/* $OpenBSD: prebind.c,v 1.26 2014/03/18 22:36:30 miod Exp $ */ /* * Copyright (c) 2006 Dale Rahn * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "resolve.h" #include "link.h" #include "path.h" #include "sod.h" #ifndef __mips64__ #include "machine/reloc.h" #endif #include "prebind.h" #include "ld.h" /* seems to make sense to limit how big of file can be dealt with */ #define MAX_FILE_SIZE (512 * 1024 * 1024) char *shstrtab; /* alpha uses RELOC_JMP_SLOT */ #ifdef __amd64__ #define RELOC_JMP_SLOT R_X86_64_JUMP_SLOT #endif #ifdef __arm__ #define RELOC_JMP_SLOT R_ARM_JUMP_SLOT #endif #ifdef __hppa__ #define RELOC_JMP_SLOT RELOC_IPLT #endif #ifdef __hppa64__ #define RELOC_JMP_SLOT RELOC_JMPSLOT #endif #ifdef __i386__ #define RELOC_JMP_SLOT RELOC_JUMP_SLOT #endif #ifdef __sh__ #define RELOC_JMP_SLOT R_SH_JMP_SLOT #endif #ifdef __mips64__ #define RELOC_JMP_SLOT 0 /* XXX mips64 doesnt have PLT reloc */ #endif #ifdef __m88k__ #define RELOC_JMP_SLOT RELOC_GOTP_ENT #endif #ifdef __vax__ #define RELOC_JMP_SLOT R_VAX_JMP_SLOT #endif /* powerpc uses RELOC_JMP_SLOT */ /* sparc uses RELOC_JMP_SLOT */ /* sparc64 uses RELOC_JMP_SLOT */ #define BUFSZ (256 * 1024) #include "prebind_struct.h" struct proglist *curbin; obj_list_ty library_list = TAILQ_HEAD_INITIALIZER(library_list); prog_list_ty prog_list = TAILQ_HEAD_INITIALIZER(prog_list); struct objarray_list { struct elf_object *obj; struct symcache_noflag *symcache; struct symcache_noflag *pltsymcache; struct proglist *proglist; u_int32_t id0; u_int32_t id1; u_int32_t *idxtolib; void *oprebind_data; int numlibs; TAILQ_HEAD(, objlist) inst_list; } *objarray; struct prebind_info { struct elf_object *object; struct prebind_footer *footer; u_int32_t footer_offset; u_int32_t nfixup; struct nameidx *nameidx; struct symcachetab *symcache; struct symcachetab *pltsymcache; u_int32_t *fixuptab; u_int32_t *fixupcnt; struct fixup **fixup; u_int32_t *maptab; u_int32_t **libmap; u_int32_t *libmapcnt; char *nametab; u_int32_t nametablen; }; int objarray_cnt; int objarray_sz; void copy_oldsymcache(int objidx, char *prebind_data); void elf_load_existing_prebind(struct elf_object *object, int fd); void insert_sym_objcache(struct elf_object *, int, const struct elf_object *, const Elf_Sym *, int); struct elf_object * elf_load_object(void *pexe, const char *name); void elf_free_object(struct elf_object *object); void map_to_virt(Elf_Phdr *, Elf_Ehdr *, Elf_Addr, u_long *); int load_obj_needed(struct elf_object *object); int load_lib(const char *name, struct elf_object *parent); elf_object_t * elf_load_shlib_hint(struct sod *sod, struct sod *req_sod, int use_hints, const char *libpath); char *elf_find_shlib(struct sod *sodp, const char *searchpath, int nohints); elf_object_t * elf_tryload_shlib(const char *libname); int elf_match_file(struct sod *sodp, char *name, int namelen); void elf_init_objarray(void); void elf_add_object(struct elf_object *object, int objtype); void elf_print_objarray(void); void elf_reloc(struct elf_object *object); struct elf_object * elf_lookup_object(const char *name); struct elf_object * elf_lookup_object_devino(dev_t dev, ino_t inode, int objtype); void elf_free_curbin_list(struct elf_object *obj); void elf_resolve_curbin(void); struct proglist *elf_newbin(void); void elf_sum_reloc(void); int elf_prep_lib_prebind(struct elf_object *object); int elf_prep_bin_prebind(struct proglist *pl); void add_fixup_prog(struct elf_object *prog, struct elf_object *obj, int idx, const struct elf_object *ref_obj, const Elf_Sym *ref_sym, int flag); void add_fixup_oldprog(struct elf_object *prog, struct elf_object *obj, int idx, const struct elf_object *ref_obj, const Elf_Sym *ref_sym, int flag); void elf_dump_footer(struct prebind_footer *footer); void elf_fixup_prog_load(int fd, struct prebind_footer *footer, struct elf_object *object); void elf_clear_prog_load(int fd, struct elf_object *object); void elf_find_symbol_rel(const char *s, struct elf_object *object, Elf_Rel *rel, struct symcache_noflag *symcache, struct symcache_noflag *pltsymcache); void elf_find_symbol_rela(const char *s, struct elf_object *object, Elf_RelA *rela, struct symcache_noflag *symcache, struct symcache_noflag *pltsymcache); int elf_find_symbol_obj(elf_object_t *object, const char *name, unsigned long hash, int flags, const Elf_Sym **this, const Elf_Sym **weak_sym, elf_object_t **weak_object); int prebind_writefile(int fd, struct prebind_info *info); int prebind_writenewfile(int infd, char *name, struct stat *st, off_t orig_size, struct prebind_info *info); struct elf_object *load_object; struct elf_object *load_file(const char *filename, int lib); int elf_check_note(void *buf, Elf_Phdr *phdr); void load_file_or_dir(char *name); void load_dir(char *name); void load_exe(char *name); int prebind(char **argv) { int i; elf_init_objarray(); for (i = 0; argv[i]; i++) load_file_or_dir(argv[i]); if (verbose > 4) { elf_print_objarray(); elf_print_prog_list(&prog_list); } elf_sum_reloc(); return (0); } /* * load ELF objects at the specified path it could be * either a either a directory or file, if the object is * a file, attempt to load it as an executable (will ignore shared objects * and any files that are not Elf execuables. * if the object is a directory pass it to a routine to deal with * directory parsing. */ void load_file_or_dir(char *name) { struct stat sb; int ret; ret = lstat(name, &sb); if (ret != 0) return; switch (sb.st_mode & S_IFMT) { case S_IFREG: load_exe(name); break; case S_IFDIR: if (verbose > 0) printf("loading dir %s\n", name); load_dir(name); break; default: ; /* links and other files we skip */ } } /* * for all of the objects in the directory, if it is a regular file * load it as a binary, if it is unknown (nfs mount) stat the file * and load the file for S_IFREG * any other type of directory object: symlink, directory, socket, ... * is ignored. */ void load_dir(char *name) { struct dirent *dp; struct stat sb; DIR *dirp; char *buf; dirp = opendir(name); /* if dir failes to open, skip */ if (dirp == NULL) return; while ((dp = readdir(dirp)) != NULL) { switch (dp->d_type) { case DT_UNKNOWN: /* * NFS will return unknown, since load_file * does stat the file, this just */ asprintf(&buf, "%s/%s", name, dp->d_name); lstat(buf, &sb); if (sb.st_mode == S_IFREG) load_exe(buf); free(buf); break; case DT_REG: asprintf(&buf, "%s/%s", name, dp->d_name); load_exe(buf); free(buf); break; default: /* other files symlinks, dirs, ... we ignore */ ; } } closedir(dirp); } /* * the given pathname is a regular file, however it may or may not * be an ELF file. Attempt to load the given path and calculate prebind * data for it. * if the given file is not a ELF binary this will 'fail' and * should not change any of the prebind state. */ void load_exe(char *name) { struct elf_object *object; struct elf_object *interp; struct objlist *ol; int fail = 0; curbin = elf_newbin(); if (verbose > 0) printf("processing %s\n", name); object = load_file(name, OBJTYPE_EXE); if (object != NULL && load_object != NULL && object->load_object == NULL) { TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { fail = load_obj_needed(ol->object); if (fail != 0) break; /* XXX */ } if (fail == 0) { interp = load_file(curbin->interp, OBJTYPE_DLO); object->load_object = interp; if (interp == NULL) fail = 1; } /* slight abuse of this field */ if (fail == 0) { objarray[object->dyn.null].proglist = curbin; elf_resolve_curbin(); TAILQ_INSERT_TAIL(&prog_list, curbin, list); } else { printf("failed to load %s\n", name); elf_free_curbin_list(object); free(curbin); } if (load_object != NULL) { load_object = NULL; } } else { free(curbin); } } /* * given a path to a file, attempt to open it and load any data necessary * for prebind. this function is used for executables, libraries and ld.so * file, it will do a lookup on the dev/inode to use a cached version * of the file if it was already loaded, in case a library is referenced * by more than one program or there are hardlinks between executable names. * if the file is not an elf file of the appropriate type, it will return * failure. */ struct elf_object * load_file(const char *filename, int objtype) { struct elf_object *obj = NULL; int fd = -1, i, note_found; struct stat ifstat; void *buf = NULL; Elf_Ehdr *ehdr; Elf_Shdr *shdr; Elf_Phdr *phdr; char *pexe; fd = open(filename, O_RDONLY); if (fd == -1) { perror(filename); goto done; } if (fstat(fd, &ifstat) == -1) { perror(filename); goto done; } if ((ifstat.st_mode & S_IFMT) != S_IFREG) goto done; if (ifstat.st_size < sizeof (Elf_Ehdr)) goto done; obj = elf_lookup_object_devino(ifstat.st_dev, ifstat.st_ino, objtype); if (obj != NULL) goto done; buf = mmap(NULL, ifstat.st_size, PROT_READ, MAP_FILE | MAP_SHARED, fd, 0); if (buf == MAP_FAILED) { printf("%s: cannot mmap\n", filename); goto done; } ehdr = (Elf_Ehdr *)buf; if (IS_ELF(*ehdr) == 0) goto done; if (ehdr->e_machine != ELF_TARG_MACH) { if (verbose > 0) printf("%s: wrong arch\n", filename); goto done; } if (objtype == OBJTYPE_EXE) { if (ehdr->e_type != ET_EXEC) goto done; note_found = 0; phdr = (Elf_Phdr *)((char *)buf + ehdr->e_phoff); for (i = 0; i < ehdr->e_phnum; i++) { if (phdr[i].p_type == PT_NOTE) { note_found = elf_check_note(buf,&phdr[i]); break; } } if (note_found == 0) goto done; /* no OpenBSD note found */ } if ((objtype == OBJTYPE_LIB || objtype == OBJTYPE_DLO) && (ehdr->e_type != ET_DYN)) goto done; pexe = buf; if (ehdr->e_shstrndx == 0) goto done; shdr = (Elf_Shdr *)(pexe + ehdr->e_shoff + (ehdr->e_shstrndx * ehdr->e_shentsize)); shstrtab = (char *)(pexe + shdr->sh_offset); obj = elf_load_object(pexe, filename); munmap(buf, ifstat.st_size); buf = NULL; if (obj != NULL) { obj->obj_type = objtype; obj->dev = ifstat.st_dev; obj->inode = ifstat.st_ino; if (load_object == NULL) load_object = obj; elf_add_object(obj, objtype); #ifdef DEBUG1 dump_info(obj); #endif } if ((objtype == OBJTYPE_LIB || objtype == OBJTYPE_DLO) && merge == 1) { /* * for libraries and dynamic linker, check if old prebind * info exists and load it if we are in merge mode */ elf_load_existing_prebind(obj, fd); } done: if (buf != NULL) munmap(buf, ifstat.st_size); if (fd != -1) close(fd); return obj; } /* * check if the given executable header on a ELF executable * has the proper OpenBSD note on the file if it is not present * binaries will be skipped. */ int elf_check_note(void *buf, Elf_Phdr *phdr) { u_long address; u_int *pint; char *osname; address = phdr->p_offset; pint = (u_int *)((char *)buf + address); osname = (char *)buf + address + sizeof(*pint) * 3; if (pint[0] == 8 /* OpenBSD\0 */ && pint[1] == 4 /* ??? */ && pint[2] == 1 /* type_osversion */ && strcmp("OpenBSD", osname) == 0) return 1; return 0; } struct elf_object * elf_load_object(void *pexe, const char *name) { struct elf_object *object; Elf_Dyn *dynp = NULL, *odynp; Elf_Ehdr *ehdr; Elf_Phdr *phdr; Elf_Addr lbase; Elf_Word *needed_list; int needed_cnt = 0, i; object = calloc(1, sizeof (struct elf_object)); if (object == NULL) { printf("unable to allocate object for %s\n", name); exit(10); } ehdr = pexe; lbase = (Elf_Addr)pexe; object->load_base = lbase; object->load_name = strdup(name); phdr = (Elf_Phdr *)((char *)pexe + ehdr->e_phoff); for (i = 0; i < ehdr->e_phnum; i++) { switch (phdr[i].p_type) { case PT_DYNAMIC: dynp = (Elf_Dyn *)(phdr[i].p_offset); break; case PT_INTERP: /* XXX can only occur in programs */ curbin->interp = strdup((char *)((char *)pexe + phdr[i].p_offset)); break; default: break; } } if (dynp == 0) { free(object); return NULL; /* not a dynamic binary */ } dynp = (Elf_Dyn *)((unsigned long)dynp + lbase); odynp = dynp; while (dynp->d_tag != DT_NULL) { if (dynp->d_tag < DT_NUM) object->Dyn.info[dynp->d_tag] = dynp->d_un.d_val; else if (dynp->d_tag >= DT_LOPROC && dynp->d_tag < DT_LOPROC + DT_PROCNUM) object->Dyn.info[dynp->d_tag + DT_NUM - DT_LOPROC] = dynp->d_un.d_val; if (dynp->d_tag == DT_TEXTREL) object->dyn.textrel = 1; if (dynp->d_tag == DT_SYMBOLIC) object->dyn.symbolic = 1; if (dynp->d_tag == DT_BIND_NOW) object->obj_flags |= DF_1_NOW; if (dynp->d_tag == DT_FLAGS_1) object->obj_flags |= dynp->d_un.d_val; if (dynp->d_tag == DT_NEEDED) needed_cnt++; dynp++; } needed_list = calloc((needed_cnt + 1), sizeof(Elf_Word)); if (needed_list == NULL) { printf("unable to allocate needed_list for %s\n", name); exit(10); } needed_list[needed_cnt] = 0; for (dynp = odynp, i = 0; dynp->d_tag != DT_NULL; dynp++) { if (dynp->d_tag == DT_NEEDED) { needed_list[i] = dynp->d_un.d_val; i++; } } if (object->Dyn.info[DT_HASH]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_HASH]); if (object->Dyn.info[DT_STRTAB]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_STRTAB]); if (object->Dyn.info[DT_SYMTAB]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_SYMTAB]); if (object->Dyn.info[DT_RELA]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_RELA]); if (object->Dyn.info[DT_RPATH]) object->Dyn.info[DT_RPATH] += object->Dyn.info[DT_STRTAB]; if (object->Dyn.info[DT_REL]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_REL]); if (object->Dyn.info[DT_JMPREL]) map_to_virt(phdr, ehdr, lbase, &object->Dyn.info[DT_JMPREL]); { Elf_Sym *sym; char *str; Elf_Rel *rel; Elf_RelA *rela; Elf_Addr *hash; Elf_Word *hashtab; void *plt; size_t hashsz; if (object->Dyn.info[DT_HASH] != 0) { hash = object->dyn.hash; hashtab = (void *)hash; object->nbuckets = hashtab[0]; object->nchains = hashtab[1]; hashsz = (2 + object->nbuckets + object->nchains) * sizeof (Elf_Word); hash = malloc(hashsz); if (hash == NULL) { printf("unable to allocate hash for %s\n", name); exit(10); } bcopy(object->dyn.hash, hash, hashsz); object->dyn.hash = hash; object->buckets = ((Elf_Word *)hash + 2); object->chains = object->buckets + object->nbuckets; } str = malloc(object->dyn.strsz); if (str == NULL) { printf("unable to allocate strtab for %s\n", name); exit(10); } bcopy(object->dyn.strtab, str, object->dyn.strsz); object->dyn.strtab = str; sym = calloc(object->nchains, sizeof(Elf_Sym)); if (sym == NULL) { printf("unable to allocate symtab for %s\n", name); exit(10); } bcopy(object->dyn.symtab, sym, object->nchains * sizeof(Elf_Sym)); object->dyn.symtab = sym; if (object->dyn.relsz != 0) { rel = malloc(object->dyn.relsz); if (rel == NULL) { printf("unable to allocate rel reloc for %s\n", name); exit(10); } bcopy(object->dyn.rel, rel, object->dyn.relsz); object->dyn.rel = rel; } else { object->dyn.rel = NULL; } if (object->dyn.relasz != 0) { rela = malloc(object->dyn.relasz); if (rela == NULL) { printf("unable to allocate rela reloc for %s\n", name); exit(10); } bcopy(object->dyn.rela, rela, object->dyn.relasz); object->dyn.rela = rela; } else { object->dyn.rela = NULL; } if (object->dyn.pltrelsz != 0) { plt = malloc(object->dyn.pltrelsz); if (plt == NULL) { printf("unable to allocate plt reloc for %s\n", name); exit(10); } bcopy((void*)object->dyn.jmprel, plt, object->dyn.pltrelsz); object->dyn.jmprel = (long)plt; } else { object->dyn.jmprel = 0; } if (object->dyn.rpath != NULL){ object->rpath = _dl_split_path(object->dyn.rpath); if (object->rpath == NULL) { printf("unable to allocate rpath for %s\n", name); exit(10); } } object->dyn.needed = (Elf_Addr)needed_list; } #ifdef DEBUG1 dump_info(object); #endif return object; } /* * Free any extra pieces associated with 'object' */ void elf_free_object(struct elf_object *object) { free(object->load_name); if (object->dyn.hash != NULL) free(object->dyn.hash); free((void *)object->dyn.strtab); free((void *)object->dyn.symtab); if (object->dyn.rel != NULL) free(object->dyn.rel); if (object->dyn.rela != NULL) free(object->dyn.rela); if (object->dyn.rpath != NULL) free((void *)object->dyn.rpath); free(object); } /* * translate an object address into a file offset for the * file assuming that the file is mapped at base. */ void map_to_virt(Elf_Phdr *phdr, Elf_Ehdr *ehdr, Elf_Addr base, u_long *vaddr) { int i; for (i = 0; i < ehdr->e_phnum; i++) { switch (phdr[i].p_type) { case PT_LOAD: if (phdr[i].p_vaddr > *vaddr) continue; if (phdr[i].p_vaddr + phdr[i].p_memsz < *vaddr) continue; #ifdef DEBUG1 printf("input address %lx translated to ", *vaddr); #endif *vaddr += phdr[i].p_offset - phdr[i].p_vaddr + base; #ifdef DEBUG1 printf("%lx, base %lx %lx %llx\n", *vaddr, base, phdr[i].p_vaddr, phdr[i].p_offset ); #endif break; default: break; } } } /* * given a dynamic elf object (executable or binary) * load any DT_NEEDED entries which were found when * the object was initially loaded. */ int load_obj_needed(struct elf_object *object) { int i; Elf_Word *needed_list; int err; needed_list = (Elf_Word *)object->dyn.needed; for (i = 0; needed_list[i] != 0; i++) { if (verbose > 1) printf("lib: %s\n", needed_list[i] + object->dyn.strtab); err = load_lib(needed_list[i] + object->dyn.strtab, object); if (err) { printf("failed to load lib %s\n", needed_list[i] + object->dyn.strtab); return 1; } } return 0; } /* * allocate a proglist entry for a new binary * so that it is available for libraries to reference */ struct proglist * elf_newbin(void) { struct proglist *proglist; proglist = malloc(sizeof (struct proglist)); if (proglist == NULL) { printf("unable to allocate proglist\n"); exit(10); } proglist->fixup = NULL; TAILQ_INIT(&(proglist->curbin_list)); return proglist; } /* * Copy the contents of a libraries symbol cache instance into * the 'global' symbol cache for that library * this will currently resolve conflicts between mismatched * libraries by flagging any mismatches as invalid * which will cause all programs to generate a fixup * It probably would be interesting to modify this to keep the most * common entry as a library cache, and only have a fixup in programs * where the symbol is overridden. * This is run once each for the (got)symcache and pltsymcache */ struct elf_object badobj_store; struct elf_object *badobj = &badobj_store; /* * copy the symbols found in a library symcache to the 'master/common' * symbol table note that this will skip copying the following references * 1. non-existing entries * 2. symobj == prog &&& obj != prog * 3. symobj == prog's interpter (references to dl_open) */ void elf_copy_syms(struct symcache_noflag *tcache, struct symcache_noflag *scache, struct elf_object *obj, struct elf_object *prog, int nsyms) { int i; int lib_prog_ref; for (i = 0; i < nsyms; i++) { if (scache[i].obj == NULL) continue; if (tcache[i].obj != NULL) { lib_prog_ref = (obj != prog && scache[i].obj == prog); if (scache[i].obj != tcache[i].obj || lib_prog_ref) { if (verbose > 2) { printf("sym mismatch %d: " "obj %d: sym %ld %s " "nobj %s\n", i, (int)scache[i].obj->dyn.null, scache[i].sym - scache[i].obj->dyn.symtab, scache[i].sym->st_name + scache[i].obj->dyn.strtab, scache[i].obj->load_name); } /* * if one of the symbol entries * happens to be a self reference * go ahead and keep that reference * prevents some instances of fixups * for every binary, eg one program * overriding malloc() will not make * ever binary have a fixup for libc * references to malloc() */ if (scache[i].obj == obj) { tcache[i].obj = scache[i].obj; tcache[i].sym = scache[i].sym; } else if (tcache[i].obj == obj) { /* no change necessary */ } else { tcache[i].obj = badobj; tcache[i].sym = NULL; } } } else { if (scache[i].obj != prog) { tcache[i].obj = scache[i].obj; tcache[i].sym = scache[i].sym; } } } } void insert_sym_objcache(struct elf_object *obj, int idx, const struct elf_object *ref_obj, const Elf_Sym *ref_sym, int flags) { struct symcache_noflag *tcache; struct elf_object *prog; prog = TAILQ_FIRST(&(curbin->curbin_list))->object; if (flags) tcache = objarray[obj->dyn.null].pltsymcache; else tcache = objarray[obj->dyn.null].symcache; if (tcache[idx].obj != NULL) { if (ref_obj != tcache[idx].obj || (obj != prog && ref_obj == prog)) { if (verbose > 2) { printf("sym mismatch %d: " "obj %d: sym %ld %s " "nobj %s\n", idx, (int)ref_obj->dyn.null, ref_sym - ref_obj->dyn.symtab, ref_sym->st_name + ref_obj->dyn.strtab, ref_obj->load_name); } /* * if one of the symbol entries * happens to be a self reference * go ahead and keep that reference * prevents some instances of fixups * for every binary, eg one program * overriding malloc() will not make * ever binary have a fixup for libc * references to malloc() */ if (ref_obj == obj) { tcache[idx].obj = ref_obj; tcache[idx].sym = ref_sym; add_fixup_oldprog(prog, obj, idx, ref_obj, ref_sym, flags); } else if (tcache[idx].obj == obj) { /* no change necessary */ add_fixup_prog(prog, obj, idx, ref_obj, ref_sym, flags); } else { add_fixup_oldprog(prog, obj, idx, tcache[idx].obj, tcache[idx].sym, flags); tcache[idx].obj = badobj; tcache[idx].sym = NULL; add_fixup_prog(prog, obj, idx, ref_obj, ref_sym, flags); } } } else { if (ref_obj != prog) { tcache[idx].obj = ref_obj; tcache[idx].sym = ref_sym; } else { add_fixup_prog(prog, obj, idx, ref_obj, ref_sym, flags); } } } void add_fixup_prog(struct elf_object *prog, struct elf_object *obj, int idx, const struct elf_object *ref_obj, const Elf_Sym *ref_sym, int flag) { struct proglist *pl; int i, libidx, cnt; pl = objarray[prog->dyn.null].proglist; libidx = -1; for (i = 0; i < pl->nobj; i++) { if (pl->libmap[0][i] == obj->dyn.null) { libidx = (i * 2) + ((flag & SYM_PLT) ? 1 : 0); break; } } if (libidx == -1) { printf("unable to find object\n"); return; } /* have to check for duplicate patches */ for (i = 0; i < pl->fixupcnt[libidx]; i++) { if (pl->fixup[libidx][i].sym == idx) return; } if (verbose > 1) printf("fixup for obj %s on prog %s sym %s: %d\n", obj->load_name, prog->load_name, ref_obj->dyn.strtab + ref_sym->st_name, pl->fixupcnt[libidx]); if (pl->fixupcntalloc[libidx] < pl->fixupcnt[libidx] + 1) { pl->fixupcntalloc[libidx] += 16; pl->fixup[libidx] = realloc(pl->fixup[libidx], sizeof (struct fixup) * pl->fixupcntalloc[libidx]); if (pl->fixup[libidx] == NULL) { printf("realloc fixup, out of memory\n"); exit(20); } } cnt = pl->fixupcnt[libidx]; pl->fixup[libidx][cnt].sym = idx; pl->fixup[libidx][cnt].obj_idx = ref_obj->dyn.null; pl->fixup[libidx][cnt].sym_idx = ref_sym - ref_obj->dyn.symtab; pl->fixupcnt[libidx]++; } void add_fixup_oldprog(struct elf_object *prog, struct elf_object *obj, int idx, const struct elf_object *ref_obj, const Elf_Sym *ref_sym, int flag) { struct objlist *ol; TAILQ_FOREACH(ol, &(objarray[obj->dyn.null].inst_list), inst_list) { if (ol->load_prog == prog) { continue; } /* process here */ add_fixup_prog(ol->load_prog, obj, idx, ref_obj, ref_sym, flag); } } struct elf_object * elf_lookup_object(const char *name) { struct objlist *ol; TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { if (strcmp (name, ol->object->load_name) == 0) { return ol->object; } } TAILQ_FOREACH(ol, &library_list, list) { if (strcmp (name, ol->object->load_name) == 0) { elf_add_object_curbin_list(ol->object); return ol->object; } } return NULL; } struct elf_object * elf_lookup_object_devino(dev_t dev, ino_t inode, int objtype) { struct objlist *ol; TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { if (ol->object->dev == dev && ol->object->inode == inode) { if (ol->object->obj_type != objtype) return NULL; return ol->object; } } TAILQ_FOREACH(ol, &library_list, list) { if (ol->object->dev == dev && ol->object->inode == inode) { if (ol->object->obj_type != objtype) return NULL; if (objtype != OBJTYPE_EXE) elf_add_object_curbin_list(ol->object); return ol->object; } } return NULL; } void elf_find_symbol_rel(const char *name, struct elf_object *object, Elf_Rel *rel, struct symcache_noflag *symcache, struct symcache_noflag *pltsymcache) { struct objlist *ol; unsigned long h = 0; const char *p = name; const Elf_Sym *sym, *ref_sym = NULL; const Elf_Sym *weak_sym = NULL; struct elf_object *weak_obj = NULL; int flags = 0; int found = 0; int type, idx; struct elf_object *ref_object = NULL; sym = object->dyn.symtab + ELF_R_SYM(rel->r_info); while (*p) { unsigned long g; h = (h << 4) + *p++; if ((g = h & 0xf0000000)) h ^= g >> 24; h &= ~g; } type = ELF_R_TYPE(rel->r_info); flags = SYM_SEARCH_ALL|SYM_WARNNOTFOUND; if (type == RELOC_JMP_SLOT) flags |= SYM_PLT; TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { found = elf_find_symbol_obj(ol->object, name, h, flags, &sym, &weak_sym, &weak_obj); if (found) { ref_object = ol->object; break; } } if (found) { ref_object = ol->object; ref_sym = sym; } else if (weak_obj != NULL) { found = 1; ref_object = weak_obj; ref_sym = weak_sym; } if (found == 1) { idx = ELF_R_SYM(rel->r_info); if (flags & SYM_PLT) { pltsymcache[idx].obj = ref_object; pltsymcache[idx].sym = ref_sym; } else { symcache[idx].obj = ref_object; symcache[idx].sym = ref_sym; } } else { /* It is not an error to have an undefined weak symbol */ const Elf_Sym *sym; sym = object->dyn.symtab + ELF_R_SYM(rel->r_info); if (ELF_ST_BIND(sym->st_info) != STB_WEAK) { printf("symbol not found %s\n", name); } } } void elf_find_symbol_rela(const char *name, struct elf_object *object, Elf_RelA *rela, struct symcache_noflag *symcache, struct symcache_noflag *pltsymcache) { struct objlist *ol; unsigned long h = 0; const char *p = name; const Elf_Sym *sym, *ref_sym = NULL; const Elf_Sym *weak_sym = NULL; struct elf_object *weak_obj = NULL; int flags = 0; int found = 0; int type, idx; struct elf_object *ref_object = NULL; sym = object->dyn.symtab + ELF_R_SYM(rela->r_info); while (*p) { unsigned long g; h = (h << 4) + *p++; if ((g = h & 0xf0000000)) h ^= g >> 24; h &= ~g; } type = ELF_R_TYPE(rela->r_info); flags = SYM_SEARCH_ALL|SYM_WARNNOTFOUND; if (type == RELOC_JMP_SLOT) flags |= SYM_PLT; TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { // printf("searching sym [%s] typ %d in obj %s\n", name, type, ol->object->load_name); found = elf_find_symbol_obj(ol->object, name, h, flags, &sym, &weak_sym, &weak_obj); if (found) { ref_object = ol->object; break; } } if (found) { ref_object = ol->object; ref_sym = sym; } else if (weak_obj != NULL) { found = 1; ref_object = weak_obj; ref_sym = weak_sym; } if (found == 1) { idx = ELF_R_SYM(rela->r_info); if (flags & SYM_PLT) { pltsymcache[idx].obj = ref_object; pltsymcache[idx].sym = ref_sym; } else { symcache[idx].obj = ref_object; symcache[idx].sym = ref_sym; } } else { /* It is not an error to have an undefined weak symbol */ const Elf_Sym *sym; sym = object->dyn.symtab + ELF_R_SYM(rela->r_info); if (ELF_ST_BIND(sym->st_info) != STB_WEAK) { printf("symbol not found %s\n", name); } } } int elf_find_symbol_obj(elf_object_t *object, const char *name, unsigned long hash, int flags, const Elf_Sym **this, const Elf_Sym **weak_sym, elf_object_t **weak_object) { const Elf_Sym *symt = object->dyn.symtab; const char *strt = object->dyn.strtab; long si; const char *symn; for (si = object->buckets[hash % object->nbuckets]; si != STN_UNDEF; si = object->chains[si]) { const Elf_Sym *sym = symt + si; if (sym->st_value == 0) continue; if (ELF_ST_TYPE(sym->st_info) != STT_NOTYPE && ELF_ST_TYPE(sym->st_info) != STT_OBJECT && ELF_ST_TYPE(sym->st_info) != STT_FUNC) continue; symn = strt + sym->st_name; if (sym != *this && strcmp(symn, name)) continue; /* allow this symbol if we are referring to a function * which has a value, even if section is UNDEF. * this allows &func to refer to PLT as per the * ELF spec. st_value is checked above. * if flags has SYM_PLT set, we must have actual * symbol, so this symbol is skipped. */ if (sym->st_shndx == SHN_UNDEF) { if ((flags & SYM_PLT) || sym->st_value == 0 || ELF_ST_TYPE(sym->st_info) != STT_FUNC) continue; } if (ELF_ST_BIND(sym->st_info) == STB_GLOBAL) { *this = sym; return 1; } else if (ELF_ST_BIND(sym->st_info) == STB_WEAK) { if (!*weak_sym) { *weak_sym = sym; *weak_object = object; } } } return 0; } void elf_reloc(struct elf_object *object) { const Elf_Sym *sym; Elf_Rel *rel; Elf_RelA *rela; int numrel; int numrela; int i; struct symcache_noflag *symcache; struct symcache_noflag *pltsymcache; numrel = object->dyn.relsz / sizeof(Elf_Rel); #ifdef DEBUG1 printf("rel relocations: %d\n", numrel); #endif #if 1 symcache = calloc(sizeof(struct symcache_noflag), object->nchains); pltsymcache = calloc(sizeof(struct symcache_noflag), object->nchains); if (symcache == NULL || pltsymcache == NULL) { printf("unable to allocate memory for cache %s\n", object->load_name); exit(20); } #endif rel = object->dyn.rel; for (i = 0; i < numrel; i++) { const char *s; sym = object->dyn.symtab + ELF_R_SYM(rel[i].r_info); /* hppa has entries without names, skip them */ if (sym->st_name == 0) continue; s = (ELF_R_SYM(rel[i].r_info) == 0) ? "" : object->dyn.strtab + sym->st_name; #ifdef DEBUG1 printf("%d: %x sym %x %s type %d\n", i, rel[i].r_offset, ELF_R_SYM(rel[i].r_info), s, ELF_R_TYPE(rel[i].r_info)); #endif if (ELF_R_SYM(rel[i].r_info) != 0) { elf_find_symbol_rel(s, object, &rel[i], symcache, pltsymcache); } } if (numrel) { numrel = object->dyn.pltrelsz / sizeof(Elf_Rel); rel = (Elf_Rel *)(object->Dyn.info[DT_JMPREL]); #ifdef DEBUG1 printf("rel plt relocations: %d\n", numrel); #endif for (i = 0; i < numrel; i++) { const char *s; sym = object->dyn.symtab + ELF_R_SYM(rel[i].r_info); /* hppa has entries without names, skip them */ if (sym->st_name == 0) continue; s = (ELF_R_SYM(rel[i].r_info) == 0) ? "" : object->dyn.strtab + sym->st_name; #ifdef DEBUG1 printf("%d: %x sym %d %s type %d\n", i, rel[i].r_offset, ELF_R_SYM(rel[i].r_info), s, ELF_R_TYPE(rel[i].r_info)); #endif if (ELF_R_SYM(rel[i].r_info) != 0) { elf_find_symbol_rel(s, object, &rel[i], symcache, pltsymcache); } } } numrela = object->dyn.relasz / sizeof(Elf_RelA); #ifdef DEBUG1 printf("rela relocations: %d\n", numrela); #endif rela = object->dyn.rela; for (i = 0; i < numrela; i++) { const char *s; sym = object->dyn.symtab + ELF_R_SYM(rela[i].r_info); /* hppa has entries without names, skip them */ if (sym->st_name == 0) continue; s = (ELF_R_SYM(rela[i].r_info) == 0) ? "" : object->dyn.strtab + sym->st_name; #ifdef DEBUG1 printf("%d: %x sym %x %s type %d\n", i, rela[i].r_offset, ELF_R_SYM(rela[i].r_info), s, ELF_R_TYPE(rela[i].r_info)); #endif if (ELF_R_SYM(rela[i].r_info) != 0) { elf_find_symbol_rela(s, object, &rela[i], symcache, pltsymcache); } } if (numrela) { numrela = object->dyn.pltrelsz / sizeof(Elf_RelA); #ifdef DEBUG1 printf("rela plt relocations: %d\n", numrela); #endif rela = (Elf_RelA *)(object->Dyn.info[DT_JMPREL]); for (i = 0; i < numrela; i++) { const char *s; sym = object->dyn.symtab + ELF_R_SYM(rela[i].r_info); /* hppa has entries without names, skip them */ if (sym->st_name == 0) continue; s = (ELF_R_SYM(rela[i].r_info) == 0) ? "" : object->dyn.strtab + sym->st_name; #ifdef DEBUG1 printf("%d: %x sym %x %s type %d\n", i, rela[i].r_offset, ELF_R_SYM(rela[i].r_info), s, ELF_R_TYPE(rela[i].r_info)); #endif if (ELF_R_SYM(rela[i].r_info) != 0) { elf_find_symbol_rela(s, object, &rela[i], symcache, pltsymcache); } } } for (i = 0; i < object->nchains; i++) if (symcache[i].sym != NULL) insert_sym_objcache(object, i, symcache[i].obj, symcache[i].sym, 0); for (i = 0; i < object->nchains; i++) if (pltsymcache[i].sym != NULL) insert_sym_objcache(object, i, pltsymcache[i].obj, pltsymcache[i].sym, SYM_PLT); free(symcache); free(pltsymcache); } void elf_resolve_curbin(void) { struct objlist *ol; int numobj = 0; #ifdef DEBUG1 elf_print_curbin_list(curbin); #endif TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { numobj++; } curbin->nobj = numobj; curbin->libmap = xcalloc(numobj, sizeof (u_int32_t *)); curbin->libmap[0] = xcalloc(numobj, sizeof (u_int32_t *)); curbin->fixup = xcalloc(2 * numobj, sizeof (struct fixup *)); curbin->fixupcnt = xcalloc(2 * numobj, sizeof (int)); curbin->fixupcntalloc = xcalloc(2 * numobj, sizeof (int)); numobj = 0; TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { curbin->libmap[0][numobj] = ol->object->dyn.null; numobj++; } TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { elf_reloc(ol->object); } } void elf_add_object_curbin_list(struct elf_object *object) { struct objlist *ol; ol = xmalloc(sizeof (struct objlist)); ol->object = object; TAILQ_INSERT_TAIL(&(curbin->curbin_list), ol, list); if (load_object == NULL) load_object = object; ol->load_prog = load_object; TAILQ_INSERT_TAIL(&(objarray[object->dyn.null].inst_list), ol, inst_list); } void elf_init_objarray(void) { objarray_sz = 512; objarray = xcalloc(sizeof (objarray[0]), objarray_sz); } void elf_sum_reloc(void) { int numobjs; int err = 0; struct objlist *ol; struct proglist *pl; TAILQ_FOREACH(ol, &library_list, list) { err += elf_prep_lib_prebind(ol->object); } TAILQ_FOREACH(pl, &prog_list, list) { numobjs = 0; TAILQ_FOREACH(ol, &(pl->curbin_list), list) { numobjs++; } pl->nobj = numobjs; } TAILQ_FOREACH(pl, &prog_list, list) err += elf_prep_bin_prebind(pl); if (err != 0) printf("failures %d\n", err); } int elf_prep_lib_prebind(struct elf_object *object) { int numlibs = 0; int ret = 0; int i; int ref_obj; int *libmap; int *idxtolib; struct nameidx *nameidx; char *nametab; int nametablen; struct symcache_noflag *symcache; struct symcache_noflag *pltsymcache; struct symcachetab *symcachetab; int symcache_cnt = 0; struct symcachetab *pltsymcachetab; int pltsymcache_cnt = 0; symcache = objarray[object->dyn.null].symcache; pltsymcache = objarray[object->dyn.null].pltsymcache; libmap = xcalloc(objarray_cnt, sizeof (int)); idxtolib = xcalloc(objarray_cnt, sizeof (int)); objarray[object->dyn.null].idxtolib = idxtolib; for (i = 0; i < objarray_cnt; i++) libmap[i] = -1; nametablen = 0; for (i = 0; i < object->nchains; i++) { if (symcache[i].sym == NULL) continue; ref_obj = symcache[i].obj->dyn.null; symcache_cnt++; if (libmap[ref_obj] != -1) continue; libmap[ref_obj] = numlibs; idxtolib[numlibs] = ref_obj; nametablen += strlen(symcache[i].obj->load_name) + 1; numlibs++; } symcachetab = xcalloc(symcache_cnt , sizeof(struct symcachetab)); symcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (symcache[i].sym == NULL) continue; symcachetab[symcache_cnt].idx = i; symcachetab[symcache_cnt].obj_idx = libmap[symcache[i].obj->dyn.null]; symcachetab[symcache_cnt].sym_idx = symcache[i].sym - symcache[i].obj->dyn.symtab; symcache_cnt++; } for (i = 0; i < object->nchains; i++) { if (pltsymcache[i].sym == NULL) continue; ref_obj = pltsymcache[i].obj->dyn.null; pltsymcache_cnt++; if (libmap[ref_obj] != -1) continue; libmap[ref_obj] = numlibs; idxtolib[numlibs] = ref_obj; nametablen += strlen(pltsymcache[i].obj->load_name) + 1; numlibs++; } pltsymcachetab = xcalloc(pltsymcache_cnt , sizeof(struct symcachetab)); pltsymcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (pltsymcache[i].sym == NULL) continue; pltsymcachetab[pltsymcache_cnt].idx = i; pltsymcachetab[pltsymcache_cnt].obj_idx = libmap[pltsymcache[i].obj->dyn.null]; pltsymcachetab[pltsymcache_cnt].sym_idx = pltsymcache[i].sym - pltsymcache[i].obj->dyn.symtab; pltsymcache_cnt++; } objarray[object->dyn.null].numlibs = numlibs; nameidx = xcalloc(numlibs, sizeof (struct nameidx)); nametab = xmalloc(nametablen); nametablen = 0; for (i = 0; i < numlibs; i++) { nameidx[i].name = nametablen; nameidx[i].id0 = objarray[idxtolib[i]].id0; nameidx[i].id1 = objarray[idxtolib[i]].id1; nametablen += strlen(objarray[idxtolib[i]].obj->load_name) + 1; strlcpy(&nametab[nameidx[i].name], objarray[idxtolib[i]].obj->load_name, nametablen - nameidx[i].name); } /* skip writing lib if using old prebind data */ if (objarray[object->dyn.null].oprebind_data == NULL) ret = elf_write_lib(object, nameidx, nametab, nametablen, numlibs, 0, NULL, NULL, NULL, NULL, symcachetab, symcache_cnt, pltsymcachetab, pltsymcache_cnt); free(nameidx); free(nametab); free(libmap); free(pltsymcachetab); free(symcachetab); return ret; } int elf_prep_bin_prebind(struct proglist *pl) { int ret; int numlibs = 0; int i, j; int ref_obj; int *libmap; int *idxtolib; struct nameidx *nameidx; char *nametab; int nametablen; struct symcache_noflag *symcache; struct symcache_noflag *pltsymcache; struct symcachetab *symcachetab; int symcache_cnt; struct symcachetab *pltsymcachetab; int pltsymcache_cnt; struct elf_object *object; struct objlist *ol; object = TAILQ_FIRST(&(pl->curbin_list))->object; symcache = objarray[object->dyn.null].symcache; pltsymcache = objarray[object->dyn.null].pltsymcache; libmap = xcalloc(objarray_cnt, sizeof (int)); idxtolib = xcalloc(pl->nobj, sizeof (int)); for (i = 0; i < objarray_cnt; i++) libmap[i] = -1; for (i = 0; i < pl->nobj; i++) idxtolib[i] = -1; nametablen = 0; TAILQ_FOREACH(ol, &(pl->curbin_list), list) { ref_obj = ol->object->dyn.null; nametablen += strlen(ol->object->load_name) + 1; libmap[ref_obj] = numlibs; idxtolib[numlibs] = ref_obj; numlibs++; } /* do got */ symcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (symcache[i].sym != NULL) symcache_cnt++; } symcachetab = xcalloc(symcache_cnt , sizeof(struct symcachetab)); symcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (symcache[i].sym == NULL) continue; symcachetab[symcache_cnt].idx = i; symcachetab[symcache_cnt].obj_idx = libmap[symcache[i].obj->dyn.null]; symcachetab[symcache_cnt].sym_idx = symcache[i].sym - symcache[i].obj->dyn.symtab; symcache_cnt++; } /* now do plt */ pltsymcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (pltsymcache[i].sym != NULL) pltsymcache_cnt++; } pltsymcachetab = xcalloc(pltsymcache_cnt , sizeof(struct symcachetab)); pltsymcache_cnt = 0; for (i = 0; i < object->nchains; i++) { if (pltsymcache[i].sym == NULL) continue; pltsymcachetab[pltsymcache_cnt].idx = i; pltsymcachetab[pltsymcache_cnt].obj_idx = libmap[pltsymcache[i].obj->dyn.null]; pltsymcachetab[pltsymcache_cnt].sym_idx = pltsymcache[i].sym - pltsymcache[i].obj->dyn.symtab; pltsymcache_cnt++; } objarray[object->dyn.null].numlibs = numlibs; nameidx = xcalloc(numlibs, sizeof (struct nameidx)); nametab = xmalloc(nametablen); nametablen = 0; for (i = 0; i < numlibs; i++) { nameidx[i].name = nametablen; nameidx[i].id0 = objarray[idxtolib[i]].id0; nameidx[i].id1 = objarray[idxtolib[i]].id1; nametablen += strlen(objarray[idxtolib[i]].obj->load_name) + 1; strlcpy(&nametab[nameidx[i].name], objarray[idxtolib[i]].obj->load_name, nametablen - nameidx[i].name); } pl->libmapcnt = xcalloc(numlibs, sizeof(u_int32_t)); /* have to do both got and plt fixups */ for (i = 0; i < numlibs; i++) { for (j = 0; j < pl->fixupcnt[2*i]; j++) { pl->fixup[2*i][j].obj_idx = libmap[pl->fixup[2*i][j].obj_idx]; } for (j = 0; j < pl->fixupcnt[2*i+1]; j++) { pl->fixup[2*i+1][j].obj_idx = libmap[pl->fixup[2*i+1][j].obj_idx]; } pl->libmapcnt[i] = objarray[idxtolib[i]].numlibs; pl->libmap[i] = xcalloc(objarray[idxtolib[i]].numlibs, sizeof(u_int32_t)); if (i != 0) { for (j = 0; j < objarray[idxtolib[i]].numlibs; j++) { pl->libmap[i][j] = libmap[objarray[idxtolib[i]].idxtolib[j]]; } } } ret = elf_write_lib(object, nameidx, nametab, nametablen, numlibs, numlibs, pl->fixup, pl->fixupcnt, pl->libmap, pl->libmapcnt, symcachetab, symcache_cnt, pltsymcachetab, pltsymcache_cnt); free(symcachetab); free(pltsymcachetab); free(idxtolib); free(nameidx); free(nametab); free(libmap); return ret; } int elf_write_lib(struct elf_object *object, struct nameidx *nameidx, char *nametab, int nametablen, int numlibs, int nfixup, struct fixup **fixup, int *fixupcnt, u_int32_t **libmap, int *libmapcnt, struct symcachetab *symcachetab, int symcache_cnt, struct symcachetab *pltsymcachetab, int pltsymcache_cnt) { struct prebind_footer footer; struct prebind_info info; u_int32_t footer_offset, *maptab = NULL; u_int32_t next_start, *fixuptab = NULL; struct stat ifstat; off_t base_offset; ssize_t len; int fd = -1, i; int readonly = 0; /* open the file, if in safe mode, only open it readonly */ if (safe == 0) fd = open(object->load_name, O_RDWR); if (fd == -1) { if (safe != 0 || errno == ETXTBSY) fd = open(object->load_name, O_RDONLY); if (fd == -1) { perror(object->load_name); return 1; } readonly = 1; } if (lseek(fd, -((off_t)sizeof(struct prebind_footer)), SEEK_END) == -1) { perror(object->load_name); close(fd); return 1; } len = read(fd, &footer, sizeof(struct prebind_footer)); if (len != sizeof(struct prebind_footer)) { close(fd); if (len == -1) perror(object->load_name); else /* paranoia */ warnx("%s on %s: short read (corrupted file?)", __func__, object->load_name); return 1; } if (fstat(fd, &ifstat) == -1) { perror(object->load_name); exit(10); } if (footer.bind_id[0] == BIND_ID0 && footer.bind_id[1] == BIND_ID1 && footer.bind_id[2] == BIND_ID2 && footer.bind_id[3] == BIND_ID3 && readonly == 0) { ftruncate(fd, footer.orig_size); elf_clear_prog_load(fd, object); base_offset = footer.orig_size; } else { base_offset = ifstat.st_size; } bzero(&footer, sizeof(struct prebind_footer)); /* verify dev/inode - do we care about last modified? */ /* pieces to store on lib * * offset to footer * nameidx - numlibs * sizeof nameidx * symcache - symcache_cnt * sizeof (symcache_idx) * pltsymcache - pltsymcache_cnt * sizeof (symcache_idx) * fixup(N/A for lib) - nfixup * sizeof (symcache_idx) * nametab - nametablen * footer (not aligned) */ footer.orig_size = base_offset; base_offset = ELF_ROUND(base_offset, sizeof(u_int64_t)); footer.prebind_base = base_offset; footer.nameidx_idx = sizeof(u_int32_t); footer.symcache_idx = footer.nameidx_idx + numlibs * sizeof (struct nameidx); footer.pltsymcache_idx = footer.symcache_idx + symcache_cnt * sizeof (struct nameidx); footer.symcache_cnt = symcache_cnt; footer.pltsymcache_cnt = pltsymcache_cnt; footer.fixup_cnt = 0; footer.numlibs = numlibs; next_start = footer.pltsymcache_idx + (pltsymcache_cnt * sizeof (struct symcachetab)); if (nfixup != 0) { footer.fixup_cnt = nfixup; footer.fixup_idx = next_start; next_start += 2*nfixup * sizeof(u_int32_t); footer.fixupcnt_idx = next_start; next_start += 2*nfixup * sizeof(u_int32_t); fixuptab = xcalloc(2*nfixup, sizeof(u_int32_t)); for (i = 0; i < 2*nfixup; i++) { fixuptab[i] = next_start; next_start += fixupcnt[i] * sizeof(struct fixup); } footer.libmap_idx = next_start; next_start += 2*nfixup * sizeof(u_int32_t); maptab = xcalloc(2*nfixup, sizeof(u_int32_t)); maptab[0] = next_start; for (i = 1; i < nfixup; i++) { maptab[i] = next_start; next_start += libmapcnt[i] * sizeof(u_int32_t); } } footer.nametab_idx = next_start; next_start += nametablen; next_start = ELF_ROUND(next_start, sizeof(u_int64_t)); footer_offset = next_start; if (verbose > 1) { printf("footer_offset %d\n", footer_offset); } footer.prebind_size = next_start + sizeof(struct prebind_footer); footer.prebind_version = PREBIND_VERSION; footer.id0 = objarray[object->dyn.null].id0; footer.id1 = objarray[object->dyn.null].id1; footer.bind_id[0] = BIND_ID0; footer.bind_id[1] = BIND_ID1; footer.bind_id[2] = BIND_ID2; footer.bind_id[3] = BIND_ID3; info.object = object; info.footer = &footer; info.footer_offset = footer_offset; info.nameidx = nameidx; info.symcache = symcachetab; info.pltsymcache = pltsymcachetab; info.nfixup = nfixup; if (nfixup != 0) { info.fixuptab = fixuptab; info.fixupcnt = fixupcnt; info.fixup = fixup; info.maptab = maptab; info.libmap = libmap; info.libmapcnt = libmapcnt; } info.nametab = nametab; info.nametablen = nametablen; if (readonly) { prebind_writenewfile(fd, object->load_name, &ifstat, (off_t)footer.orig_size, &info); } else { prebind_writefile(fd, &info); } if (fstat(fd, &ifstat) == -1) { perror(object->load_name); exit(10); } if (nfixup != 0) { free(fixuptab); free(maptab); } if (verbose > 0) printf("%s: prebind info %d bytes old size %lld, growth %f\n", object->load_name, footer.prebind_size, footer.orig_size, (double)(footer.prebind_size) / footer.orig_size); if (verbose > 1) elf_dump_footer(&footer); close(fd); return 0; } int prebind_writefile(int fd, struct prebind_info *info) { int i; struct prebind_footer *footer = info->footer; lseek(fd, footer->prebind_base, SEEK_SET); write(fd, &info->footer_offset, sizeof(u_int32_t)); lseek(fd, footer->prebind_base+footer->nameidx_idx, SEEK_SET); write(fd, info->nameidx, footer->numlibs * sizeof (struct nameidx)); lseek(fd, footer->prebind_base+footer->symcache_idx, SEEK_SET); write(fd, info->symcache, footer->symcache_cnt * sizeof (struct symcachetab)); lseek(fd, footer->prebind_base+footer->pltsymcache_idx, SEEK_SET); write(fd, info->pltsymcache, footer->pltsymcache_cnt * sizeof (struct symcachetab)); if (info->nfixup != 0) { lseek(fd, footer->prebind_base+footer->fixup_idx, SEEK_SET); write(fd, info->fixuptab, 2*info->nfixup * sizeof(u_int32_t)); lseek(fd, footer->prebind_base+footer->fixupcnt_idx, SEEK_SET); write(fd, info->fixupcnt, 2*info->nfixup * sizeof(u_int32_t)); for (i = 0; i < 2*info->nfixup; i++) { lseek(fd, footer->prebind_base+info->fixuptab[i], SEEK_SET); write(fd, info->fixup[i], info->fixupcnt[i] * sizeof(struct fixup)); } lseek(fd, footer->prebind_base+footer->libmap_idx, SEEK_SET); write(fd, info->maptab, info->nfixup * sizeof(u_int32_t)); for (i = 0; i < info->nfixup; i++) { lseek(fd, footer->prebind_base+info->maptab[i], SEEK_SET); write(fd, info->libmap[i], info->libmapcnt[i] * sizeof(u_int32_t)); } } lseek(fd, footer->prebind_base+footer->nametab_idx, SEEK_SET); write(fd, info->nametab, info->nametablen); lseek(fd, footer->prebind_base+info->footer_offset, SEEK_SET); write(fd, footer, sizeof (struct prebind_footer)); if (info->object->obj_type == OBJTYPE_EXE) elf_fixup_prog_load(fd, info->footer, info->object); return 0; } int prebind_writenewfile(int infd, char *name, struct stat *st, off_t orig_size, struct prebind_info *info) { struct timespec ts[2]; char *newname, *buf; ssize_t len, wlen; int outfd; if (asprintf(&newname, "%s.XXXXXXXXXX", name) == -1) { if (verbose) warn("asprintf"); return (-1); } outfd = open(newname, O_CREAT|O_RDWR|O_TRUNC, 0600); if (outfd == -1) { warn("%s", newname); free(newname); return (-1); } buf = malloc(BUFSZ); if (buf == NULL) { if (verbose) warn("malloc"); goto fail; } /* copy old file to new file */ lseek(infd, (off_t)0, SEEK_SET); while (1) { len = read(infd, buf, BUFSIZ); if (len == -1) { if (verbose) warn("read"); free(buf); goto fail; } if (len == 0) break; wlen = write(outfd, buf, len); if (wlen != len) { free(buf); goto fail; } } free(buf); /* now back track, and delete the header */ if (prebind_remove_load_section(outfd, newname) == -1) goto fail; if (orig_size != (off_t)-1 && ftruncate(outfd, orig_size) == -1) goto fail; prebind_writefile(outfd, info); /* move new file into place */ ts[0] = st->st_atimespec; ts[1] = st->st_mtimespec; if (futimens(outfd, ts) == -1) goto fail; if (fchown(outfd, st->st_uid, st->st_gid) == -1) goto fail; if (fchmod(outfd, st->st_mode) == -1) goto fail; if (fchflags(outfd, st->st_flags) == -1) goto fail; if (fstat(outfd, st) == -1) { /* XXX */ goto fail; } if (rename(newname, name) == -1) goto fail; close (outfd); return (0); fail: unlink(newname); free(newname); close(outfd); return (-1); } void elf_fixup_prog_load(int fd, struct prebind_footer *footer, struct elf_object *object) { void *buf; Elf_Ehdr *ehdr; Elf_Phdr *phdr; Elf_Phdr phdr_empty; int loadsection; buf = mmap(NULL, 8192, PROT_READ|PROT_WRITE, MAP_FILE | MAP_SHARED, fd, 0); if (buf == MAP_FAILED) { printf("%s: cannot mmap for write\n", object->load_name); return; } ehdr = (Elf_Ehdr *) buf; phdr = (Elf_Phdr *)((char *)buf + ehdr->e_phoff); for (loadsection = 0; loadsection < ehdr->e_phnum; loadsection++) { if (phdr[loadsection].p_type == PT_LOAD) break; } /* verify that extra slot is empty */ bzero(&phdr_empty, sizeof(phdr_empty)); if (bcmp(&phdr[ehdr->e_phnum], &phdr_empty, sizeof(phdr_empty)) != 0) { printf("extra slot not empty\n"); goto done; } phdr[ehdr->e_phnum].p_type = PT_LOAD; phdr[ehdr->e_phnum].p_flags = PF_R | 0x08000000; phdr[ehdr->e_phnum].p_offset = footer->prebind_base; phdr[ehdr->e_phnum].p_vaddr = footer->prebind_base | 0x80000000; phdr[ehdr->e_phnum].p_paddr = footer->prebind_base | 0x40000000; phdr[ehdr->e_phnum].p_filesz = footer->prebind_size; phdr[ehdr->e_phnum].p_memsz = footer->prebind_size; phdr[ehdr->e_phnum].p_align = phdr[loadsection].p_align; ehdr->e_phnum++; done: msync(buf, 8192, MS_SYNC); munmap(buf, 8192); } void elf_clear_prog_load(int fd, struct elf_object *object) { void *buf; Elf_Ehdr *ehdr; Elf_Phdr *phdr; Elf_Phdr phdr_empty; int loadsection; buf = mmap(NULL, 8192, PROT_READ|PROT_WRITE, MAP_FILE | MAP_SHARED, fd, 0); if (buf == MAP_FAILED) { printf("%s: cannot mmap for write\n", object->load_name); return; } ehdr = (Elf_Ehdr *) buf; phdr = (Elf_Phdr *)((char *)buf + ehdr->e_phoff); if (ehdr->e_type != ET_EXEC) { goto done; } loadsection = ehdr->e_phnum - 1; if ((phdr[loadsection].p_type != PT_LOAD) || ((phdr[loadsection].p_flags & 0x08000000) == 0)) { /* doesn't look like ours */ printf("mapped, %s id doesn't match %lx %d %d\n", object->load_name, (long)(phdr[loadsection].p_vaddr), phdr[loadsection].p_flags, loadsection); goto done; } /* verify that extra slot is empty */ bzero(&phdr[loadsection], sizeof(phdr_empty)); ehdr->e_phnum--; done: msync(buf, 8192, MS_SYNC); munmap(buf, 8192); } void elf_add_object(struct elf_object *object, int objtype) { struct objarray_list *newarray; struct objlist *ol; ol = xmalloc(sizeof (struct objlist)); ol->object = object; if (objtype != OBJTYPE_EXE) TAILQ_INSERT_TAIL(&library_list, ol, list); if (objarray_cnt+1 >= objarray_sz) { objarray_sz += 512; newarray = realloc(objarray, sizeof (objarray[0]) * objarray_sz); if (newarray != NULL) objarray = newarray; else { perror("objarray"); exit(20); } } object->dyn.null = objarray_cnt; /* Major abuse, I know */ TAILQ_INIT(&(objarray[objarray_cnt].inst_list)); objarray[objarray_cnt].obj = object; objarray[objarray_cnt].id0 = arc4random(); objarray[objarray_cnt].id1 = arc4random(); objarray[objarray_cnt].symcache = xcalloc( sizeof(struct symcache_noflag), object->nchains); objarray[objarray_cnt].pltsymcache = xcalloc( sizeof(struct symcache_noflag), object->nchains); objarray[objarray_cnt].oprebind_data = NULL; objarray[objarray_cnt].proglist = NULL; objarray[objarray_cnt].numlibs = 0; objarray_cnt++; elf_add_object_curbin_list(object); } void elf_free_curbin_list(elf_object_t *object) { struct objlist *ol; int i; while (!TAILQ_EMPTY(&(curbin->curbin_list))) { ol = TAILQ_FIRST(&(curbin->curbin_list)); TAILQ_REMOVE(&(objarray[ol->object->dyn.null].inst_list), ol, inst_list); TAILQ_REMOVE(&(curbin->curbin_list), ol, list); free(ol); } printf("trying to remove %s\n", object->load_name); for (i = objarray_cnt; i != 0;) { i--; printf("obj %s\n", objarray[i].obj->load_name); if (objarray[i].obj == object) { printf("found obj at %d max obj %d\n", i, objarray_cnt); TAILQ_FOREACH(ol, &(curbin->curbin_list), list) { } /* XXX - delete references */ objarray_cnt = i; break; } } } void elf_print_objarray(void) { int i; struct objlist *ol; printf("loaded objs # %d\n", objarray_cnt); for (i = 0; i < objarray_cnt; i++) { printf("%3d: %d obj %s\n", i, (int)objarray[i].obj->dyn.null, objarray[i].obj->load_name); TAILQ_FOREACH(ol, &(objarray[i].inst_list), inst_list) { printf("\tprog %s\n", ol->load_prog->load_name); } } } void elf_load_existing_prebind(struct elf_object *object, int fd) { struct prebind_footer footer; void *prebind_data; lseek(fd, -((off_t)sizeof(struct prebind_footer)), SEEK_END); read(fd, &footer, sizeof(struct prebind_footer)); if (footer.bind_id[0] != BIND_ID0 || footer.bind_id[1] != BIND_ID1 || footer.bind_id[2] != BIND_ID2 || footer.bind_id[3] != BIND_ID3) return; prebind_data = mmap(0, footer.prebind_size, PROT_READ, MAP_FILE, fd, footer.prebind_base); objarray[object->dyn.null].oprebind_data = prebind_data; objarray[object->dyn.null].id0 = footer.id0; objarray[object->dyn.null].id1 = footer.id1; copy_oldsymcache(object->dyn.null, prebind_data); } void copy_oldsymcache(int objidx, char *prebind_map) { struct prebind_footer *footer; struct elf_object *tobj; struct symcache_noflag *tcache; struct symcachetab *symcache; int i, j, found, *idxtolib; char *c, *nametab; u_int32_t offset; u_int32_t *poffset; struct nameidx *nameidx; poffset = (u_int32_t *)prebind_map; c = prebind_map; offset = *poffset; c += offset; footer = (void *)c; nameidx = (void *)(prebind_map + footer->nameidx_idx); nametab = (void *)(prebind_map + footer->nametab_idx); idxtolib = xcalloc(footer->numlibs, sizeof(int)); found = 0; for (i = 0; i < footer->numlibs; i++) { found = 0; for (j = 0; j < objarray_cnt; j++) { if (objarray[j].id0 == nameidx[i].id0 && objarray[j].id1 == nameidx[i].id1) { found = 1; idxtolib[i] = j; if (strcmp(objarray[j].obj->load_name, &nametab[nameidx[i].name]) != 0) { printf("warning filename mismatch" " [%s] [%s]\n", objarray[j].obj->load_name, &nametab[nameidx[i].name]); } } } if (found == 0) break; } if (found == 0) goto done; /* build idxtolibs */ tcache = objarray[objidx].symcache; symcache = (void *)(prebind_map + footer->symcache_idx); for (i = 0; i < footer->symcache_cnt; i++) { tobj = objarray[idxtolib[symcache[i].obj_idx]].obj; tcache[symcache[i].idx].obj = tobj; tcache[symcache[i].idx].sym = tobj->dyn.symtab + symcache[i].sym_idx; } tcache = objarray[objidx].pltsymcache; symcache = (void *)(prebind_map + footer->pltsymcache_idx); for (i = 0; i < footer->pltsymcache_cnt; i++) { tobj = objarray[idxtolib[symcache[i].obj_idx]].obj; tcache[symcache[i].idx].obj = tobj; tcache[symcache[i].idx].sym = tobj->dyn.symtab + symcache[i].sym_idx; } done: free(idxtolib); /* munmap(prebind_map, size);*/ }