#include #include #include #include #include #include #include #include //#include #include #include #include #include "linker.h" #include "linker_debug.h" #define SO_MAX 64 /* >>> IMPORTANT NOTE - READ ME BEFORE MODIFYING <<< * * Do NOT use malloc() and friends or pthread_*() code here. * Don't use printf() either; it's caused mysterious memory * corruption in the past. * The linker runs before we bring up libc and it's easiest * to make sure it does not depend on any complex libc features * * open issues / todo: * * - should we do anything special for STB_WEAK symbols? * - are we doing everything we should for ARM_COPY relocations? * - cleaner error reporting * - configuration for paths (LD_LIBRARY_PATH?) * - after linking, set as much stuff as possible to READONLY * and NOEXEC * - linker hardcodes PAGE_SIZE and PAGE_MASK because the kernel * headers provide versions that are negative... * - allocate space for soinfo structs dynamically instead of * having a hard limit (64) * * features to add someday: * * - dlopen() and friends * */ static int link_image(soinfo *si, unsigned wr_offset); static int socount = 0; static soinfo sopool[SO_MAX]; static soinfo *freelist = NULL; static soinfo *solist = &libdl_info; static soinfo *sonext = &libdl_info; int debug_verbosity; static int pid; #if STATS struct _link_stats linker_stats; #endif #if COUNT_PAGES unsigned bitmask[4096]; #endif #ifndef PT_ARM_EXIDX #define PT_ARM_EXIDX 0x70000001 /* .ARM.exidx segment */ #endif /* * This function is an empty stub where GDB locates a breakpoint to get notified * about linker activity. */ extern void __attribute__((noinline)) rtld_db_dlactivity(void); extern void sched_yield(void); static struct r_debug _r_debug = {1, NULL, &rtld_db_dlactivity, RT_CONSISTENT, 0}; static struct link_map *r_debug_tail = 0; //static pthread_mutex_t _r_debug_lock = PTHREAD_MUTEX_INITIALIZER; static volatile int loader_lock = 0; static void insert_soinfo_into_debug_map(soinfo * info) { struct link_map * map; /* Copy the necessary fields into the debug structure. */ map = &(info->linkmap); map->l_addr = info->base; map->l_name = (char*) info->name; /* Stick the new library at the end of the list. * gdb tends to care more about libc than it does * about leaf libraries, and ordering it this way * reduces the back-and-forth over the wire. */ if (r_debug_tail) { r_debug_tail->l_next = map; map->l_prev = r_debug_tail; map->l_next = 0; } else { _r_debug.r_map = map; map->l_prev = 0; map->l_next = 0; } r_debug_tail = map; } void notify_gdb_of_load(soinfo * info) { if (info->flags & FLAG_EXE) { // GDB already knows about the main executable return; } /* yes, this is a little gross, but it does avoid ** pulling in pthread_*() and at the moment we don't ** dlopen() anything anyway */ while(__atomic_swap(1, &loader_lock) != 0) { sched_yield(); usleep(5000); } _r_debug.r_state = RT_ADD; rtld_db_dlactivity(); insert_soinfo_into_debug_map(info); _r_debug.r_state = RT_CONSISTENT; rtld_db_dlactivity(); __atomic_swap(0, &loader_lock); } void notify_gdb_of_libraries() { _r_debug.r_state = RT_ADD; rtld_db_dlactivity(); _r_debug.r_state = RT_CONSISTENT; rtld_db_dlactivity(); } static soinfo *alloc_info(const char *name) { soinfo *si; if(strlen(name) >= SOINFO_NAME_LEN) { ERROR("%5d library name %s too long\n", pid, name); return 0; } /* The freelist is populated when we call free_info(), which in turn is done only by dlclose(), which is not likely to be used. */ if (!freelist) { if(socount == SO_MAX) { ERROR("%5d too many libraries when loading %s\n", pid, name); return NULL; } freelist = sopool + socount++; freelist->next = NULL; } si = freelist; freelist = freelist->next; /* Make sure we get a clean block of soinfo */ memset(si, 0, sizeof(soinfo)); strcpy((char*) si->name, name); sonext->next = si; si->next = NULL; si->refcount = 0; sonext = si; TRACE("%5d name %s: allocated soinfo @ %p\n", pid, name, si); return si; } static void free_info(soinfo *si) { soinfo *prev = NULL, *trav; TRACE("%5d name %s: freeing soinfo @ %p\n", pid, si->name, si); for(trav = solist; trav != NULL; trav = trav->next){ if (trav == si) break; prev = trav; } if (trav == NULL) { /* si was not ni solist */ ERROR("%5d name %s is not in solist!\n", pid, si->name); return; } /* prev will never be NULL, because the first entry in solist is always the static libdl_info. */ prev->next = si->next; if (si == sonext) sonext = prev; si->next = freelist; freelist = si; } #ifndef LINKER_TEXT_BASE #error "linker's makefile must define LINKER_TEXT_BASE" #endif #ifndef LINKER_AREA_SIZE #error "linker's makefile must define LINKER_AREA_SIZE" #endif #define LINKER_BASE ((LINKER_TEXT_BASE) & 0xfff00000) #define LINKER_TOP (LINKER_BASE + (LINKER_AREA_SIZE)) const char *addr_to_name(unsigned addr) { soinfo *si; for(si = solist; si != 0; si = si->next){ if((addr >= si->base) && (addr < (si->base + si->size))) { return si->name; } } if((addr >= LINKER_BASE) && (addr < LINKER_TOP)){ return "linker"; } return ""; } /* For a given PC, find the .so that it belongs to. * Returns the base address of the .ARM.exidx section * for that .so, and the number of 8-byte entries * in that section (via *pcount). * * Intended to be called by libc's __gnu_Unwind_Find_exidx(). * * This function is exposed via dlfcn.c and libdl.so. */ #ifdef ANDROID_ARM_LINKER _Unwind_Ptr dl_unwind_find_exidx(_Unwind_Ptr pc, int *pcount) { soinfo *si; unsigned addr = (unsigned)pc; if ((addr < LINKER_BASE) || (addr >= LINKER_TOP)) { for (si = solist; si != 0; si = si->next){ if ((addr >= si->base) && (addr < (si->base + si->size))) { *pcount = si->ARM_exidx_count; return (_Unwind_Ptr)(si->base + (unsigned long)si->ARM_exidx); } } } *pcount = 0; return NULL; } #elif defined(ANDROID_X86_LINKER) /* Here, we only have to provide a callback to iterate across all the * loaded libraries. gcc_eh does the rest. */ int dl_iterate_phdr(int (*cb)(struct dl_phdr_info *info, size_t size, void *data), void *data) { soinfo *si; struct dl_phdr_info dl_info; int rv = 0; for (si = solist; si != NULL; si = si->next) { dl_info.dlpi_addr = si->linkmap.l_addr; dl_info.dlpi_name = si->linkmap.l_name; dl_info.dlpi_phdr = si->phdr; dl_info.dlpi_phnum = si->phnum; rv = cb(&dl_info, sizeof (struct dl_phdr_info), data); if (rv != 0) break; } return rv; } #endif static Elf32_Sym *_elf_lookup(soinfo *si, unsigned hash, const char *name) { Elf32_Sym *s; Elf32_Sym *symtab = si->symtab; const char *strtab = si->strtab; unsigned n; TRACE_TYPE(LOOKUP, "%5d SEARCH %s in %s@0x%08x %08x %d\n", pid, name, si->name, si->base, hash, hash % si->nbucket); n = hash % si->nbucket; for(n = si->bucket[hash % si->nbucket]; n != 0; n = si->chain[n]){ s = symtab + n; if(strcmp(strtab + s->st_name, name)) continue; /* only concern ourselves with global symbols */ switch(ELF32_ST_BIND(s->st_info)){ case STB_GLOBAL: /* no section == undefined */ if(s->st_shndx == 0) continue; case STB_WEAK: TRACE_TYPE(LOOKUP, "%5d FOUND %s in %s (%08x) %d\n", pid, name, si->name, s->st_value, s->st_size); return s; } } return 0; } static unsigned elfhash(const char *_name) { const unsigned char *name = (const unsigned char *) _name; unsigned h = 0, g; while(*name) { h = (h << 4) + *name++; g = h & 0xf0000000; h ^= g; h ^= g >> 24; } return h; } static Elf32_Sym * _do_lookup_in_so(soinfo *si, const char *name, unsigned *elf_hash) { if (*elf_hash == 0) *elf_hash = elfhash(name); return _elf_lookup (si, *elf_hash, name); } /* This is used by dl_sym() */ Elf32_Sym *lookup_in_library(soinfo *si, const char *name) { unsigned unused = 0; return _do_lookup_in_so(si, name, &unused); } static Elf32_Sym * _do_lookup(soinfo *user_si, const char *name, unsigned *base) { unsigned elf_hash = 0; Elf32_Sym *s = NULL; soinfo *si; /* Look for symbols in the local scope first (the object who is * searching). This happens with C++ templates on i386 for some * reason. */ if (user_si) { s = _do_lookup_in_so(user_si, name, &elf_hash); if (s != NULL) *base = user_si->base; } for(si = solist; (s == NULL) && (si != NULL); si = si->next) { if((si->flags & FLAG_ERROR) || (si == user_si)) continue; s = _do_lookup_in_so(si, name, &elf_hash); if (s != NULL) { *base = si->base; break; } } if (s != NULL) { TRACE_TYPE(LOOKUP, "%5d %s s->st_value = 0x%08x, " "si->base = 0x%08x\n", pid, name, s->st_value, si->base); return s; } return 0; } /* This is used by dl_sym() */ Elf32_Sym *lookup(const char *name, unsigned *base) { return _do_lookup(NULL, name, base); } #if 0 static void dump(soinfo *si) { Elf32_Sym *s = si->symtab; unsigned n; for(n = 0; n < si->nchain; n++) { TRACE("%5d %04d> %08x: %02x %04x %08x %08x %s\n", pid, n, s, s->st_info, s->st_shndx, s->st_value, s->st_size, si->strtab + s->st_name); s++; } } #endif static const char *sopaths[] = { "/system/lib", "/lib", 0 }; static int open_library(const char *name) { int fd; char buf[512]; const char **path; TRACE("[ %5d opening %s ]\n", pid, name); if(strlen(name) > 256) return -1; if(name == 0) return -1; fd = open(name, O_RDONLY); if(fd != -1) return fd; for(path = sopaths; *path; path++){ sprintf(buf,"%s/%s", *path, name); fd = open(buf, O_RDONLY); if(fd != -1) return fd; } return -1; } static unsigned libbase = LIBBASE; /* temporary space for holding the first page of the shared lib * which contains the elf header (with the pht). */ static unsigned char __header[PAGE_SIZE]; typedef struct { long mmap_addr; char tag[4]; /* 'P', 'R', 'E', ' ' */ } prelink_info_t; /* Returns the requested base address if the library is prelinked, * and 0 otherwise. */ static unsigned long is_prelinked(int fd, const char *name) { off_t sz; prelink_info_t info; sz = lseek(fd, -sizeof(prelink_info_t), SEEK_END); if (sz < 0) { ERROR("lseek() failed!\n"); return 0; } if (read(fd, &info, sizeof(info)) != sizeof(info)) { WARN("Could not read prelink_info_t structure for `%s`\n", name); return 0; } if (strncmp(info.tag, "PRE ", 4)) { WARN("`%s` is not a prelinked library\n", name); return 0; } return (unsigned long)info.mmap_addr; } /* verify_elf_object * Verifies if the object @ base is a valid ELF object * * Args: * * Returns: * 0 on success * -1 if no valid ELF object is found @ base. */ static int verify_elf_object(void *base, const char *name) { Elf32_Ehdr *hdr = (Elf32_Ehdr *) base; if (hdr->e_ident[EI_MAG0] != ELFMAG0) return -1; if (hdr->e_ident[EI_MAG1] != ELFMAG1) return -1; if (hdr->e_ident[EI_MAG2] != ELFMAG2) return -1; if (hdr->e_ident[EI_MAG3] != ELFMAG3) return -1; /* TODO: Should we verify anything else in the header? */ return 0; } /* get_lib_extents * Retrieves the base (*base) address where the ELF object should be * mapped and its overall memory size (*total_sz). * * Args: * fd: Opened file descriptor for the library * name: The name of the library * _hdr: Pointer to the header page of the library * total_sz: Total size of the memory that should be allocated for * this library * * Returns: * -1 if there was an error while trying to get the lib extents. * The possible reasons are: * - Could not determine if the library was prelinked. * - The library provided is not a valid ELF object * 0 if the library did not request a specific base offset (normal * for non-prelinked libs) * > 0 if the library requests a specific address to be mapped to. * This indicates a pre-linked library. */ static unsigned get_lib_extents(int fd, const char *name, void *__hdr, unsigned *total_sz) { unsigned req_base; unsigned min_vaddr = 0xffffffff; unsigned max_vaddr = 0; unsigned char *_hdr = (unsigned char *)__hdr; Elf32_Ehdr *ehdr = (Elf32_Ehdr *)_hdr; Elf32_Phdr *phdr; int cnt; TRACE("[ %5d Computing extents for '%s'. ]\n", pid, name); if (verify_elf_object(_hdr, name) < 0) { ERROR("%5d - %s is not a valid ELF object\n", pid, name); return (unsigned)-1; } req_base = (unsigned) is_prelinked(fd, name); if (req_base == (unsigned)-1) return -1; else if (req_base != 0) { TRACE("[ %5d - Prelinked library '%s' requesting base @ 0x%08x ]\n", pid, name, req_base); } else { TRACE("[ %5d - Non-prelinked library '%s' found. ]\n", pid, name); } phdr = (Elf32_Phdr *)(_hdr + ehdr->e_phoff); /* find the min/max p_vaddrs from all the PT_LOAD segments so we can * get the range. */ for (cnt = 0; cnt < ehdr->e_phnum; ++cnt, ++phdr) { if (phdr->p_type == PT_LOAD) { if ((phdr->p_vaddr + phdr->p_memsz) > max_vaddr) max_vaddr = phdr->p_vaddr + phdr->p_memsz; if (phdr->p_vaddr < min_vaddr) min_vaddr = phdr->p_vaddr; } } if ((min_vaddr == 0xffffffff) && (max_vaddr == 0)) { ERROR("%5d - No loadable segments found in %s.\n", pid, name); return (unsigned)-1; } /* truncate min_vaddr down to page boundary */ min_vaddr &= ~PAGE_MASK; /* round max_vaddr up to the next page */ max_vaddr = (max_vaddr + PAGE_SIZE - 1) & ~PAGE_MASK; *total_sz = (max_vaddr - min_vaddr); return (unsigned)req_base; } /* alloc_mem_region * * This function reserves a chunk of memory to be used for mapping in * the shared library. We reserve the entire memory region here, and * then the rest of the linker will relocate the individual loadable * segments into the correct locations within this memory range. * * Args: * req_base: The requested base of the allocation. If 0, a sane one will be * chosen in the range LIBBASE <= base < LIBLAST. * sz: The size of the allocation. * * Returns: * NULL on failure, and non-NULL pointer to memory region on success. */ static void * alloc_mem_region(const char *name, unsigned req_base, unsigned sz) { void *base; if (req_base) { /* we should probably map it as PROT_NONE, but the init code needs * to read the phdr, so mark everything as readable. */ base = mmap((void *)req_base, sz, PROT_READ | PROT_EXEC, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); if (base == MAP_FAILED) { WARN("%5d can NOT map (prelinked) library '%s' at 0x%08x " "as requested, will try general pool: %d (%s)\n", pid, name, req_base, errno, strerror(errno)); } else if (base != (void *)req_base) { ERROR("OOPS: %5d prelinked library '%s' mapped at 0x%08x, " "not at 0x%08x\n", pid, name, (unsigned)base, req_base); munmap(base, sz); return NULL; } /* Here we know that we got a valid allocation. Hooray! */ return base; } /* We either did not request a specific base address to map at * (i.e. not-prelinked) OR we could not map at the requested address. * Try to find a memory range in our "reserved" area that can be mapped. */ while(libbase < LIBLAST) { base = mmap((void*) libbase, sz, PROT_READ | PROT_EXEC, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0); if(((unsigned)base) == libbase) { /* success -- got the address we wanted */ return base; } /* If we got a different address than requested (rather than * just a failure), we need to unmap the mismapped library * before trying again */ if(base != MAP_FAILED) munmap(base, sz); libbase += LIBINC; } ERROR("OOPS: %5d cannot map library '%s'. no vspace available.\n", pid, name); return NULL; } #define MAYBE_MAP_FLAG(x,from,to) (((x) & (from)) ? (to) : 0) #define PFLAGS_TO_PROT(x) (MAYBE_MAP_FLAG((x), PF_X, PROT_EXEC) | \ MAYBE_MAP_FLAG((x), PF_R, PROT_READ) | \ MAYBE_MAP_FLAG((x), PF_W, PROT_WRITE)) /* load_segments * * This function loads all the loadable (PT_LOAD) segments into memory * at their appropriate memory offsets off the base address. * * Args: * fd: Open file descriptor to the library to load. * header: Pointer to a header page that contains the ELF header. * This is needed since we haven't mapped in the real file yet. * si: ptr to soinfo struct describing the shared object. * * Returns: * 0 on success, -1 on failure. */ static int load_segments(int fd, void *header, soinfo *si) { Elf32_Ehdr *ehdr = (Elf32_Ehdr *)header; Elf32_Phdr *phdr = (Elf32_Phdr *)((unsigned char *)header + ehdr->e_phoff); unsigned char *base = (unsigned char *)si->base; int cnt; unsigned len; unsigned char *tmp; unsigned char *pbase; unsigned char *extra_base; unsigned extra_len; unsigned total_sz = 0; si->wrprotect_start = 0xffffffff; si->wrprotect_end = 0; TRACE("[ %5d - Begin loading segments for '%s' @ 0x%08x ]\n", pid, si->name, (unsigned)si->base); /* Now go through all the PT_LOAD segments and map them into memory * at the appropriate locations. */ for (cnt = 0; cnt < ehdr->e_phnum; ++cnt, ++phdr) { if (phdr->p_type == PT_LOAD) { DEBUG_DUMP_PHDR(phdr, "PT_LOAD", pid); /* we want to map in the segment on a page boundary */ tmp = base + (phdr->p_vaddr & (~PAGE_MASK)); /* add the # of bytes we masked off above to the total length. */ len = phdr->p_filesz + (phdr->p_vaddr & PAGE_MASK); TRACE("[ %d - Trying to load segment from '%s' @ 0x%08x " "(0x%08x). p_vaddr=0x%08x p_offset=0x%08x ]\n", pid, si->name, (unsigned)tmp, len, phdr->p_vaddr, phdr->p_offset); pbase = mmap(tmp, len, PFLAGS_TO_PROT(phdr->p_flags), MAP_PRIVATE | MAP_FIXED, fd, phdr->p_offset & (~PAGE_MASK)); if (pbase == MAP_FAILED) { ERROR("%d failed to map segment from '%s' @ 0x%08x (0x%08x). " "p_vaddr=0x%08x p_offset=0x%08x\n", pid, si->name, (unsigned)tmp, len, phdr->p_vaddr, phdr->p_offset); goto fail; } /* If 'len' didn't end on page boundary, and it's a writable * segment, zero-fill the rest. */ if ((len & PAGE_MASK) && (phdr->p_flags & PF_W)) memset((void *)(pbase + len), 0, PAGE_SIZE - (len & PAGE_MASK)); /* Check to see if we need to extend the map for this segment to * cover the diff between filesz and memsz (i.e. for bss). * * base _+---------------------+ page boundary * . . * | | * . . * pbase _+---------------------+ page boundary * | | * . . * base + p_vaddr _| | * . \ \ . * . | filesz | . * pbase + len _| / | | * <0 pad> . . . * extra_base _+------------|--------+ page boundary * / . . . * | . . . * | +------------|--------+ page boundary * extra_len-> | | | | * | . | memsz . * | . | . * \ _| / | * . . * | | * _+---------------------+ page boundary */ tmp = (unsigned char *)(((unsigned)pbase + len + PAGE_SIZE - 1) & (~PAGE_MASK)); if (tmp < (base + phdr->p_vaddr + phdr->p_memsz)) { extra_len = base + phdr->p_vaddr + phdr->p_memsz - tmp; TRACE("[ %5d - Need to extend segment from '%s' @ 0x%08x " "(0x%08x) ]\n", pid, si->name, (unsigned)tmp, extra_len); /* map in the extra page(s) as anonymous into the range. * This is probably not necessary as we already mapped in * the entire region previously, but we just want to be * sure. This will also set the right flags on the region * (though we can probably accomplish the same thing with * mprotect). */ extra_base = mmap((void *)tmp, extra_len, PFLAGS_TO_PROT(phdr->p_flags), MAP_PRIVATE | MAP_FIXED | MAP_ANONYMOUS, -1, 0); if (extra_base == MAP_FAILED) { ERROR("[ %5d - failed to extend segment from '%s' @ 0x%08x " "(0x%08x) ]\n", pid, si->name, (unsigned)tmp, extra_len); goto fail; } /* TODO: Check if we need to memset-0 this region. * Anonymous mappings are zero-filled copy-on-writes, so we * shouldn't need to. */ TRACE("[ %5d - Segment from '%s' extended @ 0x%08x " "(0x%08x)\n", pid, si->name, (unsigned)extra_base, extra_len); } /* set the len here to show the full extent of the segment we * just loaded, mostly for debugging */ len = (((unsigned)base + phdr->p_vaddr + phdr->p_memsz + PAGE_SIZE - 1) & (~PAGE_MASK)) - (unsigned)pbase; TRACE("[ %5d - Successfully loaded segment from '%s' @ 0x%08x " "(0x%08x). p_vaddr=0x%08x p_offset=0x%08x\n", pid, si->name, (unsigned)pbase, len, phdr->p_vaddr, phdr->p_offset); total_sz += len; /* Make the section writable just in case we'll have to write to * it during relocation (i.e. text segment). However, we will * remember what range of addresses should be write protected. * */ if (!(phdr->p_flags & PF_W)) { if ((unsigned)pbase < si->wrprotect_start) si->wrprotect_start = (unsigned)pbase; if (((unsigned)pbase + len) > si->wrprotect_end) si->wrprotect_end = (unsigned)pbase + len; mprotect(pbase, len, PFLAGS_TO_PROT(phdr->p_flags) | PROT_WRITE); } } else if (phdr->p_type == PT_DYNAMIC) { DEBUG_DUMP_PHDR(phdr, "PT_DYNAMIC", pid); /* this segment contains the dynamic linking information */ si->dynamic = (unsigned *)(base + phdr->p_vaddr); } else { #ifdef ANDROID_ARM_LINKER if (phdr->p_type == PT_ARM_EXIDX) { DEBUG_DUMP_PHDR(phdr, "PT_ARM_EXIDX", pid); /* exidx entries (used for stack unwinding) are 8 bytes each. */ si->ARM_exidx = (unsigned *)phdr->p_vaddr; si->ARM_exidx_count = phdr->p_memsz / 8; } #endif } } /* Sanity check */ if (total_sz > si->size) { ERROR("%5d - Total length (0x%08x) of mapped segments from '%s' is " "greater than what was allocated (0x%08x). THIS IS BAD!\n", pid, total_sz, si->name, si->size); goto fail; } TRACE("[ %5d - Finish loading segments for '%s' @ 0x%08x. " "Total memory footprint: 0x%08x bytes ]\n", pid, si->name, (unsigned)si->base, si->size); return 0; fail: /* We can just blindly unmap the entire region even though some things * were mapped in originally with anonymous and others could have been * been mapped in from the file before we failed. The kernel will unmap * all the pages in the range, irrespective of how they got there. */ munmap((void *)si->base, si->size); si->flags |= FLAG_ERROR; return -1; } /* TODO: Implement this to take care of the fact that Android ARM * ELF objects shove everything into a single loadable segment that has the * write bit set. wr_offset is then used to set non-(data|bss) pages to be * non-writable. */ #if 0 static unsigned get_wr_offset(int fd, const char *name, Elf32_Ehdr *ehdr) { Elf32_Shdr *shdr_start; Elf32_Shdr *shdr; int shdr_sz = ehdr->e_shnum * sizeof(Elf32_Shdr); int cnt; unsigned wr_offset = 0xffffffff; shdr_start = mmap(0, shdr_sz, PROT_READ, MAP_PRIVATE, fd, ehdr->e_shoff & (~PAGE_MASK)); if (shdr_start == MAP_FAILED) { WARN("%5d - Could not read section header info from '%s'. Will not " "not be able to determine write-protect offset.\n", pid, name); return (unsigned)-1; } for(cnt = 0, shdr = shdr_start; cnt < ehdr->e_shnum; ++cnt, ++shdr) { if ((shdr->sh_type != SHT_NULL) && (shdr->sh_flags & SHF_WRITE) && (shdr->sh_addr < wr_offset)) { wr_offset = shdr->sh_addr; } } munmap(shdr_start, shdr_sz); return wr_offset; } #endif static soinfo * load_library(const char *name) { int fd = open_library(name); int cnt; unsigned ext_sz; unsigned req_base; void *base; soinfo *si; Elf32_Ehdr *hdr; if(fd == -1) return NULL; /* We have to read the ELF header to figure out what to do with this image */ if (lseek(fd, 0, SEEK_SET) < 0) { ERROR("lseek() failed!\n"); goto fail; } if ((cnt = read(fd, &__header[0], PAGE_SIZE)) < 0) { ERROR("read() failed!\n"); goto fail; } /* Parse the ELF header and get the size of the memory footprint for * the library */ req_base = get_lib_extents(fd, name, &__header[0], &ext_sz); if (req_base == (unsigned)-1) goto fail; TRACE("[ %5d - '%s' (%s) wants base=0x%08x sz=0x%08x ]\n", pid, name, (req_base ? "prelinked" : "not pre-linked"), req_base, ext_sz); /* Carve out a chunk of memory where we will map in the individual * segments */ base = alloc_mem_region(name, req_base, ext_sz); if (base == NULL) goto fail; TRACE("[ %5d allocated memory for %s @ %p (0x%08x) ]\n", pid, name, base, (unsigned) ext_sz); /* Now configure the soinfo struct where we'll store all of our data * for the ELF object. If the loading fails, we waste the entry, but * same thing would happen if we failed during linking. Configuring the * soinfo struct here is a lot more convenient. */ si = alloc_info(name); if (si == NULL) goto fail; si->base = (unsigned)base; si->size = ext_sz; si->flags = 0; si->entry = 0; si->dynamic = (unsigned *)-1; /* Now actually load the library's segments into right places in memory */ if (load_segments(fd, &__header[0], si) < 0) goto fail; /* this might not be right. Technically, we don't even need this info * once we go through 'load_segments'. */ hdr = (Elf32_Ehdr *)base; si->phdr = (Elf32_Phdr *)((unsigned char *)si->base + hdr->e_phoff); si->phnum = hdr->e_phnum; /**/ close(fd); return si; fail: close(fd); return NULL; } static soinfo * init_library(soinfo *si) { unsigned wr_offset = 0xffffffff; unsigned libbase_before = 0; unsigned libbase_after = 0; /* At this point we know that whatever is loaded @ base is a valid ELF * shared library whose segments are properly mapped in. */ TRACE("[ %5d init_library base=0x%08x sz=0x%08x name='%s') ]\n", pid, si->base, si->size, si->name); if (si->base < LIBBASE || si->base >= LIBLAST) si->flags |= FLAG_PRELINKED; /* Adjust libbase for the size of this library, rounded up to ** LIBINC alignment. Make note of the previous and current ** value of libbase to allow us to roll back in the event of ** a link failure. */ if (!(si->flags & FLAG_PRELINKED)) { libbase_before = libbase; libbase += (si->size + (LIBINC - 1)) & (~(LIBINC - 1)); libbase_after = libbase; } if(link_image(si, wr_offset)) { /* We failed to link. However, we can only restore libbase ** if no additional libraries have moved it since we updated it. */ if(!(si->flags & FLAG_PRELINKED) && (libbase == libbase_after)) { libbase = libbase_before; } munmap((void *)si->base, si->size); return NULL; } return si; } soinfo *find_library(const char *name) { soinfo *si; for(si = solist; si != 0; si = si->next){ if(!strcmp(name, si->name)) { if(si->flags & FLAG_ERROR) return 0; if(si->flags & FLAG_LINKED) return si; ERROR("OOPS: %5d recursive link to '%s'\n", pid, si->name); return 0; } } TRACE("[ %5d '%s' has not been loaded yet. Locating...]\n", pid, name); si = load_library(name); if(si == NULL) return NULL; return init_library(si); } /* TODO: * notify gdb of unload * for non-prelinked libraries, find a way to decrement libbase */ static void call_destructors(soinfo *si); unsigned unload_library(soinfo *si) { unsigned *d; if (si->refcount == 1) { TRACE("%5d unloading '%s'\n", pid, si->name); call_destructors(si); for(d = si->dynamic; *d; d += 2) { if(d[0] == DT_NEEDED){ TRACE("%5d %s needs to unload %s\n", pid, si->name, si->strtab + d[1]); soinfo *lsi = find_library(si->strtab + d[1]); if(lsi) unload_library(lsi); else ERROR("%5d could not unload '%s'\n", pid, si->strtab + d[1]); } } munmap((char *)si->base, si->size); free_info(si); si->refcount = 0; } else { si->refcount--; ERROR("%5d not unloading '%s', decrementing refcount to %d\n", pid, si->name, si->refcount); } return si->refcount; } /* TODO: don't use unsigned for addrs below. It works, but is not * ideal. They should probably be either uint32_t, Elf32_Addr, or unsigned * long. */ static int reloc_library(soinfo *si, Elf32_Rel *rel, unsigned count) { Elf32_Sym *symtab = si->symtab; const char *strtab = si->strtab; Elf32_Sym *s; unsigned base; Elf32_Rel *start = rel; unsigned idx; for (idx = 0; idx < count; ++idx) { unsigned type = ELF32_R_TYPE(rel->r_info); unsigned sym = ELF32_R_SYM(rel->r_info); unsigned reloc = (unsigned)(rel->r_offset + si->base); unsigned sym_addr = 0; char *sym_name = NULL; DEBUG("%5d Processing '%s' relocation at index %d\n", pid, si->name, idx); if(sym != 0) { s = _do_lookup(si, strtab + symtab[sym].st_name, &base); if(s == 0) { ERROR("%5d cannot locate '%s'...\n", pid, sym_name); return -1; } #if 0 if((base == 0) && (si->base != 0)){ /* linking from libraries to main image is bad */ ERROR("%5d cannot locate '%s'...\n", pid, strtab + symtab[sym].st_name); return -1; } #endif if ((s->st_shndx == SHN_UNDEF) && (s->st_value != 0)) { ERROR("%5d In '%s', shndx=%d && value=0x%08x. We do not " "handle this yet\n", pid, si->name, s->st_shndx, s->st_value); return -1; } sym_addr = (unsigned)(s->st_value + base); sym_name = (char *)(strtab + symtab[sym].st_name); COUNT_RELOC(RELOC_SYMBOL); } else { s = 0; } /* TODO: This is ugly. Split up the relocations by arch into * different files. */ switch(type){ #if defined(ANDROID_ARM_LINKER) case R_ARM_JUMP_SLOT: case R_ARM_GLOB_DAT: case R_ARM_ABS32: COUNT_RELOC(RELOC_ABSOLUTE); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO ABS %08x <- %08x %s\n", pid, reloc, sym_addr, sym_name); *((unsigned*)reloc) = sym_addr; break; #elif defined(ANDROID_X86_LINKER) case R_386_JUMP_SLOT: COUNT_RELOC(RELOC_ABSOLUTE); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO JMP_SLOT %08x <- %08x %s\n", pid, reloc, sym_addr, sym_name); *((unsigned*)reloc) = sym_addr; break; case R_386_GLOB_DAT: COUNT_RELOC(RELOC_ABSOLUTE); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO GLOB_DAT %08x <- %08x %s\n", pid, reloc, sym_addr, sym_name); *((unsigned*)reloc) = sym_addr; break; #endif /* ANDROID_*_LINKER */ #if defined(ANDROID_ARM_LINKER) case R_ARM_RELATIVE: #elif defined(ANDROID_X86_LINKER) case R_386_RELATIVE: #endif /* ANDROID_*_LINKER */ COUNT_RELOC(RELOC_RELATIVE); MARK(rel->r_offset); if(sym){ ERROR("%5d odd RELATIVE form...\n", pid); return -1; } TRACE_TYPE(RELO, "%5d RELO RELATIVE %08x <- +%08x\n", pid, reloc, si->base); *((unsigned*)reloc) += si->base; break; #if defined(ANDROID_X86_LINKER) case R_386_32: COUNT_RELOC(RELOC_RELATIVE); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO R_386_32 %08x <- +%08x %s\n", pid, reloc, sym_addr, sym_name); *((unsigned *)reloc) += (unsigned)sym_addr; break; case R_386_PC32: COUNT_RELOC(RELOC_RELATIVE); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO R_386_PC32 %08x <- " "+%08x (%08x - %08x) %s\n", pid, reloc, (sym_addr - reloc), sym_addr, reloc, sym_name); *((unsigned *)reloc) += (unsigned)(sym_addr - reloc); break; #endif /* ANDROID_X86_LINKER */ #ifdef ANDROID_ARM_LINKER case R_ARM_COPY: COUNT_RELOC(RELOC_COPY); MARK(rel->r_offset); TRACE_TYPE(RELO, "%5d RELO %08x <- %d @ %08x %s\n", pid, reloc, s->st_size, sym_addr, sym_name); memcpy((void*)reloc, (void*)sym_addr, s->st_size); break; #endif /* ANDROID_ARM_LINKER */ default: ERROR("%5d unknown reloc type %d @ %p (%d)\n", pid, type, rel, (int) (rel - start)); return -1; } rel++; } return 0; } static void call_array(unsigned *ctor, int count) { int n; for(n = count; n > 0; n--){ TRACE("[ %5d Looking at ctor *0x%08x == 0x%08x ]\n", pid, (unsigned)ctor, (unsigned)*ctor); void (*func)() = (void (*)()) *ctor++; if(((int) func == 0) || ((int) func == -1)) continue; TRACE("[ %5d Calling func @ 0x%08x ]\n", pid, (unsigned)func); func(); } } static void call_constructors(soinfo *si) { /* TODO: THE ORIGINAL CODE SEEMED TO CALL THE INIT FUNCS IN THE WRONG ORDER. * Old order: init, init_array, preinit_array.. * Correct order: preinit_array, init, init_array. * Verify WHY. */ if (si->flags & FLAG_EXE) { TRACE("[ %5d Calling preinit_array @ 0x%08x [%d] for '%s' ]\n", pid, (unsigned)si->preinit_array, si->preinit_array_count, si->name); call_array(si->preinit_array, si->preinit_array_count); TRACE("[ %5d Done calling preinit_array for '%s' ]\n", pid, si->name); } else { if (si->preinit_array) { ERROR("%5d Shared library '%s' has a preinit_array table @ 0x%08x." " This is INVALID.\n", pid, si->name, (unsigned)si->preinit_array); } } // If we have an init section, then we should call it now, to make sure // that all the funcs in the .ctors section get run. // Note: For ARM, we shouldn't have a .ctor section (should be empty) // when we have an (pre)init_array section, but let's be compatible with // old (non-eabi) binaries and try the _init (DT_INIT) anyway. if (si->init_func) { TRACE("[ %5d Calling init_func @ 0x%08x for '%s' ]\n", pid, (unsigned)si->init_func, si->name); si->init_func(); TRACE("[ %5d Done calling init_func for '%s' ]\n", pid, si->name); } if (si->init_array) { TRACE("[ %5d Calling init_array @ 0x%08x [%d] for '%s' ]\n", pid, (unsigned)si->init_array, si->init_array_count, si->name); call_array(si->init_array, si->init_array_count); TRACE("[ %5d Done calling init_array for '%s' ]\n", pid, si->name); } } static void call_destructors(soinfo *si) { if (si->fini_array) { TRACE("[ %5d Calling fini_array @ 0x%08x [%d] for '%s' ]\n", pid, (unsigned)si->fini_array, si->fini_array_count, si->name); call_array(si->fini_array, si->fini_array_count); TRACE("[ %5d Done calling fini_array for '%s' ]\n", pid, si->name); } // If we have an fini section, then we should call it now, to make sure // that all the funcs in the .dtors section get run. // Note: For ARM, we shouldn't have a .dtor section (should be empty) // when we have an fini_array section, but let's be compatible with // old (non-eabi) binaries and try the _fini (DT_FINI) anyway. if (si->fini_func) { TRACE("[ %5d Calling fini_func @ 0x%08x for '%s' ]\n", pid, (unsigned)si->fini_func, si->name); si->fini_func(); TRACE("[ %5d Done calling fini_func for '%s' ]\n", pid, si->name); } } /* Force any of the closed stdin, stdout and stderr to be associated with /dev/null. */ static int nullify_closed_stdio (void) { int dev_null, i, status; int return_value = 0; dev_null = open("/dev/null", O_RDWR); if (dev_null < 0) { ERROR("Cannot open /dev/null.\n"); return -1; } TRACE("[ %5d Opened /dev/null file-descriptor=%d]\n", pid, dev_null); /* If any of the stdio file descriptors is valid and not associated with /dev/null, dup /dev/null to it. */ for (i = 0; i < 3; i++) { /* If it is /dev/null already, we are done. */ if (i == dev_null) continue; TRACE("[ %5d Nullifying stdio file descriptor %d]\n", pid, i); /* The man page of fcntl does not say that fcntl(..,F_GETFL) can be interrupted but we do this just to be safe. */ do { status = fcntl(i, F_GETFL); } while (status < 0 && errno == EINTR); /* If file is openned, we are good. */ if (status >= 0) continue; /* The only error we allow is that the file descriptor does not exist, in which case we dup /dev/null to it. */ if (errno != EBADF) { ERROR("nullify_stdio: unhandled error %s\n", strerror(errno)); return_value = -1; continue; } /* Try dupping /dev/null to this stdio file descriptor and repeat if there is a signal. Note that any errors in closing the stdio descriptor are lost. */ do { status = dup2(dev_null, i); } while (status < 0 && errno == EINTR); if (status < 0) { ERROR("nullify_stdio: dup2 error %s\n", strerror(errno)); return_value = -1; continue; } } /* If /dev/null is not one of the stdio file descriptors, close it. */ if (dev_null > 2) { TRACE("[ %5d Closing /dev/null file-descriptor=%d]\n", pid, dev_null); do { status = close(dev_null); } while (status < 0 && errno == EINTR); if (status < 0) { ERROR("nullify_stdio: close error %s\n", strerror(errno)); return_value = -1; } } return return_value; } static int link_image(soinfo *si, unsigned wr_offset) { unsigned *d; Elf32_Phdr *phdr = si->phdr; int phnum = si->phnum; INFO("[ %5d linking %s ]\n", pid, si->name); DEBUG("%5d si->base = 0x%08x si->flags = 0x%08x\n", pid, si->base, si->flags); if (si->flags & FLAG_EXE) { /* Locate the needed program segments (DYNAMIC/ARM_EXIDX) for * linkage info if this is the executable. If this was a * dynamic lib, that would have been done at load time. * * TODO: It's unfortunate that small pieces of this are * repeated from the load_library routine. Refactor this just * slightly to reuse these bits. */ si->size = 0; for(; phnum > 0; --phnum, ++phdr) { #ifdef ANDROID_ARM_LINKER if(phdr->p_type == PT_ARM_EXIDX) { /* exidx entries (used for stack unwinding) are 8 bytes each. */ si->ARM_exidx = (unsigned *)phdr->p_vaddr; si->ARM_exidx_count = phdr->p_memsz / 8; } #endif if (phdr->p_type == PT_LOAD) { /* For the executable, we use the si->size field only in dl_unwind_find_exidx(), so the meaning of si->size is not the size of the executable; it is the last virtual address of the loadable part of the executable; since si->base == 0 for an executable, we use the range [0, si->size) to determine whether a PC value falls within the executable section. Of course, if a value is below phdr->p_vaddr, it's not in the executable section, but a) we shouldn't be asking for such a value anyway, and b) if we have to provide an EXIDX for such a value, then the executable's EXIDX is probably the better choice. */ DEBUG_DUMP_PHDR(phdr, "PT_LOAD", pid); if (phdr->p_vaddr + phdr->p_memsz > si->size) si->size = phdr->p_vaddr + phdr->p_memsz; /* try to remember what range of addresses should be write * protected */ if (!(phdr->p_flags & PF_W)) { unsigned _end; if (phdr->p_vaddr < si->wrprotect_start) si->wrprotect_start = phdr->p_vaddr; _end = (((phdr->p_vaddr + phdr->p_memsz + PAGE_SIZE - 1) & (~PAGE_MASK))); if (_end > si->wrprotect_end) si->wrprotect_end = _end; } } else if (phdr->p_type == PT_DYNAMIC) { if (si->dynamic != (unsigned *)-1) { ERROR("%5d multiple PT_DYNAMIC segments found in '%s'. " "Segment at 0x%08x, previously one found at 0x%08x\n", pid, si->name, si->base + phdr->p_vaddr, (unsigned)si->dynamic); goto fail; } DEBUG_DUMP_PHDR(phdr, "PT_DYNAMIC", pid); si->dynamic = (unsigned *) (si->base + phdr->p_vaddr); } } } if (si->dynamic == (unsigned *)-1) { ERROR("%5d missing PT_DYNAMIC?!\n", pid); goto fail; } DEBUG("%5d dynamic = %p\n", pid, si->dynamic); /* extract useful information from dynamic section */ for(d = si->dynamic; *d; d++){ DEBUG("%5d d = %p, d[0] = 0x%08x d[1] = 0x%08x\n", pid, d, d[0], d[1]); switch(*d++){ case DT_HASH: si->nbucket = ((unsigned *) (si->base + *d))[0]; si->nchain = ((unsigned *) (si->base + *d))[1]; si->bucket = (unsigned *) (si->base + *d + 8); si->chain = (unsigned *) (si->base + *d + 8 + si->nbucket * 4); break; case DT_STRTAB: si->strtab = (const char *) (si->base + *d); break; case DT_SYMTAB: si->symtab = (Elf32_Sym *) (si->base + *d); break; case DT_PLTREL: if(*d != DT_REL) { ERROR("DT_RELA not supported\n"); goto fail; } break; case DT_JMPREL: si->plt_rel = (Elf32_Rel*) (si->base + *d); break; case DT_PLTRELSZ: si->plt_rel_count = *d / 8; break; case DT_REL: si->rel = (Elf32_Rel*) (si->base + *d); break; case DT_RELSZ: si->rel_count = *d / 8; break; case DT_PLTGOT: /* Save this in case we decide to do lazy binding. We don't yet. */ si->plt_got = (unsigned *)(si->base + *d); break; case DT_DEBUG: // Set the DT_DEBUG entry to the addres of _r_debug for GDB *d = (int) &_r_debug; break; case DT_RELA: ERROR("%5d DT_RELA not supported\n", pid); goto fail; case DT_INIT: si->init_func = (void (*)(void))(si->base + *d); DEBUG("%5d %s constructors (init func) found at %p\n", pid, si->name, si->init_func); break; case DT_FINI: si->fini_func = (void (*)(void))(si->base + *d); DEBUG("%5d %s destructors (fini func) found at %p\n", pid, si->name, si->fini_func); break; case DT_INIT_ARRAY: si->init_array = (unsigned *)(si->base + *d); DEBUG("%5d %s constructors (init_array) found at %p\n", pid, si->name, si->init_array); break; case DT_INIT_ARRAYSZ: si->init_array_count = ((unsigned)*d) / sizeof(Elf32_Addr); break; case DT_FINI_ARRAY: si->fini_array = (unsigned *)(si->base + *d); DEBUG("%5d %s destructors (fini_array) found at %p\n", pid, si->name, si->fini_array); break; case DT_FINI_ARRAYSZ: si->fini_array_count = ((unsigned)*d) / sizeof(Elf32_Addr); break; case DT_PREINIT_ARRAY: si->preinit_array = (unsigned *)(si->base + *d); DEBUG("%5d %s constructors (preinit_array) found at %p\n", pid, si->name, si->preinit_array); break; case DT_PREINIT_ARRAYSZ: si->preinit_array_count = ((unsigned)*d) / sizeof(Elf32_Addr); break; case DT_TEXTREL: /* TODO: make use of this. */ /* this means that we might have to write into where the text * segment was loaded during relocation... Do something with * it. */ DEBUG("%5d Text segment should be writable during relocation.\n", pid); break; } } DEBUG("%5d si->base = 0x%08x, si->strtab = %p, si->symtab = %p\n", pid, si->base, si->strtab, si->symtab); if((si->strtab == 0) || (si->symtab == 0)) { ERROR("%5d missing essential tables\n", pid); goto fail; } for(d = si->dynamic; *d; d += 2) { if(d[0] == DT_NEEDED){ DEBUG("%5d %s needs %s\n", pid, si->name, si->strtab + d[1]); soinfo *lsi = find_library(si->strtab + d[1]); if(lsi == 0) { ERROR("%5d could not load '%s'\n", pid, si->strtab + d[1]); goto fail; } lsi->refcount++; } } if(si->plt_rel) { DEBUG("[ %5d relocating %s plt ]\n", pid, si->name ); if(reloc_library(si, si->plt_rel, si->plt_rel_count)) goto fail; } if(si->rel) { DEBUG("[ %5d relocating %s ]\n", pid, si->name ); if(reloc_library(si, si->rel, si->rel_count)) goto fail; } si->flags |= FLAG_LINKED; DEBUG("[ %5d finished linking %s ]\n", pid, si->name); #if 0 /* This is the way that the old dynamic linker did protection of * non-writable areas. It would scan section headers and find where * .text ended (rather where .data/.bss began) and assume that this is * the upper range of the non-writable area. This is too coarse, * and is kept here for reference until we fully move away from single * segment elf objects. See the code in get_wr_offset (also #if'd 0) * that made this possible. */ if(wr_offset < 0xffffffff){ mprotect((void*) si->base, wr_offset, PROT_READ | PROT_EXEC); } #else /* TODO: Verify that this does the right thing in all cases, as it * presently probably does not. It is possible that an ELF image will * come with multiple read-only segments. What we ought to do is scan * the program headers again and mprotect all the read-only segments. * To prevent re-scanning the program header, we would have to build a * list of loadable segments in si, and then scan that instead. */ if (si->wrprotect_start != 0xffffffff && si->wrprotect_end != 0) { mprotect((void *)si->wrprotect_start, si->wrprotect_end - si->wrprotect_start, PROT_READ | PROT_EXEC); } #endif /* If this is a SETUID programme, dup /dev/null to openned stdin, stdout and stderr to close a security hole described in: ftp://ftp.freebsd.org/pub/FreeBSD/CERT/advisories/FreeBSD-SA-02:23.stdio.asc */ if (getuid() != geteuid()) nullify_closed_stdio (); call_constructors(si); notify_gdb_of_load(si); return 0; fail: ERROR("failed to link %s\n", si->name); si->flags |= FLAG_ERROR; return -1; } int main(int argc, char **argv) { return 0; } #define ANDROID_TLS_SLOTS BIONIC_TLS_SLOTS static void * __tls_area[ANDROID_TLS_SLOTS]; unsigned __linker_init(unsigned **elfdata) { static soinfo linker_soinfo; int argc = (int) *elfdata; char **argv = (char**) (elfdata + 1); unsigned *vecs = (unsigned*) (argv + argc + 1); soinfo *si; struct link_map * map; pid = getpid(); #if TIMING struct timeval t0, t1; gettimeofday(&t0, 0); #endif __set_tls(__tls_area); ((unsigned *)__get_tls())[TLS_SLOT_THREAD_ID] = gettid(); debugger_init(); /* skip past the environment */ while(vecs[0] != 0) { if(!strncmp((char*) vecs[0], "DEBUG=", 6)) { debug_verbosity = atoi(((char*) vecs[0]) + 6); } vecs++; } vecs++; INFO("[ android linker & debugger ]\n"); DEBUG("%5d elfdata @ 0x%08x\n", pid, (unsigned)elfdata); si = alloc_info(argv[0]); if(si == 0) { exit(-1); } /* bootstrap the link map, the main exe always needs to be first */ si->flags |= FLAG_EXE; map = &(si->linkmap); map->l_addr = 0; map->l_name = argv[0]; map->l_prev = NULL; map->l_next = NULL; _r_debug.r_map = map; r_debug_tail = map; /* gdb expects the linker to be in the debug shared object list, * and we need to make sure that the reported load address is zero. * Without this, gdb gets the wrong idea of where rtld_db_dlactivity() * is. Don't use alloc_info(), because the linker shouldn't * be on the soinfo list. */ strcpy((char*) linker_soinfo.name, "/system/bin/linker"); linker_soinfo.flags = 0; linker_soinfo.base = 0; // This is the important part; must be zero. insert_soinfo_into_debug_map(&linker_soinfo); /* extract information passed from the kernel */ while(vecs[0] != 0){ switch(vecs[0]){ case AT_PHDR: si->phdr = (Elf32_Phdr*) vecs[1]; break; case AT_PHNUM: si->phnum = (int) vecs[1]; break; case AT_ENTRY: si->entry = vecs[1]; break; } vecs += 2; } si->base = 0; si->dynamic = (unsigned *)-1; si->wrprotect_start = 0xffffffff; si->wrprotect_end = 0; if(link_image(si, 0)){ ERROR("CANNOT LINK EXECUTABLE '%s'\n", argv[0]); exit(-1); } #if TIMING gettimeofday(&t1,NULL); PRINT("LINKER TIME: %s: %d microseconds\n", argv[0], (int) ( (((long long)t1.tv_sec * 1000000LL) + (long long)t1.tv_usec) - (((long long)t0.tv_sec * 1000000LL) + (long long)t0.tv_usec) )); #endif #if STATS PRINT("RELO STATS: %s: %d abs, %d rel, %d copy, %d symbol\n", argv[0], linker_stats.reloc[RELOC_ABSOLUTE], linker_stats.reloc[RELOC_RELATIVE], linker_stats.reloc[RELOC_COPY], linker_stats.reloc[RELOC_SYMBOL]); #endif #if COUNT_PAGES { unsigned n; unsigned i; unsigned count = 0; for(n = 0; n < 4096; n++){ if(bitmask[n]){ unsigned x = bitmask[n]; for(i = 0; i < 8; i++){ if(x & 1) count++; x >>= 1; } } } PRINT("PAGES MODIFIED: %s: %d (%dKB)\n", argv[0], count, count * 4); } #endif #if TIMING || STATS || COUNT_PAGES fflush(stdout); #endif TRACE("[ %5d Ready to execute '%s' @ 0x%08x ]\n", pid, si->name, si->entry); return si->entry; }