86_64)) { ERROR("Only support XIP stages for x86/x86_64\n"); goto out; } xipctx.ignored_section = find_ignored_section_header(pelf, ignore_section); if (xipctx.ignored_section != NULL) xipctx.ignored_section_idx = xipctx.ignored_section - pelf->shdr; filter.filter = rmod_filter; filter.context = &xipctx; if (rmodule_collect_relocations(rmodctx, &filter)) goto out; output_sz = sizeof(struct cbfs_stage) + pelf->phdr->p_filesz; if (buffer_create(output, output_sz, input->name) != 0) { ERROR("Unable to allocate memory: %m\n"); goto out; } buffer_clone(&boutput, output); memset(buffer_get(&boutput), 0, output_sz); buffer_set_size(&boutput, 0); /* Single loadable segment. The entire segment moves to final * location from based on virtual address of loadable segment. */ adjustment = *location - pelf->phdr->p_vaddr; DEBUG("Relocation adjustment: %08x\n", adjustment); fill_cbfs_stage(&boutput, CBFS_COMPRESS_NONE, (uint32_t)pelf->ehdr.e_entry + adjustment, (uint32_t)pelf->phdr->p_vaddr + adjustment, pelf->phdr->p_filesz, pelf->phdr->p_memsz); /* Need an adjustable buffer. */ buffer_clone(&binput, input); buffer_seek(&binput, pelf->phdr->p_offset); bputs(&boutput, buffer_get(&binput), pelf->phdr->p_filesz); buffer_clone(&boutput, output); buffer_seek(&boutput, sizeof(struct cbfs_stage)); /* Make adjustments to all the relocations within the program. */ for (i = 0; i < rmodctx->nrelocs; i++) { size_t reloc_offset; uint32_t val; struct buffer in, out; /* The relocations represent in-program addresses of the * linked program. Obtain the offset into the program to do * the adjustment. */ reloc_offset = rmodctx->emitted_relocs[i] - pelf->phdr->p_vaddr; buffer_clone(&out, &boutput); buffer_seek(&out, reloc_offset); buffer_clone(&in, &out); /* Appease around xdr semantics: xdr decrements buffer * size when get()ing and appends to size when put()ing. */ buffer_set_size(&out, 0); val = xdr_le.get32(&in); DEBUG("reloc %zx %08x -> %08x\n", reloc_offset, val, val + adjustment); xdr_le.put32(&out, val + adjustment); } /* Need to back up the location to include cbfs stage metadata. */ *location -= sizeof(struct cbfs_stage); ret = 0; out: rmodule_cleanup(rmodctx); return ret; }