/* +----------------------------------------------------------------------+ | Zend OPcache | +----------------------------------------------------------------------+ | Copyright (c) The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 3.01 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.php.net/license/3_01.txt | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Authors: Andi Gutmans | | Zeev Suraski | | Stanislav Malyshev | | Dmitry Stogov | +----------------------------------------------------------------------+ */ #include #include "ZendAccelerator.h" #include "zend_shared_alloc.h" #ifdef HAVE_UNISTD_H # include #endif #include #ifndef ZEND_WIN32 # include # include # include # include #endif #ifdef HAVE_MPROTECT # include "sys/mman.h" #endif #define SEM_FILENAME_PREFIX ".ZendSem." #define S_H(s) g_shared_alloc_handler->s /* True globals */ /* old/new mapping. We can use true global even for ZTS because its usage is wrapped with exclusive lock anyway */ static const zend_shared_memory_handlers *g_shared_alloc_handler = NULL; static const char *g_shared_model; /* pointer to globals allocated in SHM and shared across processes */ zend_smm_shared_globals *smm_shared_globals; #ifndef ZEND_WIN32 #ifdef ZTS static MUTEX_T zts_lock; #endif int lock_file; static char lockfile_name[MAXPATHLEN]; #endif static const zend_shared_memory_handler_entry handler_table[] = { #ifdef USE_MMAP { "mmap", &zend_alloc_mmap_handlers }, #endif #ifdef USE_SHM { "shm", &zend_alloc_shm_handlers }, #endif #ifdef USE_SHM_OPEN { "posix", &zend_alloc_posix_handlers }, #endif #ifdef ZEND_WIN32 { "win32", &zend_alloc_win32_handlers }, #endif { NULL, NULL} }; #ifndef ZEND_WIN32 void zend_shared_alloc_create_lock(char *lockfile_path) { int val; #ifdef ZTS zts_lock = tsrm_mutex_alloc(); #endif snprintf(lockfile_name, sizeof(lockfile_name), "%s/%sXXXXXX", lockfile_path, SEM_FILENAME_PREFIX); lock_file = mkstemp(lockfile_name); fchmod(lock_file, 0666); if (lock_file == -1) { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Unable to create lock file: %s (%d)", strerror(errno), errno); } val = fcntl(lock_file, F_GETFD, 0); val |= FD_CLOEXEC; fcntl(lock_file, F_SETFD, val); unlink(lockfile_name); } #endif static void no_memory_bailout(size_t allocate_size, char *error) { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Unable to allocate shared memory segment of %zu bytes: %s: %s (%d)", allocate_size, error?error:"unknown", strerror(errno), errno ); } static void copy_shared_segments(void *to, void *from, int count, int size) { zend_shared_segment **shared_segments_v = (zend_shared_segment **)to; void *shared_segments_to_p = ((char *)to + count*(sizeof(void *))); void *shared_segments_from_p = from; int i; for (i = 0; i < count; i++) { shared_segments_v[i] = shared_segments_to_p; memcpy(shared_segments_to_p, shared_segments_from_p, size); shared_segments_to_p = ((char *)shared_segments_to_p + size); shared_segments_from_p = ((char *)shared_segments_from_p + size); } } static int zend_shared_alloc_try(const zend_shared_memory_handler_entry *he, size_t requested_size, zend_shared_segment ***shared_segments_p, int *shared_segments_count, char **error_in) { int res; g_shared_alloc_handler = he->handler; g_shared_model = he->name; ZSMMG(shared_segments) = NULL; ZSMMG(shared_segments_count) = 0; res = S_H(create_segments)(requested_size, shared_segments_p, shared_segments_count, error_in); if (res) { /* this model works! */ return res; } if (*shared_segments_p) { int i; /* cleanup */ for (i = 0; i < *shared_segments_count; i++) { if ((*shared_segments_p)[i]->p && (*shared_segments_p)[i]->p != (void *)-1) { S_H(detach_segment)((*shared_segments_p)[i]); } } free(*shared_segments_p); *shared_segments_p = NULL; } g_shared_alloc_handler = NULL; return ALLOC_FAILURE; } int zend_shared_alloc_startup(size_t requested_size, size_t reserved_size) { zend_shared_segment **tmp_shared_segments; size_t shared_segments_array_size; zend_smm_shared_globals tmp_shared_globals, *p_tmp_shared_globals; char *error_in = NULL; const zend_shared_memory_handler_entry *he; int res = ALLOC_FAILURE; int i; /* shared_free must be valid before we call zend_shared_alloc() * - make it temporarily point to a local variable */ smm_shared_globals = &tmp_shared_globals; ZSMMG(shared_free) = requested_size - reserved_size; /* goes to tmp_shared_globals.shared_free */ #ifndef ZEND_WIN32 zend_shared_alloc_create_lock(ZCG(accel_directives).lockfile_path); #else zend_shared_alloc_create_lock(); #endif if (ZCG(accel_directives).memory_model && ZCG(accel_directives).memory_model[0]) { char *model = ZCG(accel_directives).memory_model; /* "cgi" is really "shm"... */ if (strncmp(ZCG(accel_directives).memory_model, "cgi", sizeof("cgi")) == 0) { model = "shm"; } for (he = handler_table; he->name; he++) { if (strcmp(model, he->name) == 0) { res = zend_shared_alloc_try(he, requested_size, &ZSMMG(shared_segments), &ZSMMG(shared_segments_count), &error_in); if (res) { /* this model works! */ } break; } } } if (res == FAILED_REATTACHED) { smm_shared_globals = NULL; return res; } #if ENABLE_FILE_CACHE_FALLBACK if (ALLOC_FALLBACK == res) { return ALLOC_FALLBACK; } #endif if (!g_shared_alloc_handler) { /* try memory handlers in order */ for (he = handler_table; he->name; he++) { res = zend_shared_alloc_try(he, requested_size, &ZSMMG(shared_segments), &ZSMMG(shared_segments_count), &error_in); if (res) { /* this model works! */ break; } } } if (!g_shared_alloc_handler) { no_memory_bailout(requested_size, error_in); return ALLOC_FAILURE; } if (res == SUCCESSFULLY_REATTACHED) { return res; } #if ENABLE_FILE_CACHE_FALLBACK if (ALLOC_FALLBACK == res) { return ALLOC_FALLBACK; } #endif for (i = 0; i < ZSMMG(shared_segments_count); i++) { ZSMMG(shared_segments)[i]->end = ZSMMG(shared_segments)[i]->size; } shared_segments_array_size = ZSMMG(shared_segments_count) * S_H(segment_type_size)(); /* move shared_segments and shared_free to shared memory */ ZCG(locked) = 1; /* no need to perform a real lock at this point */ p_tmp_shared_globals = (zend_smm_shared_globals *) zend_shared_alloc(sizeof(zend_smm_shared_globals)); if (!p_tmp_shared_globals) { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Insufficient shared memory!"); return ALLOC_FAILURE; } memset(p_tmp_shared_globals, 0, sizeof(zend_smm_shared_globals)); tmp_shared_segments = zend_shared_alloc(shared_segments_array_size + ZSMMG(shared_segments_count) * sizeof(void *)); if (!tmp_shared_segments) { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Insufficient shared memory!"); return ALLOC_FAILURE; } copy_shared_segments(tmp_shared_segments, ZSMMG(shared_segments)[0], ZSMMG(shared_segments_count), S_H(segment_type_size)()); *p_tmp_shared_globals = tmp_shared_globals; smm_shared_globals = p_tmp_shared_globals; free(ZSMMG(shared_segments)); ZSMMG(shared_segments) = tmp_shared_segments; ZSMMG(shared_memory_state).positions = (int *)zend_shared_alloc(sizeof(int) * ZSMMG(shared_segments_count)); if (!ZSMMG(shared_memory_state).positions) { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Insufficient shared memory!"); return ALLOC_FAILURE; } if (reserved_size) { i = ZSMMG(shared_segments_count) - 1; if (ZSMMG(shared_segments)[i]->size - ZSMMG(shared_segments)[i]->pos >= reserved_size) { ZSMMG(shared_segments)[i]->end = ZSMMG(shared_segments)[i]->size - reserved_size; ZSMMG(reserved) = (char*)ZSMMG(shared_segments)[i]->p + ZSMMG(shared_segments)[i]->end; ZSMMG(reserved_size) = reserved_size; } else { zend_accel_error_noreturn(ACCEL_LOG_FATAL, "Insufficient shared memory!"); return ALLOC_FAILURE; } } ZCG(locked) = 0; return res; } void zend_shared_alloc_shutdown(void) { zend_shared_segment **tmp_shared_segments; zend_shared_segment *shared_segments_buf[16]; size_t shared_segments_array_size; zend_smm_shared_globals tmp_shared_globals; int i; tmp_shared_globals = *smm_shared_globals; smm_shared_globals = &tmp_shared_globals; shared_segments_array_size = ZSMMG(shared_segments_count) * (S_H(segment_type_size)() + sizeof(void *)); if (shared_segments_array_size > 16) { tmp_shared_segments = malloc(shared_segments_array_size); } else { tmp_shared_segments = shared_segments_buf; } copy_shared_segments(tmp_shared_segments, ZSMMG(shared_segments)[0], ZSMMG(shared_segments_count), S_H(segment_type_size)()); ZSMMG(shared_segments) = tmp_shared_segments; for (i = 0; i < ZSMMG(shared_segments_count); i++) { S_H(detach_segment)(ZSMMG(shared_segments)[i]); } if (shared_segments_array_size > 16) { free(ZSMMG(shared_segments)); } ZSMMG(shared_segments) = NULL; g_shared_alloc_handler = NULL; #ifndef ZEND_WIN32 close(lock_file); # ifdef ZTS tsrm_mutex_free(zts_lock); # endif #endif } static size_t zend_shared_alloc_get_largest_free_block(void) { int i; size_t largest_block_size = 0; for (i = 0; i < ZSMMG(shared_segments_count); i++) { size_t block_size = ZSMMG(shared_segments)[i]->end - ZSMMG(shared_segments)[i]->pos; if (block_size>largest_block_size) { largest_block_size = block_size; } } return largest_block_size; } #define MIN_FREE_MEMORY 64*1024 #define SHARED_ALLOC_FAILED() do { \ zend_accel_error(ACCEL_LOG_WARNING, "Not enough free shared space to allocate "ZEND_LONG_FMT" bytes ("ZEND_LONG_FMT" bytes free)", (zend_long)size, (zend_long)ZSMMG(shared_free)); \ if (zend_shared_alloc_get_largest_free_block() < MIN_FREE_MEMORY) { \ ZSMMG(memory_exhausted) = 1; \ } \ } while (0) void *zend_shared_alloc(size_t size) { int i; unsigned int block_size = ZEND_ALIGNED_SIZE(size); #if 1 if (!ZCG(locked)) { zend_accel_error_noreturn(ACCEL_LOG_ERROR, "Shared memory lock not obtained"); } #endif if (block_size > ZSMMG(shared_free)) { /* No hope to find a big-enough block */ SHARED_ALLOC_FAILED(); return NULL; } for (i = 0; i < ZSMMG(shared_segments_count); i++) { if (ZSMMG(shared_segments)[i]->end - ZSMMG(shared_segments)[i]->pos >= block_size) { /* found a valid block */ void *retval = (void *) (((char *) ZSMMG(shared_segments)[i]->p) + ZSMMG(shared_segments)[i]->pos); ZSMMG(shared_segments)[i]->pos += block_size; ZSMMG(shared_free) -= block_size; ZEND_ASSERT(((zend_uintptr_t)retval & 0x7) == 0); /* should be 8 byte aligned */ return retval; } } SHARED_ALLOC_FAILED(); return NULL; } int zend_shared_memdup_size(void *source, size_t size) { void *old_p; zend_ulong key = (zend_ulong)source; key = (key >> 3) | (key << ((sizeof(key) * 8) - 3)); /* key = _rotr(key, 3);*/ if ((old_p = zend_hash_index_find_ptr(&ZCG(xlat_table), key)) != NULL) { /* we already duplicated this pointer */ return 0; } zend_hash_index_add_new_ptr(&ZCG(xlat_table), key, source); return ZEND_ALIGNED_SIZE(size); } static zend_always_inline void *_zend_shared_memdup(void *source, size_t size, bool get_xlat, bool set_xlat, bool free_source) { void *old_p, *retval; zend_ulong key; if (get_xlat) { key = (zend_ulong)source; key = (key >> 3) | (key << ((sizeof(key) * 8) - 3)); /* key = _rotr(key, 3);*/ if ((old_p = zend_hash_index_find_ptr(&ZCG(xlat_table), key)) != NULL) { /* we already duplicated this pointer */ return old_p; } } retval = ZCG(mem); ZCG(mem) = (void*)(((char*)ZCG(mem)) + ZEND_ALIGNED_SIZE(size)); memcpy(retval, source, size); if (set_xlat) { if (!get_xlat) { key = (zend_ulong)source; key = (key >> 3) | (key << ((sizeof(key) * 8) - 3)); /* key = _rotr(key, 3);*/ } zend_hash_index_add_new_ptr(&ZCG(xlat_table), key, retval); } if (free_source) { efree(source); } return retval; } void *zend_shared_memdup_get_put_free(void *source, size_t size) { return _zend_shared_memdup(source, size, 1, 1, 1); } void *zend_shared_memdup_put_free(void *source, size_t size) { return _zend_shared_memdup(source, size, 0, 1, 1); } void *zend_shared_memdup_free(void *source, size_t size) { return _zend_shared_memdup(source, size, 0, 0, 1); } void *zend_shared_memdup_get_put(void *source, size_t size) { return _zend_shared_memdup(source, size, 1, 1, 0); } void *zend_shared_memdup_put(void *source, size_t size) { return _zend_shared_memdup(source, size, 0, 1, 0); } void *zend_shared_memdup(void *source, size_t size) { return _zend_shared_memdup(source, size, 0, 0, 0); } void zend_shared_alloc_safe_unlock(void) { if (ZCG(locked)) { zend_shared_alloc_unlock(); } } void zend_shared_alloc_lock(void) { #ifndef ZEND_WIN32 struct flock mem_write_lock; mem_write_lock.l_type = F_WRLCK; mem_write_lock.l_whence = SEEK_SET; mem_write_lock.l_start = 0; mem_write_lock.l_len = 1; #ifdef ZTS tsrm_mutex_lock(zts_lock); #endif #if 0 /* this will happen once per process, and will un-globalize mem_write_lock */ if (mem_write_lock.l_pid == -1) { mem_write_lock.l_pid = getpid(); } #endif while (1) { if (fcntl(lock_file, F_SETLKW, &mem_write_lock) == -1) { if (errno == EINTR) { continue; } zend_accel_error_noreturn(ACCEL_LOG_ERROR, "Cannot create lock - %s (%d)", strerror(errno), errno); } break; } #else zend_shared_alloc_lock_win32(); #endif ZCG(locked) = 1; } void zend_shared_alloc_unlock(void) { #ifndef ZEND_WIN32 struct flock mem_write_unlock; mem_write_unlock.l_type = F_UNLCK; mem_write_unlock.l_whence = SEEK_SET; mem_write_unlock.l_start = 0; mem_write_unlock.l_len = 1; #endif ZCG(locked) = 0; #ifndef ZEND_WIN32 if (fcntl(lock_file, F_SETLK, &mem_write_unlock) == -1) { zend_accel_error_noreturn(ACCEL_LOG_ERROR, "Cannot remove lock - %s (%d)", strerror(errno), errno); } #ifdef ZTS tsrm_mutex_unlock(zts_lock); #endif #else zend_shared_alloc_unlock_win32(); #endif } void zend_shared_alloc_init_xlat_table(void) { /* Prepare translation table */ zend_hash_init(&ZCG(xlat_table), 128, NULL, NULL, 0); } void zend_shared_alloc_destroy_xlat_table(void) { /* Destroy translation table */ zend_hash_destroy(&ZCG(xlat_table)); } void zend_shared_alloc_clear_xlat_table(void) { zend_hash_clean(&ZCG(xlat_table)); } uint32_t zend_shared_alloc_checkpoint_xlat_table(void) { return ZCG(xlat_table).nNumUsed; } void zend_shared_alloc_restore_xlat_table(uint32_t checkpoint) { zend_hash_discard(&ZCG(xlat_table), checkpoint); } void zend_shared_alloc_register_xlat_entry(const void *old, const void *new) { zend_ulong key = (zend_ulong)old; key = (key >> 3) | (key << ((sizeof(key) * 8) - 3)); /* key = _rotr(key, 3);*/ zend_hash_index_add_new_ptr(&ZCG(xlat_table), key, (void*)new); } void *zend_shared_alloc_get_xlat_entry(const void *old) { void *retval; zend_ulong key = (zend_ulong)old; key = (key >> 3) | (key << ((sizeof(key) * 8) - 3)); /* key = _rotr(key, 3);*/ if ((retval = zend_hash_index_find_ptr(&ZCG(xlat_table), key)) == NULL) { return NULL; } return retval; } size_t zend_shared_alloc_get_free_memory(void) { return ZSMMG(shared_free); } void zend_shared_alloc_save_state(void) { int i; for (i = 0; i < ZSMMG(shared_segments_count); i++) { ZSMMG(shared_memory_state).positions[i] = ZSMMG(shared_segments)[i]->pos; } ZSMMG(shared_memory_state).shared_free = ZSMMG(shared_free); } void zend_shared_alloc_restore_state(void) { int i; for (i = 0; i < ZSMMG(shared_segments_count); i++) { ZSMMG(shared_segments)[i]->pos = ZSMMG(shared_memory_state).positions[i]; } ZSMMG(shared_free) = ZSMMG(shared_memory_state).shared_free; ZSMMG(memory_exhausted) = 0; ZSMMG(wasted_shared_memory) = 0; } const char *zend_accel_get_shared_model(void) { return g_shared_model; } void zend_accel_shared_protect(int mode) { #ifdef HAVE_MPROTECT int i; if (!smm_shared_globals) { return; } if (mode) { mode = PROT_READ; } else { mode = PROT_READ|PROT_WRITE; } for (i = 0; i < ZSMMG(shared_segments_count); i++) { mprotect(ZSMMG(shared_segments)[i]->p, ZSMMG(shared_segments)[i]->end, mode); } #elif defined(ZEND_WIN32) int i; if (!smm_shared_globals) { return; } if (mode) { mode = PAGE_READONLY; } else { mode = PAGE_READWRITE; } for (i = 0; i < ZSMMG(shared_segments_count); i++) { DWORD oldProtect; if (!VirtualProtect(ZSMMG(shared_segments)[i]->p, ZSMMG(shared_segments)[i]->end, mode, &oldProtect)) { zend_accel_error_noreturn(ACCEL_LOG_ERROR, "Failed to protect memory"); } } #endif } int zend_accel_in_shm(void *ptr) { int i; if (!smm_shared_globals) { return 0; } for (i = 0; i < ZSMMG(shared_segments_count); i++) { if ((char*)ptr >= (char*)ZSMMG(shared_segments)[i]->p && (char*)ptr < (char*)ZSMMG(shared_segments)[i]->p + ZSMMG(shared_segments)[i]->end) { return 1; } } return 0; }