/* * common.c * * Created on: Aug 11, 2008 * Author: Stefan Bucur */ #include #include #include #include #include #include #include "elfutils.h" #include "common.h" /** * The one and only list of loaded modules */ LIST_HEAD(modules_head); // User-space debugging routines #ifdef ELF_DEBUG void print_elf_ehdr(Elf_Ehdr *ehdr) { int i; fprintf(stderr, "Identification:\t"); for (i=0; i < EI_NIDENT; i++) { printf("%d ", ehdr->e_ident[i]); } fprintf(stderr, "\n"); fprintf(stderr, "Type:\t\t%u\n", ehdr->e_type); fprintf(stderr, "Machine:\t%u\n", ehdr->e_machine); fprintf(stderr, "Version:\t%u\n", ehdr->e_version); fprintf(stderr, "Entry:\t\t0x%08x\n", ehdr->e_entry); fprintf(stderr, "PHT Offset:\t0x%08x\n", ehdr->e_phoff); fprintf(stderr, "SHT Offset:\t0x%08x\n", ehdr->e_shoff); //fprintf(stderr, "Flags:\t\t%u\n", ehdr->e_flags); //fprintf(stderr, "Header size:\t%u (Structure size: %u)\n", ehdr->e_ehsize,sizeof(Elf_Ehdr)); fprintf(stderr, "phnum: %d shnum: %d\n", ehdr->e_phnum, ehdr->e_shnum); } void print_elf_symbols(struct elf_module *module) { unsigned int i; Elf_Sym *crt_sym; for (i = 1; i < module->symtable_size/module->syment_size; i++) { crt_sym = (Elf_Sym*)(module->sym_table + i*module->syment_size); fprintf(stderr,"%s %d\n", module->str_table + crt_sym->st_name, crt_sym->st_value); } } #endif //ELF_DEBUG FILE *findpath(char *name) { struct path_entry *entry; char path[FILENAME_MAX]; FILE *f; f = fopen(name, "rb"); /* for full path */ if (f) return f; list_for_each_entry(entry, &PATH, list) { bool slash = false; /* Ensure we have a '/' separator */ if (entry->str[strlen(entry->str) - 1] != '/') slash = true; snprintf(path, sizeof(path), "%s%s%s", entry->str, slash ? "/" : "", name); dprintf("findpath: trying \"%s\"\n", path); f = fopen(path, "rb"); if (f) return f; } return NULL; } /* * Image files manipulation routines */ int image_load(struct elf_module *module) { module->u.l._file = findpath(module->name); if (module->u.l._file == NULL) { dprintf("Could not open object file '%s'\n", module->name); goto error; } module->u.l._cr_offset = 0; return 0; error: if (module->u.l._file != NULL) { fclose(module->u.l._file); module->u.l._file = NULL; } return -1; } int image_unload(struct elf_module *module) { if (module->u.l._file != NULL) { fclose(module->u.l._file); module->u.l._file = NULL; } module->u.l._cr_offset = 0; return 0; } int image_read(void *buff, size_t size, struct elf_module *module) { size_t result = fread(buff, size, 1, module->u.l._file); if (result < 1) return -1; module->u.l._cr_offset += size; return 0; } int image_skip(size_t size, struct elf_module *module) { void *skip_buff = NULL; size_t result; if (size == 0) return 0; skip_buff = malloc(size); result = fread(skip_buff, size, 1, module->u.l._file); free(skip_buff); if (result < 1) return -1; module->u.l._cr_offset += size; return 0; } int image_seek(Elf_Off offset, struct elf_module *module) { if (offset < module->u.l._cr_offset) // Cannot seek backwards return -1; return image_skip(offset - module->u.l._cr_offset, module); } // Initialization of the module subsystem int modules_init(void) { return 0; } // Termination of the module subsystem void modules_term(void) { } // Allocates the structure for a new module struct elf_module *module_alloc(const char *name) { struct elf_module *result = malloc(sizeof(struct elf_module)); if (!result) { dprintf("module: Failed to alloc elf_module\n"); return NULL; } memset(result, 0, sizeof(struct elf_module)); INIT_LIST_HEAD(&result->list); INIT_LIST_HEAD(&result->required); INIT_LIST_HEAD(&result->dependants); strncpy(result->name, name, MODULE_NAME_SIZE); return result; } struct module_dep *module_dep_alloc(struct elf_module *module) { struct module_dep *result = malloc(sizeof(struct module_dep)); INIT_LIST_HEAD (&result->list); result->module = module; return result; } struct elf_module *module_find(const char *name) { struct elf_module *cr_module; for_each_module(cr_module) { if (strcmp(cr_module->name, name) == 0) return cr_module; } return NULL; } // Mouli: This is checking the header for 32bit machine // Support 64bit architecture as well. // Parts of the ELF header checked are common to both ELF32 and ELF64 // Adding simple checks for both 32bit and 64bit should work (hopefully) // // Performs verifications on ELF header to assure that the open file is a // valid SYSLINUX ELF module. int check_header_common(Elf_Ehdr *elf_hdr) { // Check the header magic if (elf_hdr->e_ident[EI_MAG0] != ELFMAG0 || elf_hdr->e_ident[EI_MAG1] != ELFMAG1 || elf_hdr->e_ident[EI_MAG2] != ELFMAG2 || elf_hdr->e_ident[EI_MAG3] != ELFMAG3) { dprintf("The file is not an ELF object\n"); return -1; } if (elf_hdr->e_ident[EI_CLASS] != ELFCLASS32 && elf_hdr->e_ident[EI_CLASS] != ELFCLASS64) { dprintf("Invalid ELF class code\n"); return -1; } if (elf_hdr->e_ident[EI_DATA] != MODULE_ELF_DATA) { dprintf("Invalid ELF data encoding\n"); return -1; } if (elf_hdr->e_ident[EI_VERSION] != MODULE_ELF_VERSION || elf_hdr->e_version != MODULE_ELF_VERSION) { dprintf("Invalid ELF file version\n"); return -1; } if (elf_hdr->e_machine != EM_386 && elf_hdr->e_machine != EM_X86_64) { dprintf("Invalid ELF architecture\n"); return -1; } return 0; } int enforce_dependency(struct elf_module *req, struct elf_module *dep) { struct module_dep *crt_dep; struct module_dep *new_dep; list_for_each_entry(crt_dep, &req->dependants, list) { if (crt_dep->module == dep) { // The dependency is already enforced return 0; } } new_dep = module_dep_alloc(req); list_add(&new_dep->list, &dep->required); new_dep = module_dep_alloc(dep); list_add(&new_dep->list, &req->dependants); return 0; } int clear_dependency(struct elf_module *req, struct elf_module *dep) { struct module_dep *crt_dep = NULL; int found = 0; list_for_each_entry(crt_dep, &req->dependants, list) { if (crt_dep->module == dep) { found = 1; break; } } if (found) { list_del(&crt_dep->list); free(crt_dep); } found = 0; list_for_each_entry(crt_dep, &dep->required, list) { if (crt_dep->module == req) { found = 1; break; } } if (found) { list_del(&crt_dep->list); free(crt_dep); } return 0; } int check_symbols(struct elf_module *module) { unsigned int i; Elf_Sym *crt_sym = NULL, *ref_sym = NULL; char *crt_name; struct elf_module *crt_module; int strong_count; int weak_count; for (i = 1; i < module->symtable_size/module->syment_size; i++) { crt_sym = symbol_get_entry(module, i); crt_name = module->str_table + crt_sym->st_name; strong_count = 0; weak_count = (ELF32_ST_BIND(crt_sym->st_info) == STB_WEAK); for_each_module(crt_module) { ref_sym = module_find_symbol(crt_name, crt_module); // If we found a definition for our symbol... if (ref_sym != NULL && ref_sym->st_shndx != SHN_UNDEF) { switch (ELF32_ST_BIND(ref_sym->st_info)) { case STB_GLOBAL: strong_count++; break; case STB_WEAK: weak_count++; break; } } } if (crt_sym->st_shndx == SHN_UNDEF) { // We have an undefined symbol // // We use the weak_count to differentiate // between Syslinux-derivative-specific // functions. For example, unload_pxe() is // only provided by PXELINUX, so we mark it as // __weak and replace it with a reference to // undefined_symbol() on SYSLINUX, EXTLINUX, // and ISOLINUX. See perform_relocations(). if (strong_count == 0 && weak_count == 0) { dprintf("Symbol %s is undefined\n", crt_name); printf("Undef symbol FAIL: %s\n",crt_name); return -1; } } else { if (strong_count > 0 && ELF32_ST_BIND(ref_sym->st_info) == STB_GLOBAL) { // It's not an error - at relocation, the most recent symbol // will be considered dprintf("Info: Symbol %s is defined more than once\n", crt_name); } } //printf("symbol %s laoded from %d\n",crt_name,crt_sym->st_value); } return 0; } int module_unloadable(struct elf_module *module) { if (!list_empty(&module->dependants)) return 0; return 1; } // Unloads the module from the system and releases all the associated memory int _module_unload(struct elf_module *module) { struct module_dep *crt_dep, *tmp; // Make sure nobody needs us if (!module_unloadable(module)) { dprintf("Module is required by other modules.\n"); return -1; } // Remove any dependency information list_for_each_entry_safe(crt_dep, tmp, &module->required, list) { clear_dependency(crt_dep->module, module); } // Remove the module from the module list list_del_init(&module->list); // Release the loaded segments or sections if (module->module_addr != NULL) { elf_free(module->module_addr); dprintf("%s MODULE %s UNLOADED\n", module->shallow ? "SHALLOW" : "", module->name); } dprintf("Unloading module %s\n", module->name); // Release the module structure free(module); return 0; } int module_unload(struct elf_module *module) { module_ctor_t *dtor; for (dtor = module->dtors; dtor && *dtor; dtor++) (*dtor) (); return _module_unload(module); } struct elf_module *unload_modules_since(const char *name) { struct elf_module *m, *mod, *begin = NULL; for_each_module(mod) { if (!strcmp(mod->name, name)) { begin = mod; break; } } if (!begin) return begin; for_each_module_safe(mod, m) { if (mod == begin) break; if (mod != begin) module_unload(mod); } return begin; } static Elf_Sym *module_find_symbol_sysv(const char *name, struct elf_module *module) { unsigned long h = elf_hash((const unsigned char*)name); Elf_Word *cr_word = module->hash_table; Elf_Word nbucket = *cr_word++; cr_word++; // Skip nchain Elf_Word *bkt = cr_word; Elf_Word *chn = cr_word + nbucket; Elf_Word crt_index = bkt[h % module->hash_table[0]]; Elf_Sym *crt_sym; while (crt_index != STN_UNDEF) { crt_sym = symbol_get_entry(module, crt_index); if (strcmp(name, module->str_table + crt_sym->st_name) == 0) return crt_sym; crt_index = chn[crt_index]; } return NULL; } static Elf_Sym *module_find_symbol_gnu(const char *name, struct elf_module *module) { unsigned long h = elf_gnu_hash((const unsigned char*)name); // Setup code (TODO: Optimize this by computing only once) Elf_Word *cr_word = module->ghash_table; Elf_Word nbucket = *cr_word++; Elf_Word symbias = *cr_word++; Elf_Word bitmask_nwords = *cr_word++; if ((bitmask_nwords & (bitmask_nwords - 1)) != 0) { dprintf("Invalid GNU Hash structure\n"); return NULL; } Elf_Word gnu_shift = *cr_word++; Elf_Addr *gnu_bitmask = (Elf_Addr*)cr_word; cr_word += MODULE_ELF_CLASS_SIZE / 32 * bitmask_nwords; Elf_Word *gnu_buckets = cr_word; cr_word += nbucket; Elf_Word *gnu_chain_zero = cr_word - symbias; // Computations Elf_Bword bitmask_word = gnu_bitmask[(h / MODULE_ELF_CLASS_SIZE) & (bitmask_nwords - 1)]; unsigned int hashbit1 = h & (MODULE_ELF_CLASS_SIZE - 1); unsigned int hashbit2 = (h >> gnu_shift) & (MODULE_ELF_CLASS_SIZE - 1); if ((bitmask_word >> hashbit1) & (bitmask_word >> hashbit2) & 1) { unsigned long rem; Elf_Word bucket; rem = h % nbucket; bucket = gnu_buckets[rem]; if (bucket != 0) { const Elf_Word* hasharr = &gnu_chain_zero[bucket]; do { if (((*hasharr ^ h ) >> 1) == 0) { Elf_Sym *crt_sym = symbol_get_entry(module, (hasharr - gnu_chain_zero)); if (strcmp(name, module->str_table + crt_sym->st_name) == 0) { return crt_sym; } } } while ((*hasharr++ & 1u) == 0); } } return NULL; } static Elf_Sym *module_find_symbol_iterate(const char *name,struct elf_module *module) { unsigned int i; Elf_Sym *crt_sym; for (i = 1; i < module->symtable_size/module->syment_size; i++) { crt_sym = symbol_get_entry(module, i); if (strcmp(name, module->str_table + crt_sym->st_name) == 0) { return crt_sym; } } return NULL; } Elf_Sym *module_find_symbol(const char *name, struct elf_module *module) { Elf_Sym *result = NULL; if (module->ghash_table != NULL) result = module_find_symbol_gnu(name, module); if (result == NULL) { if (module->hash_table != NULL) { //printf("Attempting SYSV Symbol search\n"); result = module_find_symbol_sysv(name, module); } else { //printf("Attempting Iterative Symbol search\n"); result = module_find_symbol_iterate(name, module); } } return result; } Elf_Sym *global_find_symbol(const char *name, struct elf_module **module) { struct elf_module *crt_module; Elf_Sym *crt_sym = NULL; Elf_Sym *result = NULL; for_each_module(crt_module) { crt_sym = module_find_symbol(name, crt_module); if (crt_sym != NULL && crt_sym->st_shndx != SHN_UNDEF) { switch (ELF32_ST_BIND(crt_sym->st_info)) { case STB_GLOBAL: if (module != NULL) { *module = crt_module; } return crt_sym; case STB_WEAK: // Consider only the first weak symbol if (result == NULL) { if (module != NULL) { *module = crt_module; } result = crt_sym; } break; } } } return result; }