/* * File elf.c - processing of ELF files * * Copyright (C) 1996, Eric Youngdale. * 1999-2007 Eric Pouech * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include "config.h" #include "wine/port.h" #if defined(__svr4__) || defined(__sun) #define __ELF__ 1 /* large files are not supported by libelf */ #undef _FILE_OFFSET_BITS #define _FILE_OFFSET_BITS 32 #endif #include #include #include #ifdef HAVE_SYS_STAT_H # include #endif #include #ifdef HAVE_SYS_MMAN_H #include #endif #ifdef HAVE_UNISTD_H # include #endif #ifndef PATH_MAX #define PATH_MAX MAX_PATH #endif #include "dbghelp_private.h" #include "image_private.h" #include "wine/library.h" #include "wine/debug.h" #ifdef __ELF__ #define ELF_INFO_DEBUG_HEADER 0x0001 #define ELF_INFO_MODULE 0x0002 #define ELF_INFO_NAME 0x0004 WINE_DEFAULT_DEBUG_CHANNEL(dbghelp); struct elf_info { unsigned flags; /* IN one (or several) of the ELF_INFO constants */ DWORD_PTR dbg_hdr_addr; /* OUT address of debug header (if ELF_INFO_DEBUG_HEADER is set) */ struct module* module; /* OUT loaded module (if ELF_INFO_MODULE is set) */ const WCHAR* module_name; /* OUT found module name (if ELF_INFO_NAME is set) */ }; struct symtab_elt { struct hash_table_elt ht_elt; const Elf_Sym* symp; struct symt_compiland* compiland; unsigned used; }; struct elf_thunk_area { const char* symname; THUNK_ORDINAL ordinal; unsigned long rva_start; unsigned long rva_end; }; struct elf_module_info { unsigned long elf_addr; unsigned short elf_mark : 1, elf_loader : 1; struct image_file_map file_map; }; /****************************************************************** * elf_map_section * * Maps a single section into memory from an ELF file */ const char* elf_map_section(struct image_section_map* ism) { struct elf_file_map* fmap = &ism->fmap->u.elf; unsigned long pgsz = getpagesize(); unsigned long ofst, size; assert(ism->fmap->modtype == DMT_ELF); if (ism->sidx < 0 || ism->sidx >= ism->fmap->u.elf.elfhdr.e_shnum || fmap->sect[ism->sidx].shdr.sh_type == SHT_NOBITS) return IMAGE_NO_MAP; /* align required information on page size (we assume pagesize is a power of 2) */ ofst = fmap->sect[ism->sidx].shdr.sh_offset & ~(pgsz - 1); size = ((fmap->sect[ism->sidx].shdr.sh_offset + fmap->sect[ism->sidx].shdr.sh_size + pgsz - 1) & ~(pgsz - 1)) - ofst; fmap->sect[ism->sidx].mapped = mmap(NULL, size, PROT_READ, MAP_PRIVATE, fmap->fd, ofst); if (fmap->sect[ism->sidx].mapped == IMAGE_NO_MAP) return IMAGE_NO_MAP; return fmap->sect[ism->sidx].mapped + (fmap->sect[ism->sidx].shdr.sh_offset & (pgsz - 1)); } /****************************************************************** * elf_find_section * * Finds a section by name (and type) into memory from an ELF file * or its alternate if any */ BOOL elf_find_section(struct image_file_map* _fmap, const char* name, unsigned sht, struct image_section_map* ism) { struct elf_file_map* fmap; unsigned i; while (_fmap) { fmap = &_fmap->u.elf; if (fmap->shstrtab == IMAGE_NO_MAP) { struct image_section_map hdr_ism = {_fmap, fmap->elfhdr.e_shstrndx}; if ((fmap->shstrtab = elf_map_section(&hdr_ism)) == IMAGE_NO_MAP) break; } for (i = 0; i < fmap->elfhdr.e_shnum; i++) { if (strcmp(fmap->shstrtab + fmap->sect[i].shdr.sh_name, name) == 0 && (sht == SHT_NULL || sht == fmap->sect[i].shdr.sh_type)) { ism->fmap = _fmap; ism->sidx = i; return TRUE; } } _fmap = fmap->alternate; } ism->fmap = NULL; ism->sidx = -1; return FALSE; } /****************************************************************** * elf_unmap_section * * Unmaps a single section from memory */ void elf_unmap_section(struct image_section_map* ism) { struct elf_file_map* fmap = &ism->fmap->u.elf; if (ism->sidx >= 0 && ism->sidx < fmap->elfhdr.e_shnum && fmap->sect[ism->sidx].mapped != IMAGE_NO_MAP) { unsigned long pgsz = getpagesize(); unsigned long ofst, size; ofst = fmap->sect[ism->sidx].shdr.sh_offset & ~(pgsz - 1); size = ((fmap->sect[ism->sidx].shdr.sh_offset + fmap->sect[ism->sidx].shdr.sh_size + pgsz - 1) & ~(pgsz - 1)) - ofst; if (munmap((char*)fmap->sect[ism->sidx].mapped, size) < 0) WARN("Couldn't unmap the section\n"); fmap->sect[ism->sidx].mapped = IMAGE_NO_MAP; } } static void elf_end_find(struct image_file_map* fmap) { struct image_section_map ism; while (fmap) { ism.fmap = fmap; ism.sidx = fmap->u.elf.elfhdr.e_shstrndx; elf_unmap_section(&ism); fmap->u.elf.shstrtab = IMAGE_NO_MAP; fmap = fmap->u.elf.alternate; } } /****************************************************************** * elf_get_map_rva * * Get the RVA of an ELF section */ DWORD_PTR elf_get_map_rva(const struct image_section_map* ism) { if (ism->sidx < 0 || ism->sidx >= ism->fmap->u.elf.elfhdr.e_shnum) return 0; return ism->fmap->u.elf.sect[ism->sidx].shdr.sh_addr - ism->fmap->u.elf.elf_start; } /****************************************************************** * elf_get_map_size * * Get the size of an ELF section */ unsigned elf_get_map_size(const struct image_section_map* ism) { if (ism->sidx < 0 || ism->sidx >= ism->fmap->u.elf.elfhdr.e_shnum) return 0; return ism->fmap->u.elf.sect[ism->sidx].shdr.sh_size; } static inline void elf_reset_file_map(struct image_file_map* fmap) { fmap->u.elf.fd = -1; fmap->u.elf.shstrtab = IMAGE_NO_MAP; fmap->u.elf.alternate = NULL; } /****************************************************************** * elf_map_file * * Maps an ELF file into memory (and checks it's a real ELF file) */ static BOOL elf_map_file(const WCHAR* filenameW, struct image_file_map* fmap) { static const BYTE elf_signature[4] = { ELFMAG0, ELFMAG1, ELFMAG2, ELFMAG3 }; struct stat statbuf; int i; Elf_Phdr phdr; unsigned long tmp, page_mask = getpagesize() - 1; char* filename; unsigned len; BOOL ret = FALSE; len = WideCharToMultiByte(CP_UNIXCP, 0, filenameW, -1, NULL, 0, NULL, NULL); if (!(filename = HeapAlloc(GetProcessHeap(), 0, len))) return FALSE; WideCharToMultiByte(CP_UNIXCP, 0, filenameW, -1, filename, len, NULL, NULL); elf_reset_file_map(fmap); fmap->modtype = DMT_ELF; /* check that the file exists, and that the module hasn't been loaded yet */ if (stat(filename, &statbuf) == -1 || S_ISDIR(statbuf.st_mode)) goto done; /* Now open the file, so that we can mmap() it. */ if ((fmap->u.elf.fd = open(filename, O_RDONLY)) == -1) goto done; if (read(fmap->u.elf.fd, &fmap->u.elf.elfhdr, sizeof(fmap->u.elf.elfhdr)) != sizeof(fmap->u.elf.elfhdr)) goto done; /* and check for an ELF header */ if (memcmp(fmap->u.elf.elfhdr.e_ident, elf_signature, sizeof(elf_signature))) goto done; /* and check 32 vs 64 size according to current machine */ #ifdef _WIN64 if (fmap->u.elf.elfhdr.e_ident[EI_CLASS] != ELFCLASS64) goto done; #else if (fmap->u.elf.elfhdr.e_ident[EI_CLASS] != ELFCLASS32) goto done; #endif fmap->u.elf.sect = HeapAlloc(GetProcessHeap(), 0, fmap->u.elf.elfhdr.e_shnum * sizeof(fmap->u.elf.sect[0])); if (!fmap->u.elf.sect) goto done; lseek(fmap->u.elf.fd, fmap->u.elf.elfhdr.e_shoff, SEEK_SET); for (i = 0; i < fmap->u.elf.elfhdr.e_shnum; i++) { if (read(fmap->u.elf.fd, &fmap->u.elf.sect[i].shdr, sizeof(fmap->u.elf.sect[i].shdr)) != sizeof(fmap->u.elf.sect[i].shdr)) { HeapFree(GetProcessHeap(), 0, fmap->u.elf.sect); fmap->u.elf.sect = NULL; goto done; } fmap->u.elf.sect[i].mapped = IMAGE_NO_MAP; } /* grab size of module once loaded in memory */ lseek(fmap->u.elf.fd, fmap->u.elf.elfhdr.e_phoff, SEEK_SET); fmap->u.elf.elf_size = 0; fmap->u.elf.elf_start = ~0L; for (i = 0; i < fmap->u.elf.elfhdr.e_phnum; i++) { if (read(fmap->u.elf.fd, &phdr, sizeof(phdr)) == sizeof(phdr) && phdr.p_type == PT_LOAD) { tmp = (phdr.p_vaddr + phdr.p_memsz + page_mask) & ~page_mask; if (fmap->u.elf.elf_size < tmp) fmap->u.elf.elf_size = tmp; if (phdr.p_vaddr < fmap->u.elf.elf_start) fmap->u.elf.elf_start = phdr.p_vaddr; } } /* if non relocatable ELF, then remove fixed address from computation * otherwise, all addresses are zero based and start has no effect */ fmap->u.elf.elf_size -= fmap->u.elf.elf_start; ret = TRUE; done: HeapFree(GetProcessHeap(), 0, filename); return ret; } /****************************************************************** * elf_unmap_file * * Unmaps an ELF file from memory (previously mapped with elf_map_file) */ static void elf_unmap_file(struct image_file_map* fmap) { while (fmap) { if (fmap->u.elf.fd != -1) { struct image_section_map ism; ism.fmap = fmap; for (ism.sidx = 0; ism.sidx < fmap->u.elf.elfhdr.e_shnum; ism.sidx++) { elf_unmap_section(&ism); } HeapFree(GetProcessHeap(), 0, fmap->u.elf.sect); close(fmap->u.elf.fd); } fmap = fmap->u.elf.alternate; } } static void elf_module_remove(struct process* pcs, struct module_format* modfmt) { elf_unmap_file(&modfmt->u.elf_info->file_map); HeapFree(GetProcessHeap(), 0, modfmt); } /****************************************************************** * elf_is_in_thunk_area * * Check whether an address lies within one of the thunk area we * know of. */ int elf_is_in_thunk_area(unsigned long addr, const struct elf_thunk_area* thunks) { unsigned i; if (thunks) for (i = 0; thunks[i].symname; i++) { if (addr >= thunks[i].rva_start && addr < thunks[i].rva_end) return i; } return -1; } /****************************************************************** * elf_hash_symtab * * creating an internal hash table to ease use ELF symtab information lookup */ static void elf_hash_symtab(struct module* module, struct pool* pool, struct hash_table* ht_symtab, struct image_file_map* fmap, struct elf_thunk_area* thunks) { int i, j, nsym; const char* strp; const char* symname; struct symt_compiland* compiland = NULL; const char* ptr; const Elf_Sym* symp; struct symtab_elt* ste; struct image_section_map ism, ism_str; if (!elf_find_section(fmap, ".symtab", SHT_SYMTAB, &ism) && !elf_find_section(fmap, ".dynsym", SHT_DYNSYM, &ism)) return; if ((symp = (const Elf_Sym*)image_map_section(&ism)) == IMAGE_NO_MAP) return; ism_str.fmap = ism.fmap; ism_str.sidx = fmap->u.elf.sect[ism.sidx].shdr.sh_link; if ((strp = image_map_section(&ism_str)) == IMAGE_NO_MAP) { image_unmap_section(&ism); return; } nsym = image_get_map_size(&ism) / sizeof(*symp); for (j = 0; thunks[j].symname; j++) thunks[j].rva_start = thunks[j].rva_end = 0; for (i = 0; i < nsym; i++, symp++) { /* Ignore certain types of entries which really aren't of that much * interest. */ if ((ELF32_ST_TYPE(symp->st_info) != STT_NOTYPE && ELF32_ST_TYPE(symp->st_info) != STT_FILE && ELF32_ST_TYPE(symp->st_info) != STT_OBJECT && ELF32_ST_TYPE(symp->st_info) != STT_FUNC) || symp->st_shndx == SHN_UNDEF) { continue; } symname = strp + symp->st_name; /* handle some specific symtab (that we'll throw away when done) */ switch (ELF32_ST_TYPE(symp->st_info)) { case STT_FILE: if (symname) compiland = symt_new_compiland(module, symp->st_value, source_new(module, NULL, symname)); else compiland = NULL; continue; case STT_NOTYPE: /* we are only interested in wine markers inserted by winebuild */ for (j = 0; thunks[j].symname; j++) { if (!strcmp(symname, thunks[j].symname)) { thunks[j].rva_start = symp->st_value; thunks[j].rva_end = symp->st_value + symp->st_size; break; } } continue; } /* FIXME: we don't need to handle them (GCC internals) * Moreover, they screw up our symbol lookup :-/ */ if (symname[0] == '.' && symname[1] == 'L' && isdigit(symname[2])) continue; ste = pool_alloc(pool, sizeof(*ste)); ste->ht_elt.name = symname; /* GCC emits, in some cases, a .+ suffix. * This is used for static variable inside functions, so * that we can have several such variables with same name in * the same compilation unit * We simply ignore that suffix when present (we also get rid * of it in stabs parsing) */ ptr = symname + strlen(symname) - 1; if (isdigit(*ptr)) { while (isdigit(*ptr) && ptr >= symname) ptr--; if (ptr > symname && *ptr == '.') { char* n = pool_alloc(pool, ptr - symname + 1); memcpy(n, symname, ptr - symname + 1); n[ptr - symname] = '\0'; ste->ht_elt.name = n; } } ste->symp = symp; ste->compiland = compiland; ste->used = 0; hash_table_add(ht_symtab, &ste->ht_elt); } /* as we added in the ht_symtab pointers to the symbols themselves, * we cannot unmap yet the sections, it will be done when we're over * with this ELF file */ } /****************************************************************** * elf_lookup_symtab * * lookup a symbol by name in our internal hash table for the symtab */ static const Elf_Sym* elf_lookup_symtab(const struct module* module, const struct hash_table* ht_symtab, const char* name, const struct symt* compiland) { struct symtab_elt* weak_result = NULL; /* without compiland name */ struct symtab_elt* result = NULL; struct hash_table_iter hti; struct symtab_elt* ste; const char* compiland_name; const char* compiland_basename; const char* base; /* we need weak match up (at least) when symbols of same name, * defined several times in different compilation units, * are merged in a single one (hence a different filename for c.u.) */ if (compiland) { compiland_name = source_get(module, ((const struct symt_compiland*)compiland)->source); compiland_basename = strrchr(compiland_name, '/'); if (!compiland_basename++) compiland_basename = compiland_name; } else compiland_name = compiland_basename = NULL; hash_table_iter_init(ht_symtab, &hti, name); while ((ste = hash_table_iter_up(&hti))) { if (ste->used || strcmp(ste->ht_elt.name, name)) continue; weak_result = ste; if ((ste->compiland && !compiland_name) || (!ste->compiland && compiland_name)) continue; if (ste->compiland && compiland_name) { const char* filename = source_get(module, ste->compiland->source); if (strcmp(filename, compiland_name)) { base = strrchr(filename, '/'); if (!base++) base = filename; if (strcmp(base, compiland_basename)) continue; } } if (result) { FIXME("Already found symbol %s (%s) in symtab %s @%08x and %s @%08x\n", name, compiland_name, source_get(module, result->compiland->source), (unsigned int)result->symp->st_value, source_get(module, ste->compiland->source), (unsigned int)ste->symp->st_value); } else { result = ste; ste->used = 1; } } if (!result && !(result = weak_result)) { FIXME("Couldn't find symbol %s!%s in symtab\n", debugstr_w(module->module.ModuleName), name); return NULL; } return result->symp; } /****************************************************************** * elf_finish_stabs_info * * - get any relevant information (address & size) from the bits we got from the * stabs debugging information */ static void elf_finish_stabs_info(struct module* module, const struct hash_table* symtab) { struct hash_table_iter hti; void* ptr; struct symt_ht* sym; const Elf_Sym* symp; struct elf_module_info* elf_info = module->format_info[DFI_ELF]->u.elf_info; hash_table_iter_init(&module->ht_symbols, &hti, NULL); while ((ptr = hash_table_iter_up(&hti))) { sym = GET_ENTRY(ptr, struct symt_ht, hash_elt); switch (sym->symt.tag) { case SymTagFunction: if (((struct symt_function*)sym)->address != elf_info->elf_addr && ((struct symt_function*)sym)->size) { break; } symp = elf_lookup_symtab(module, symtab, sym->hash_elt.name, ((struct symt_function*)sym)->container); if (symp) { if (((struct symt_function*)sym)->address != elf_info->elf_addr && ((struct symt_function*)sym)->address != elf_info->elf_addr + symp->st_value) FIXME("Changing address for %p/%s!%s from %08lx to %08lx\n", sym, debugstr_w(module->module.ModuleName), sym->hash_elt.name, ((struct symt_function*)sym)->address, elf_info->elf_addr + symp->st_value); if (((struct symt_function*)sym)->size && ((struct symt_function*)sym)->size != symp->st_size) FIXME("Changing size for %p/%s!%s from %08lx to %08x\n", sym, debugstr_w(module->module.ModuleName), sym->hash_elt.name, ((struct symt_function*)sym)->size, (unsigned int)symp->st_size); ((struct symt_function*)sym)->address = elf_info->elf_addr + symp->st_value; ((struct symt_function*)sym)->size = symp->st_size; } else FIXME("Couldn't find %s!%s\n", debugstr_w(module->module.ModuleName), sym->hash_elt.name); break; case SymTagData: switch (((struct symt_data*)sym)->kind) { case DataIsGlobal: case DataIsFileStatic: if (((struct symt_data*)sym)->u.var.offset != elf_info->elf_addr) break; symp = elf_lookup_symtab(module, symtab, sym->hash_elt.name, ((struct symt_data*)sym)->container); if (symp) { if (((struct symt_data*)sym)->u.var.offset != elf_info->elf_addr && ((struct symt_data*)sym)->u.var.offset != elf_info->elf_addr + symp->st_value) FIXME("Changing address for %p/%s!%s from %08lx to %08lx\n", sym, debugstr_w(module->module.ModuleName), sym->hash_elt.name, ((struct symt_function*)sym)->address, elf_info->elf_addr + symp->st_value); ((struct symt_data*)sym)->u.var.offset = elf_info->elf_addr + symp->st_value; ((struct symt_data*)sym)->kind = (ELF32_ST_BIND(symp->st_info) == STB_LOCAL) ? DataIsFileStatic : DataIsGlobal; } else FIXME("Couldn't find %s!%s\n", debugstr_w(module->module.ModuleName), sym->hash_elt.name); break; default:; } break; default: FIXME("Unsupported tag %u\n", sym->symt.tag); break; } } /* since we may have changed some addresses & sizes, mark the module to be resorted */ module->sortlist_valid = FALSE; } /****************************************************************** * elf_load_wine_thunks * * creating the thunk objects for a wine native DLL */ static int elf_new_wine_thunks(struct module* module, const struct hash_table* ht_symtab, const struct elf_thunk_area* thunks) { int j; struct hash_table_iter hti; struct symtab_elt* ste; DWORD_PTR addr; struct symt_ht* symt; hash_table_iter_init(ht_symtab, &hti, NULL); while ((ste = hash_table_iter_up(&hti))) { if (ste->used) continue; addr = module->reloc_delta + ste->symp->st_value; j = elf_is_in_thunk_area(ste->symp->st_value, thunks); if (j >= 0) /* thunk found */ { symt_new_thunk(module, ste->compiland, ste->ht_elt.name, thunks[j].ordinal, addr, ste->symp->st_size); } else { ULONG64 ref_addr; symt = symt_find_nearest(module, addr); if (symt && !symt_get_info(module, &symt->symt, TI_GET_ADDRESS, &ref_addr)) ref_addr = addr; if (!symt || addr != ref_addr) { /* creating public symbols for all the ELF symbols which haven't been * used yet (ie we have no debug information on them) * That's the case, for example, of the .spec.c files */ switch (ELF32_ST_TYPE(ste->symp->st_info)) { case STT_FUNC: symt_new_function(module, ste->compiland, ste->ht_elt.name, addr, ste->symp->st_size, NULL); break; case STT_OBJECT: symt_new_global_variable(module, ste->compiland, ste->ht_elt.name, ELF32_ST_BIND(ste->symp->st_info) == STB_LOCAL, addr, ste->symp->st_size, NULL); break; default: FIXME("Shouldn't happen\n"); break; } /* FIXME: this is a hack !!! * we are adding new symbols, but as we're parsing a symbol table * (hopefully without duplicate symbols) we delay rebuilding the sorted * module table until we're done with the symbol table * Otherwise, as we intertwine symbols's add and lookup, performance * is rather bad */ module->sortlist_valid = TRUE; } else if (strcmp(ste->ht_elt.name, symt->hash_elt.name)) { ULONG64 xaddr = 0, xsize = 0; DWORD kind = -1; symt_get_info(module, &symt->symt, TI_GET_ADDRESS, &xaddr); symt_get_info(module, &symt->symt, TI_GET_LENGTH, &xsize); symt_get_info(module, &symt->symt, TI_GET_DATAKIND, &kind); /* If none of symbols has a correct size, we consider they are both markers * Hence, we can silence this warning * Also, we check that we don't have two symbols, one local, the other * global which is legal */ if ((xsize || ste->symp->st_size) && (kind == (ELF32_ST_BIND(ste->symp->st_info) == STB_LOCAL) ? DataIsFileStatic : DataIsGlobal)) FIXME("Duplicate in %s: %s<%08lx-%08x> %s<%s-%s>\n", debugstr_w(module->module.ModuleName), ste->ht_elt.name, addr, (unsigned int)ste->symp->st_size, symt->hash_elt.name, wine_dbgstr_longlong(xaddr), wine_dbgstr_longlong(xsize)); } } } /* see comment above */ module->sortlist_valid = FALSE; return TRUE; } /****************************************************************** * elf_new_public_symbols * * Creates a set of public symbols from an ELF symtab */ static int elf_new_public_symbols(struct module* module, const struct hash_table* symtab) { struct hash_table_iter hti; struct symtab_elt* ste; if (dbghelp_options & SYMOPT_NO_PUBLICS) return TRUE; /* FIXME: we're missing the ELF entry point here */ hash_table_iter_init(symtab, &hti, NULL); while ((ste = hash_table_iter_up(&hti))) { symt_new_public(module, ste->compiland, ste->ht_elt.name, module->reloc_delta + ste->symp->st_value, ste->symp->st_size); } return TRUE; } static BOOL elf_check_debug_link(const WCHAR* file, struct image_file_map* fmap, DWORD crc) { BOOL ret; if (!elf_map_file(file, fmap)) return FALSE; if (!(ret = crc == calc_crc32(fmap->u.elf.fd))) { WARN("Bad CRC for file %s (got %08x while expecting %08x)\n", debugstr_w(file), calc_crc32(fmap->u.elf.fd), crc); elf_unmap_file(fmap); } return ret; } /****************************************************************** * elf_locate_debug_link * * Locate a filename from a .gnu_debuglink section, using the same * strategy as gdb: * "If the full name of the directory containing the executable is * execdir, and the executable has a debug link that specifies the * name debugfile, then GDB will automatically search for the * debugging information file in three places: * - the directory containing the executable file (that is, it * will look for a file named `execdir/debugfile', * - a subdirectory of that directory named `.debug' (that is, the * file `execdir/.debug/debugfile', and * - a subdirectory of the global debug file directory that includes * the executable's full path, and the name from the link (that is, * the file `globaldebugdir/execdir/debugfile', where globaldebugdir * is the global debug file directory, and execdir has been turned * into a relative path)." (from GDB manual) */ static BOOL elf_locate_debug_link(struct image_file_map* fmap, const char* filename, const WCHAR* loaded_file, DWORD crc) { static const WCHAR globalDebugDirW[] = {'/','u','s','r','/','l','i','b','/','d','e','b','u','g','/'}; static const WCHAR dotDebugW[] = {'.','d','e','b','u','g','/'}; const size_t globalDebugDirLen = sizeof(globalDebugDirW) / sizeof(WCHAR); size_t filename_len; WCHAR* p = NULL; WCHAR* slash; struct image_file_map* fmap_link = NULL; fmap_link = HeapAlloc(GetProcessHeap(), 0, sizeof(*fmap_link)); if (!fmap_link) return FALSE; filename_len = MultiByteToWideChar(CP_UNIXCP, 0, filename, -1, NULL, 0); p = HeapAlloc(GetProcessHeap(), 0, (globalDebugDirLen + strlenW(loaded_file) + 6 + 1 + filename_len + 1) * sizeof(WCHAR)); if (!p) goto found; /* we prebuild the string with "execdir" */ strcpyW(p, loaded_file); slash = strrchrW(p, '/'); if (slash == NULL) slash = p; else slash++; /* testing execdir/filename */ MultiByteToWideChar(CP_UNIXCP, 0, filename, -1, slash, filename_len); if (elf_check_debug_link(p, fmap_link, crc)) goto found; /* testing execdir/.debug/filename */ memcpy(slash, dotDebugW, sizeof(dotDebugW)); MultiByteToWideChar(CP_UNIXCP, 0, filename, -1, slash + sizeof(dotDebugW) / sizeof(WCHAR), filename_len); if (elf_check_debug_link(p, fmap_link, crc)) goto found; /* testing globaldebugdir/execdir/filename */ memmove(p + globalDebugDirLen, p, (slash - p) * sizeof(WCHAR)); memcpy(p, globalDebugDirW, globalDebugDirLen * sizeof(WCHAR)); slash += globalDebugDirLen; MultiByteToWideChar(CP_UNIXCP, 0, filename, -1, slash, filename_len); if (elf_check_debug_link(p, fmap_link, crc)) goto found; /* finally testing filename */ if (elf_check_debug_link(slash, fmap_link, crc)) goto found; WARN("Couldn't locate or map %s\n", filename); HeapFree(GetProcessHeap(), 0, p); HeapFree(GetProcessHeap(), 0, fmap_link); return FALSE; found: TRACE("Located debug information file %s at %s\n", filename, debugstr_w(p)); HeapFree(GetProcessHeap(), 0, p); fmap->u.elf.alternate = fmap_link; return TRUE; } /****************************************************************** * elf_debuglink_parse * * Parses a .gnu_debuglink section and loads the debug info from * the external file specified there. */ static BOOL elf_debuglink_parse(struct image_file_map* fmap, const struct module* module, const BYTE* debuglink) { /* The content of a debug link section is: * 1/ a NULL terminated string, containing the file name for the * debug info * 2/ padding on 4 byte boundary * 3/ CRC of the linked ELF file */ const char* dbg_link = (const char*)debuglink; DWORD crc; crc = *(const DWORD*)(dbg_link + ((DWORD_PTR)(strlen(dbg_link) + 4) & ~3)); return elf_locate_debug_link(fmap, dbg_link, module->module.LoadedImageName, crc); } /****************************************************************** * elf_load_debug_info_from_map * * Loads the symbolic information from ELF module which mapping is described * in fmap * the module has been loaded at 'load_offset' address, so symbols' address * relocation is performed. * CRC is checked if fmap->with_crc is TRUE * returns * 0 if the file doesn't contain symbolic info (or this info cannot be * read or parsed) * 1 on success */ static BOOL elf_load_debug_info_from_map(struct module* module, struct image_file_map* fmap, struct pool* pool, struct hash_table* ht_symtab) { BOOL ret = FALSE, lret; struct elf_thunk_area thunks[] = { {"__wine_spec_import_thunks", THUNK_ORDINAL_NOTYPE, 0, 0}, /* inter DLL calls */ {"__wine_spec_delayed_import_loaders", THUNK_ORDINAL_LOAD, 0, 0}, /* delayed inter DLL calls */ {"__wine_spec_delayed_import_thunks", THUNK_ORDINAL_LOAD, 0, 0}, /* delayed inter DLL calls */ {"__wine_delay_load", THUNK_ORDINAL_LOAD, 0, 0}, /* delayed inter DLL calls */ {"__wine_spec_thunk_text_16", -16, 0, 0}, /* 16 => 32 thunks */ {"__wine_spec_thunk_text_32", -32, 0, 0}, /* 32 => 16 thunks */ {NULL, 0, 0, 0} }; module->module.SymType = SymExport; /* create a hash table for the symtab */ elf_hash_symtab(module, pool, ht_symtab, fmap, thunks); if (!(dbghelp_options & SYMOPT_PUBLICS_ONLY)) { struct image_section_map stab_sect, stabstr_sect; struct image_section_map debuglink_sect; /* if present, add the .gnu_debuglink file as an alternate to current one */ if (elf_find_section(fmap, ".gnu_debuglink", SHT_NULL, &debuglink_sect)) { const BYTE* dbg_link; dbg_link = (const BYTE*)image_map_section(&debuglink_sect); if (dbg_link != IMAGE_NO_MAP) { lret = elf_debuglink_parse(fmap, module, dbg_link); if (!lret) WARN("Couldn't load linked debug file for %s\n", debugstr_w(module->module.ModuleName)); ret = ret || lret; } image_unmap_section(&debuglink_sect); } if (elf_find_section(fmap, ".stab", SHT_NULL, &stab_sect) && elf_find_section(fmap, ".stabstr", SHT_NULL, &stabstr_sect)) { const char* stab; const char* stabstr; stab = image_map_section(&stab_sect); stabstr = image_map_section(&stabstr_sect); if (stab != IMAGE_NO_MAP && stabstr != IMAGE_NO_MAP) { /* OK, now just parse all of the stabs. */ lret = stabs_parse(module, module->format_info[DFI_ELF]->u.elf_info->elf_addr, stab, image_get_map_size(&stab_sect), stabstr, image_get_map_size(&stabstr_sect), NULL, NULL); if (lret) /* and fill in the missing information for stabs */ elf_finish_stabs_info(module, ht_symtab); else WARN("Couldn't correctly read stabs\n"); ret = ret || lret; } else lret = FALSE; image_unmap_section(&stab_sect); image_unmap_section(&stabstr_sect); } lret = dwarf2_parse(module, module->reloc_delta, thunks, fmap); ret = ret || lret; } if (strstrW(module->module.ModuleName, S_ElfW) || !strcmpW(module->module.ModuleName, S_WineLoaderW)) { /* add the thunks for native libraries */ if (!(dbghelp_options & SYMOPT_PUBLICS_ONLY)) elf_new_wine_thunks(module, ht_symtab, thunks); } /* add all the public symbols from symtab */ if (elf_new_public_symbols(module, ht_symtab) && !ret) ret = TRUE; return ret; } /****************************************************************** * elf_load_debug_info * * Loads ELF debugging information from the module image file. */ BOOL elf_load_debug_info(struct module* module) { BOOL ret = TRUE; struct pool pool; struct hash_table ht_symtab; struct module_format* modfmt; if (module->type != DMT_ELF || !(modfmt = module->format_info[DFI_ELF]) || !modfmt->u.elf_info) { ERR("Bad elf module '%s'\n", debugstr_w(module->module.LoadedImageName)); return FALSE; } pool_init(&pool, 65536); hash_table_init(&pool, &ht_symtab, 256); ret = elf_load_debug_info_from_map(module, &modfmt->u.elf_info->file_map, &pool, &ht_symtab); pool_destroy(&pool); return ret; } /****************************************************************** * elf_fetch_file_info * * Gathers some more information for an ELF module from a given file */ BOOL elf_fetch_file_info(const WCHAR* name, DWORD_PTR* base, DWORD* size, DWORD* checksum) { struct image_file_map fmap; if (!elf_map_file(name, &fmap)) return FALSE; if (base) *base = fmap.u.elf.elf_start; *size = fmap.u.elf.elf_size; *checksum = calc_crc32(fmap.u.elf.fd); elf_unmap_file(&fmap); return TRUE; } /****************************************************************** * elf_load_file * * Loads the information for ELF module stored in 'filename' * the module has been loaded at 'load_offset' address * returns * -1 if the file cannot be found/opened * 0 if the file doesn't contain symbolic info (or this info cannot be * read or parsed) * 1 on success */ static BOOL elf_load_file(struct process* pcs, const WCHAR* filename, unsigned long load_offset, unsigned long dyn_addr, struct elf_info* elf_info) { BOOL ret = FALSE; struct image_file_map fmap; TRACE("Processing elf file '%s' at %08lx\n", debugstr_w(filename), load_offset); if (!elf_map_file(filename, &fmap)) return ret; /* Next, we need to find a few of the internal ELF headers within * this thing. We need the main executable header, and the section * table. */ if (!fmap.u.elf.elf_start && !load_offset) ERR("Relocatable ELF %s, but no load address. Loading at 0x0000000\n", debugstr_w(filename)); if (elf_info->flags & ELF_INFO_DEBUG_HEADER) { struct image_section_map ism; if (elf_find_section(&fmap, ".dynamic", SHT_DYNAMIC, &ism)) { Elf_Dyn dyn; char* ptr = (char*)fmap.u.elf.sect[ism.sidx].shdr.sh_addr; unsigned long len; do { if (!ReadProcessMemory(pcs->handle, ptr, &dyn, sizeof(dyn), &len) || len != sizeof(dyn)) goto leave; if (dyn.d_tag == DT_DEBUG) { elf_info->dbg_hdr_addr = dyn.d_un.d_ptr; if (load_offset == 0 && dyn_addr == 0) /* likely the case */ /* Assume this module (the Wine loader) has been loaded at its preferred address */ dyn_addr = ism.fmap->u.elf.sect[ism.sidx].shdr.sh_addr; break; } ptr += sizeof(dyn); } while (dyn.d_tag != DT_NULL); if (dyn.d_tag == DT_NULL) goto leave; } elf_end_find(&fmap); } if (elf_info->flags & ELF_INFO_MODULE) { struct elf_module_info *elf_module_info; struct module_format* modfmt; struct image_section_map ism; unsigned long modbase = load_offset; if (elf_find_section(&fmap, ".dynamic", SHT_DYNAMIC, &ism)) { unsigned long rva_dyn = elf_get_map_rva(&ism); TRACE("For module %s, got ELF (start=%lx dyn=%lx), link_map (start=%lx dyn=%lx)\n", debugstr_w(filename), (unsigned long)fmap.u.elf.elf_start, rva_dyn, load_offset, dyn_addr); if (dyn_addr && load_offset + rva_dyn != dyn_addr) { WARN("\thave to relocate: %lx\n", dyn_addr - rva_dyn); modbase = dyn_addr - rva_dyn; } } else WARN("For module %s, no .dynamic section\n", debugstr_w(filename)); elf_end_find(&fmap); modfmt = HeapAlloc(GetProcessHeap(), 0, sizeof(struct module_format) + sizeof(struct elf_module_info)); if (!modfmt) goto leave; elf_info->module = module_new(pcs, filename, DMT_ELF, FALSE, modbase, fmap.u.elf.elf_size, 0, calc_crc32(fmap.u.elf.fd)); if (!elf_info->module) { HeapFree(GetProcessHeap(), 0, modfmt); goto leave; } elf_info->module->reloc_delta = elf_info->module->module.BaseOfImage - fmap.u.elf.elf_start; elf_module_info = (void*)(modfmt + 1); elf_info->module->format_info[DFI_ELF] = modfmt; modfmt->module = elf_info->module; modfmt->remove = elf_module_remove; modfmt->loc_compute = NULL; modfmt->u.elf_info = elf_module_info; elf_module_info->elf_addr = load_offset; elf_module_info->file_map = fmap; elf_reset_file_map(&fmap); if (dbghelp_options & SYMOPT_DEFERRED_LOADS) { elf_info->module->module.SymType = SymDeferred; ret = TRUE; } else ret = elf_load_debug_info(elf_info->module); elf_module_info->elf_mark = 1; elf_module_info->elf_loader = 0; } else ret = TRUE; if (elf_info->flags & ELF_INFO_NAME) { WCHAR* ptr; ptr = HeapAlloc(GetProcessHeap(), 0, (lstrlenW(filename) + 1) * sizeof(WCHAR)); if (ptr) { strcpyW(ptr, filename); elf_info->module_name = ptr; } else ret = FALSE; } leave: elf_unmap_file(&fmap); return ret; } /****************************************************************** * elf_load_file_from_path * tries to load an ELF file from a set of paths (separated by ':') */ static BOOL elf_load_file_from_path(HANDLE hProcess, const WCHAR* filename, unsigned long load_offset, unsigned long dyn_addr, const char* path, struct elf_info* elf_info) { BOOL ret = FALSE; WCHAR *s, *t, *fn; WCHAR* pathW = NULL; unsigned len; if (!path) return FALSE; len = MultiByteToWideChar(CP_UNIXCP, 0, path, -1, NULL, 0); pathW = HeapAlloc(GetProcessHeap(), 0, len * sizeof(WCHAR)); if (!pathW) return FALSE; MultiByteToWideChar(CP_UNIXCP, 0, path, -1, pathW, len); for (s = pathW; s && *s; s = (t) ? (t+1) : NULL) { t = strchrW(s, ':'); if (t) *t = '\0'; fn = HeapAlloc(GetProcessHeap(), 0, (lstrlenW(filename) + 1 + lstrlenW(s) + 1) * sizeof(WCHAR)); if (!fn) break; strcpyW(fn, s); strcatW(fn, S_SlashW); strcatW(fn, filename); ret = elf_load_file(hProcess, fn, load_offset, dyn_addr, elf_info); HeapFree(GetProcessHeap(), 0, fn); if (ret) break; s = (t) ? (t+1) : NULL; } HeapFree(GetProcessHeap(), 0, pathW); return ret; } /****************************************************************** * elf_load_file_from_dll_path * * Tries to load an ELF file from the dll path */ static BOOL elf_load_file_from_dll_path(HANDLE hProcess, const WCHAR* filename, unsigned long load_offset, unsigned long dyn_addr, struct elf_info* elf_info) { BOOL ret = FALSE; unsigned int index = 0; const char *path; while (!ret && (path = wine_dll_enum_load_path( index++ ))) { WCHAR *name; unsigned len; len = MultiByteToWideChar(CP_UNIXCP, 0, path, -1, NULL, 0); name = HeapAlloc( GetProcessHeap(), 0, (len + lstrlenW(filename) + 2) * sizeof(WCHAR) ); if (!name) break; MultiByteToWideChar(CP_UNIXCP, 0, path, -1, name, len); strcatW( name, S_SlashW ); strcatW( name, filename ); ret = elf_load_file(hProcess, name, load_offset, dyn_addr, elf_info); HeapFree( GetProcessHeap(), 0, name ); } return ret; } /****************************************************************** * elf_search_and_load_file * * lookup a file in standard ELF locations, and if found, load it */ static BOOL elf_search_and_load_file(struct process* pcs, const WCHAR* filename, unsigned long load_offset, unsigned long dyn_addr, struct elf_info* elf_info) { BOOL ret = FALSE; struct module* module; static WCHAR S_libstdcPPW[] = {'l','i','b','s','t','d','c','+','+','\0'}; if (filename == NULL || *filename == '\0') return FALSE; if ((module = module_is_already_loaded(pcs, filename))) { elf_info->module = module; elf_info->module->format_info[DFI_ELF]->u.elf_info->elf_mark = 1; return module->module.SymType; } if (strstrW(filename, S_libstdcPPW)) return FALSE; /* We know we can't do it */ ret = elf_load_file(pcs, filename, load_offset, dyn_addr, elf_info); /* if relative pathname, try some absolute base dirs */ if (!ret && !strchrW(filename, '/')) { ret = elf_load_file_from_path(pcs, filename, load_offset, dyn_addr, getenv("PATH"), elf_info) || elf_load_file_from_path(pcs, filename, load_offset, dyn_addr, getenv("LD_LIBRARY_PATH"), elf_info); if (!ret) ret = elf_load_file_from_dll_path(pcs, filename, load_offset, dyn_addr, elf_info); } return ret; } typedef BOOL (*enum_elf_modules_cb)(const WCHAR*, unsigned long load_addr, unsigned long dyn_addr, void* user); /****************************************************************** * elf_enum_modules_internal * * Enumerate ELF modules from a running process */ static BOOL elf_enum_modules_internal(const struct process* pcs, const WCHAR* main_name, enum_elf_modules_cb cb, void* user) { struct r_debug dbg_hdr; void* lm_addr; struct link_map lm; char bufstr[256]; WCHAR bufstrW[MAX_PATH]; if (!pcs->dbg_hdr_addr || !ReadProcessMemory(pcs->handle, (void*)pcs->dbg_hdr_addr, &dbg_hdr, sizeof(dbg_hdr), NULL)) return FALSE; /* Now walk the linked list. In all known ELF implementations, * the dynamic loader maintains this linked list for us. In some * cases the first entry doesn't appear with a name, in other cases it * does. */ for (lm_addr = (void*)dbg_hdr.r_map; lm_addr; lm_addr = (void*)lm.l_next) { if (!ReadProcessMemory(pcs->handle, lm_addr, &lm, sizeof(lm), NULL)) return FALSE; if (lm.l_prev != NULL && /* skip first entry, normally debuggee itself */ lm.l_name != NULL && ReadProcessMemory(pcs->handle, lm.l_name, bufstr, sizeof(bufstr), NULL)) { bufstr[sizeof(bufstr) - 1] = '\0'; MultiByteToWideChar(CP_UNIXCP, 0, bufstr, -1, bufstrW, sizeof(bufstrW) / sizeof(WCHAR)); if (main_name && !bufstrW[0]) strcpyW(bufstrW, main_name); if (!cb(bufstrW, (unsigned long)lm.l_addr, (unsigned long)lm.l_ld, user)) break; } } return TRUE; } struct elf_sync { struct process* pcs; struct elf_info elf_info; }; static BOOL elf_enum_sync_cb(const WCHAR* name, unsigned long load_addr, unsigned long dyn_addr, void* user) { struct elf_sync* es = user; elf_search_and_load_file(es->pcs, name, load_addr, dyn_addr, &es->elf_info); return TRUE; } /****************************************************************** * elf_synchronize_module_list * * this functions rescans the debuggee module's list and synchronizes it with * the one from 'pcs', ie: * - if a module is in debuggee and not in pcs, it's loaded into pcs * - if a module is in pcs and not in debuggee, it's unloaded from pcs */ BOOL elf_synchronize_module_list(struct process* pcs) { struct module* module; struct elf_sync es; for (module = pcs->lmodules; module; module = module->next) { if (module->type == DMT_ELF && !module->is_virtual) module->format_info[DFI_ELF]->u.elf_info->elf_mark = 0; } es.pcs = pcs; es.elf_info.flags = ELF_INFO_MODULE; if (!elf_enum_modules_internal(pcs, NULL, elf_enum_sync_cb, &es)) return FALSE; module = pcs->lmodules; while (module) { if (module->type == DMT_ELF && !module->is_virtual) { struct elf_module_info* elf_info = module->format_info[DFI_ELF]->u.elf_info; if (!elf_info->elf_mark && !elf_info->elf_loader) { module_remove(pcs, module); /* restart all over */ module = pcs->lmodules; continue; } } module = module->next; } return TRUE; } /****************************************************************** * elf_search_loader * * Lookup in a running ELF process the loader, and sets its ELF link * address (for accessing the list of loaded .so libs) in pcs. * If flags is ELF_INFO_MODULE, the module for the loader is also * added as a module into pcs. */ static BOOL elf_search_loader(struct process* pcs, struct elf_info* elf_info) { BOOL ret; const char* ptr; /* All binaries are loaded with WINELOADER (if run from tree) or by the * main executable */ if ((ptr = getenv("WINELOADER"))) { WCHAR tmp[MAX_PATH]; MultiByteToWideChar(CP_ACP, 0, ptr, -1, tmp, sizeof(tmp) / sizeof(WCHAR)); ret = elf_search_and_load_file(pcs, tmp, 0, 0, elf_info); } else { ret = elf_search_and_load_file(pcs, S_WineW, 0, 0, elf_info); } return ret; } /****************************************************************** * elf_read_wine_loader_dbg_info * * Try to find a decent wine executable which could have loaded the debuggee */ BOOL elf_read_wine_loader_dbg_info(struct process* pcs) { struct elf_info elf_info; elf_info.flags = ELF_INFO_DEBUG_HEADER | ELF_INFO_MODULE; if (!elf_search_loader(pcs, &elf_info)) return FALSE; elf_info.module->format_info[DFI_ELF]->u.elf_info->elf_loader = 1; module_set_module(elf_info.module, S_WineLoaderW); return (pcs->dbg_hdr_addr = elf_info.dbg_hdr_addr) != 0; } struct elf_enum_user { enum_modules_cb cb; void* user; }; static BOOL elf_enum_modules_translate(const WCHAR* name, unsigned long load_addr, unsigned long dyn_addr, void* user) { struct elf_enum_user* eeu = user; return eeu->cb(name, load_addr, eeu->user); } /****************************************************************** * elf_enum_modules * * Enumerates the ELF loaded modules from a running target (hProc) * This function doesn't require that someone has called SymInitialize * on this very process. */ BOOL elf_enum_modules(HANDLE hProc, enum_modules_cb cb, void* user) { struct process pcs; struct elf_info elf_info; BOOL ret; struct elf_enum_user eeu; memset(&pcs, 0, sizeof(pcs)); pcs.handle = hProc; elf_info.flags = ELF_INFO_DEBUG_HEADER | ELF_INFO_NAME; if (!elf_search_loader(&pcs, &elf_info)) return FALSE; pcs.dbg_hdr_addr = elf_info.dbg_hdr_addr; eeu.cb = cb; eeu.user = user; ret = elf_enum_modules_internal(&pcs, elf_info.module_name, elf_enum_modules_translate, &eeu); HeapFree(GetProcessHeap(), 0, (char*)elf_info.module_name); return ret; } struct elf_load { struct process* pcs; struct elf_info elf_info; const WCHAR* name; BOOL ret; }; /****************************************************************** * elf_load_cb * * Callback for elf_load_module, used to walk the list of loaded * modules. */ static BOOL elf_load_cb(const WCHAR* name, unsigned long load_addr, unsigned long dyn_addr, void* user) { struct elf_load* el = user; const WCHAR* p; /* memcmp is needed for matches when bufstr contains also version information * el->name: libc.so, name: libc.so.6.0 */ p = strrchrW(name, '/'); if (!p++) p = name; if (!memcmp(p, el->name, lstrlenW(el->name) * sizeof(WCHAR))) { el->ret = elf_search_and_load_file(el->pcs, name, load_addr, dyn_addr, &el->elf_info); return FALSE; } return TRUE; } /****************************************************************** * elf_load_module * * loads an ELF module and stores it in process' module list * Also, find module real name and load address from * the real loaded modules list in pcs address space */ struct module* elf_load_module(struct process* pcs, const WCHAR* name, unsigned long addr) { struct elf_load el; TRACE("(%p %s %08lx)\n", pcs, debugstr_w(name), addr); el.elf_info.flags = ELF_INFO_MODULE; el.ret = FALSE; if (pcs->dbg_hdr_addr) /* we're debugging a life target */ { el.pcs = pcs; /* do only the lookup from the filename, not the path (as we lookup module * name in the process' loaded module list) */ el.name = strrchrW(name, '/'); if (!el.name++) el.name = name; el.ret = FALSE; if (!elf_enum_modules_internal(pcs, NULL, elf_load_cb, &el)) return NULL; } else if (addr) { el.name = name; el.ret = elf_search_and_load_file(pcs, el.name, addr, 0, &el.elf_info); } if (!el.ret) return NULL; assert(el.elf_info.module); return el.elf_info.module; } #else /* !__ELF__ */ BOOL elf_find_section(struct image_file_map* fmap, const char* name, unsigned sht, struct image_section_map* ism) { return FALSE; } const char* elf_map_section(struct image_section_map* ism) { return NULL; } void elf_unmap_section(struct image_section_map* ism) {} unsigned elf_get_map_size(const struct image_section_map* ism) { return 0; } DWORD_PTR elf_get_map_rva(const struct image_section_map* ism) { return 0; } BOOL elf_synchronize_module_list(struct process* pcs) { return FALSE; } BOOL elf_fetch_file_info(const WCHAR* name, DWORD_PTR* base, DWORD* size, DWORD* checksum) { return FALSE; } BOOL elf_read_wine_loader_dbg_info(struct process* pcs) { return FALSE; } BOOL elf_enum_modules(HANDLE hProc, enum_modules_cb cb, void* user) { return FALSE; } struct module* elf_load_module(struct process* pcs, const WCHAR* name, unsigned long addr) { return NULL; } BOOL elf_load_debug_info(struct module* module) { return FALSE; } int elf_is_in_thunk_area(unsigned long addr, const struct elf_thunk_area* thunks) { return -1; } #endif /* __ELF__ */