/* * Copyright (c) 1999 Apple Computer, Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * The contents of this file constitute Original Code as defined in and * are subject to the Apple Public Source License Version 1.1 (the * "License"). You may not use this file except in compliance with the * License. Please obtain a copy of the License at * http://www.apple.com/publicsource and read it before using this file. * * This Original Code and all software distributed under the License are * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the * License for the specific language governing rights and limitations * under the License. * * @APPLE_LICENSE_HEADER_END@ */ #define __POSIX_LIB__ #import #import #import #import #import #import // for spin lock #import #include #import "scalable_malloc.h" #import "stack_logging.h" #define USE_SLEEP_RATHER_THAN_ABORT 0 #define MAX_ALLOCATION 0xc0000000 // beyond this, assume a programming error #define INITIAL_ZONES 8 // After this number, we reallocate for new zones typedef void (malloc_logger_t)(unsigned type, unsigned arg1, unsigned arg2, unsigned arg3, unsigned result, unsigned num_hot_frames_to_skip); static pthread_lock_t _malloc_lock; static malloc_zone_t *initial_malloc_zones[INITIAL_ZONES] = {0}; /* The following variables are exported for the benefit of performance tools */ unsigned malloc_num_zones = 0; malloc_zone_t **malloc_zones = initial_malloc_zones; malloc_logger_t *malloc_logger = NULL; unsigned malloc_debug_flags = 0; unsigned malloc_check_start = 0; // 0 means don't check unsigned malloc_check_counter = 0; unsigned malloc_check_each = 1000; #define MALLOC_LOCK() LOCK(_malloc_lock) #define MALLOC_UNLOCK() UNLOCK(_malloc_lock) #define MALLOC_LOG_TYPE_ALLOCATE stack_logging_type_alloc #define MALLOC_LOG_TYPE_DEALLOCATE stack_logging_type_dealloc #define MALLOC_LOG_TYPE_HAS_ZONE stack_logging_flag_zone #define MALLOC_LOG_TYPE_CLEARED stack_logging_flag_cleared /********* Utilities ************/ static inline malloc_zone_t *find_registered_zone(const void *ptr, size_t *returned_size) { // locates the proper zone // if zone found fills returnedSize; else returns NULL // See comment in malloc_zone_register() about clients non locking to call this function // Speed is critical for this function unsigned index = malloc_num_zones; malloc_zone_t **zones = malloc_zones; while (index--) { malloc_zone_t *zone = *zones++; size_t size; size = zone->size(zone, ptr); if (size) { if (returned_size) *returned_size = size; return zone; } } return NULL; } /********* Creation and destruction ************/ static void _malloc_initialize(void) { // guaranteed to be called only once (void)malloc_create_zone(0, 0); malloc_set_zone_name(malloc_zones[0], "DefaultMallocZone"); LOCK_INIT(_malloc_lock); // malloc_printf("Malloc: %d registered zones\n", malloc_num_zones); // malloc_printf("malloc: malloc_zones is at 0x%x; malloc_num_zones is at 0x%x\n", (unsigned)&malloc_zones, (unsigned)&malloc_num_zones); } static inline malloc_zone_t *inline_malloc_default_zone(void) { if (!malloc_num_zones) _malloc_initialize(); // malloc_printf("In inline_malloc_default_zone with %d %d\n", malloc_num_zones, malloc_has_debug_zone); return malloc_zones[0]; } malloc_zone_t *malloc_default_zone(void) { return inline_malloc_default_zone(); } static void set_flags_from_environment(void) { const char *flag; if (getenv("MallocGuardEdges")) { malloc_debug_flags = SCALABLE_MALLOC_ADD_GUARD_PAGES; malloc_printf("malloc[%d]: protecting edges\n", getpid()); if (getenv("MallocDoNotProtectPrelude")) { malloc_debug_flags |= SCALABLE_MALLOC_DONT_PROTECT_PRELUDE; malloc_printf("malloc[%d]: ... but not protecting prelude guard page\n", getpid()); } if (getenv("MallocDoNotProtectPostlude")) { malloc_debug_flags |= SCALABLE_MALLOC_DONT_PROTECT_POSTLUDE; malloc_printf("malloc[%d]: ... but not protecting postlude guard page\n", getpid()); } } flag = getenv("MallocStackLogging"); if (!flag) { flag = getenv("MallocStackLoggingNoCompact"); stack_logging_dontcompact = 1; } if (flag) { unsigned val = strtoul(flag, NULL, 0); if (val == 1) val = 0; if (val == -1) val = 0; malloc_logger = (val) ? (void *)val : stack_logging_log_stack; stack_logging_enable_logging = 1; if (malloc_logger == stack_logging_log_stack) { malloc_printf("malloc[%d]: recording stacks using standard recorder\n", getpid()); } else { malloc_printf("malloc[%d]: recording stacks using recorder %p\n", getpid(), malloc_logger); } if (stack_logging_dontcompact) malloc_printf("malloc[%d]: stack logging compaction turned off; VM can increase rapidly\n", getpid()); } if (getenv("MallocScribble")) { malloc_debug_flags |= SCALABLE_MALLOC_DO_SCRIBBLE; malloc_printf("malloc[%d]: enabling scribbling to detect mods to free blocks\n", getpid()); } flag = getenv("MallocCheckHeapStart"); if (flag) { malloc_check_start = strtoul(flag, NULL, 0); if (malloc_check_start == 0) malloc_check_start = 1; if (malloc_check_start == -1) malloc_check_start = 1; flag = getenv("MallocCheckHeapEach"); if (flag) { malloc_check_each = strtoul(flag, NULL, 0); if (malloc_check_each == 0) malloc_check_each = 1; if (malloc_check_each == -1) malloc_check_each = 1; } malloc_printf("malloc[%d]: checks heap after %dth operation and each %d operations\n", getpid(), malloc_check_start, malloc_check_each); } if (getenv("MallocHelp")) { malloc_printf( "malloc[%d]: environment variables that can be set for debug:\n" "- MallocGuardEdges to add 2 guard pages for each large block\n" "- MallocDoNotProtectPrelude to disable protection (when previous flag set)\n" "- MallocDoNotProtectPostlude to disable protection (when previous flag set)\n" "- MallocStackLogging to record all stacks. Tools like leaks can then be applied\n" "- MallocStackLoggingNoCompact to record all stacks. Needed for malloc_history\n" "- MallocScribble to detect writing on free blocks: 0x55 is written upon free\n" "- MallocCheckHeapStart to check the heap from time to time after operations \n" "- MallocHelp - this help!\n", getpid()); } } malloc_zone_t *malloc_create_zone(vm_size_t start_size, unsigned flags) { malloc_zone_t *zone; if (!malloc_num_zones) { char **env = * _NSGetEnviron(); char **p; char *c; /* Given that all environment variables start with "Malloc" we optimize by scanning quickly first the environment, therefore avoiding repeated calls to getenv() */ for (p = env; (c = *p) != NULL; ++p) { if (!strncmp(c, "Malloc", 6)) { set_flags_from_environment(); break; } } } zone = create_scalable_zone(start_size, malloc_debug_flags); malloc_zone_register(zone); return zone; } void malloc_destroy_zone(malloc_zone_t *zone) { malloc_zone_unregister(zone); zone->destroy(zone); } /********* Block creation and manipulation ************/ static void internal_check(void) { static vm_address_t *frames = NULL; static unsigned num_frames; if (malloc_zone_check(NULL)) { malloc_printf("MallocCheckHeap: PASSED check at %dth operation\n", malloc_check_counter-1); if (!frames) vm_allocate(mach_task_self(), (void *)&frames, vm_page_size, 1); thread_stack_pcs(frames, vm_page_size/sizeof(vm_address_t) - 1, &num_frames); } else { malloc_printf("*** MallocCheckHeap: FAILED check at %dth operation\n", malloc_check_counter-1); if (frames) { unsigned index = 1; malloc_printf("Stack for last operation where the malloc check succeeded: "); while (index < num_frames) malloc_printf("0x%x ", frames[index++]); malloc_printf("\n(Use 'atos' for a symbolic stack)\n"); } if (malloc_check_each > 1) { unsigned recomm_each = (malloc_check_each > 10) ? malloc_check_each/10 : 1; unsigned recomm_start = (malloc_check_counter > malloc_check_each+1) ? malloc_check_counter-1-malloc_check_each : 1; malloc_printf("*** Recommend using 'setenv MallocCheckHeapStart %d; setenv MallocCheckHeapEach %d' to narrow down failure\n", recomm_start, recomm_each); } malloc_printf("*** Sleeping for 100 seconds to leave time to attach\n"); sleep(100); } malloc_check_start += malloc_check_each; } void *malloc_zone_malloc(malloc_zone_t *zone, size_t size) { void *ptr; if ((unsigned)size >= MAX_ALLOCATION) { /* Probably a programming error */ fprintf(stderr, "*** malloc_zone_malloc[%d]: argument too large: %d\n", getpid(), (unsigned)size); return NULL; } if (malloc_check_start && (malloc_check_counter++ >= malloc_check_start)) { internal_check(); } ptr = zone->malloc(zone, size); if (malloc_logger) malloc_logger(MALLOC_LOG_TYPE_ALLOCATE | MALLOC_LOG_TYPE_HAS_ZONE, (unsigned)zone, size, 0, (unsigned)ptr, 0); return ptr; } void *malloc_zone_calloc(malloc_zone_t *zone, size_t num_items, size_t size) { void *ptr; if (malloc_check_start && (malloc_check_counter++ >= malloc_check_start)) { internal_check(); } if (((unsigned)num_items >= MAX_ALLOCATION) || ((unsigned)size >= MAX_ALLOCATION) || ((long long)size * num_items >= (long long) MAX_ALLOCATION)) { /* Probably a programming error */ fprintf(stderr, "*** malloc_zone_calloc[%d]: arguments too large: %d,%d\n", getpid(), (unsigned)num_items, (unsigned)size); return NULL; } ptr = zone->calloc(zone, num_items, size); if (malloc_logger) malloc_logger(MALLOC_LOG_TYPE_ALLOCATE | MALLOC_LOG_TYPE_HAS_ZONE | MALLOC_LOG_TYPE_CLEARED, (unsigned)zone, num_items * size, 0, (unsigned)ptr, 0); return ptr; } void *malloc_zone_valloc(malloc_zone_t *zone, size_t size) { void *ptr; if ((unsigned)size >= MAX_ALLOCATION) { /* Probably a programming error */ fprintf(stderr, "*** malloc_zone_valloc[%d]: argument too large: %d\n", getpid(), (unsigned)size); return NULL; } if (malloc_check_start && (malloc_check_counter++ >= malloc_check_start)) { internal_check(); } ptr = zone->valloc(zone, size); if (malloc_logger) malloc_logger(MALLOC_LOG_TYPE_ALLOCATE | MALLOC_LOG_TYPE_HAS_ZONE, (unsigned)zone, size, 0, (unsigned)ptr, 0); return ptr; } void *malloc_zone_realloc(malloc_zone_t *zone, void *ptr, size_t size) { void *new_ptr; if (malloc_check_start && (malloc_check_counter++ >= malloc_check_start)) { internal_check(); } new_ptr = zone->realloc(zone, ptr, size); if (malloc_logger) malloc_logger(MALLOC_LOG_TYPE_ALLOCATE | MALLOC_LOG_TYPE_DEALLOCATE | MALLOC_LOG_TYPE_HAS_ZONE, (unsigned)zone, (unsigned)ptr, size, (unsigned)new_ptr, 0); return new_ptr; } void malloc_zone_free(malloc_zone_t *zone, void *ptr) { if (malloc_logger) malloc_logger(MALLOC_LOG_TYPE_DEALLOCATE | MALLOC_LOG_TYPE_HAS_ZONE, (unsigned)zone, (unsigned)ptr, 0, 0, 0); if (malloc_check_start && (malloc_check_counter++ >= malloc_check_start)) { internal_check(); } zone->free(zone, ptr); } malloc_zone_t *malloc_zone_from_ptr(const void *ptr) { malloc_zone_t *zone; if (!ptr) return NULL; zone = find_registered_zone(ptr, NULL); return zone; } /********* Functions for zone implementors ************/ void malloc_zone_register(malloc_zone_t *zone) { /* Note that given the sequencing it is always safe to first get the number of zones, then get malloc_zones without taking the lock, if all you need is to iterate through the list */ MALLOC_LOCK(); if (malloc_num_zones >= INITIAL_ZONES) { malloc_zone_t **zones = malloc_zones; malloc_zone_t *pzone = malloc_zones[0]; boolean_t copy = malloc_num_zones == INITIAL_ZONES; if (copy) zones = NULL; // to avoid realloc on something not allocated MALLOC_UNLOCK(); zones = pzone->realloc(pzone, zones, (malloc_num_zones + 1) * sizeof(malloc_zone_t *)); // we leak initial_malloc_zones, not worth tracking it MALLOC_LOCK(); if (copy) memcpy(zones, malloc_zones, malloc_num_zones * sizeof(malloc_zone_t *)); malloc_zones = zones; } malloc_zones[malloc_num_zones] = zone; malloc_num_zones++; // note that we do this after setting malloc_num_zones, so enumerations without taking the lock are safe MALLOC_UNLOCK(); // malloc_printf("Registered %p malloc_zones at address %p is %p [%d zones]\n", zone, &malloc_zones, malloc_zones, malloc_num_zones); } void malloc_zone_unregister(malloc_zone_t *z) { unsigned index; MALLOC_LOCK(); index = malloc_num_zones; while (index--) { malloc_zone_t *zone = malloc_zones[index]; if (zone == z) { malloc_zones[index] = malloc_zones[--malloc_num_zones]; MALLOC_UNLOCK(); return; } } MALLOC_UNLOCK(); fprintf(stderr, "*** malloc[%d]: malloc_zone_unregister() failed for %p\n", getpid(), z); } void malloc_set_zone_name(malloc_zone_t *z, const char *name) { char *newName; if (z->zone_name) { free((char *)z->zone_name); z->zone_name = NULL; } newName = malloc_zone_malloc(z, strlen(name) + 1); strcpy(newName, name); z->zone_name = (const char *)newName; } const char *malloc_get_zone_name(malloc_zone_t *zone) { return zone->zone_name; } static char *_malloc_append_unsigned(unsigned value, unsigned base, char *head) { if (!value) { head[0] = '0'; } else { if (value >= base) head = _malloc_append_unsigned(value / base, base, head); value = value % base; head[0] = (value < 10) ? '0' + value : 'a' + value - 10; } return head+1; } void malloc_printf(const char *format, ...) { va_list args; char buf[1024]; char *head = buf; char ch; unsigned *nums; va_start(args, format); #if LOG_THREAD head = _malloc_append_unsigned(((unsigned)&args) >> 12, 16, head); *head++ = ' '; #endif nums = args; while (ch = *format++) { if (ch == '%') { ch = *format++; if (ch == 's') { char *str = (char *)(*nums++); write(2, buf, head - buf); head = buf; write(2, str, strlen(str)); } else { if (ch == 'p') { *head++ = '0'; *head++ = 'x'; } head = _malloc_append_unsigned(*nums++, (ch == 'd') ? 10 : 16, head); } } else { *head++ = ch; } } write(2, buf, head - buf); fflush(stderr); va_end(args); } /********* Generic ANSI callouts ************/ void *malloc(size_t size) { return malloc_zone_malloc(inline_malloc_default_zone(), size); } void *calloc(size_t num_items, size_t size) { return malloc_zone_calloc(inline_malloc_default_zone(), num_items, size); } void free(void *ptr) { malloc_zone_t *zone; if (!ptr) return; zone = find_registered_zone(ptr, NULL); if (zone) { malloc_zone_free(zone, ptr); } else { fprintf(stderr, "*** malloc[%d]: Deallocation of a pointer not malloced: %p; This could be a double free(), or free() called with the middle of an allocated block; Try setting environment variable MallocHelp to see tools to help debug\n", getpid(), ptr); } } void *realloc(void *old_ptr, size_t new_size) { malloc_zone_t *zone; size_t old_size = 0; if (!old_ptr) return malloc_zone_malloc(inline_malloc_default_zone(), new_size); zone = find_registered_zone(old_ptr, &old_size); if (zone && (old_size >= new_size)) return old_ptr; if (!zone) zone = inline_malloc_default_zone(); return malloc_zone_realloc(zone, old_ptr, new_size); } void *valloc(size_t size) { malloc_zone_t *zone = inline_malloc_default_zone(); return malloc_zone_valloc(zone, size); } extern void vfree(void *ptr) { free(ptr); } size_t malloc_size(const void *ptr) { size_t size = 0; if (!ptr) return size; (void)find_registered_zone(ptr, &size); return size; } size_t malloc_good_size (size_t size) { malloc_zone_t *zone = inline_malloc_default_zone(); return zone->introspect->good_size(zone, size); } /********* Functions for performance tools ************/ static kern_return_t _malloc_default_reader(task_t task, vm_address_t address, vm_size_t size, void **ptr) { *ptr = (void *)address; return 0; } kern_return_t malloc_get_all_zones(task_t task, memory_reader_t reader, vm_address_t **addresses, unsigned *count) { // Note that the 2 following addresses are not correct if the address of the target is different from your own. This notably occurs if the address of System.framework is slid (e.g. different than at B & I ) vm_address_t remote_malloc_zones = (vm_address_t)&malloc_zones; vm_address_t remote_malloc_num_zones = (vm_address_t)&malloc_num_zones; kern_return_t err; vm_address_t zones_address; vm_address_t *zones_address_ref; unsigned num_zones; unsigned *num_zones_ref; if (!reader) reader = _malloc_default_reader; // printf("Read malloc_zones at address %p should be %p\n", &malloc_zones, malloc_zones); err = reader(task, remote_malloc_zones, sizeof(void *), (void **)&zones_address_ref); // printf("Read malloc_zones[0x%x]=%p\n", remote_malloc_zones, *zones_address_ref); if (err) { fprintf(stderr, "*** malloc[%d]: malloc_get_all_zones: error reading zones_address at 0x%x\n", getpid(), (unsigned)remote_malloc_zones); return err; } zones_address = *zones_address_ref; // printf("Reading num_zones at address %p\n", remote_malloc_num_zones); err = reader(task, remote_malloc_num_zones, sizeof(unsigned), (void **)&num_zones_ref); if (err) { fprintf(stderr, "*** malloc[%d]: malloc_get_all_zones: error reading num_zones at 0x%x\n", getpid(), (unsigned)remote_malloc_num_zones); return err; } num_zones = *num_zones_ref; // printf("Read malloc_num_zones[0x%x]=%d\n", remote_malloc_num_zones, num_zones); *count = num_zones; // printf("malloc_get_all_zones succesfully found %d zones\n", num_zones); err = reader(task, zones_address, sizeof(malloc_zone_t *) * num_zones, (void **)addresses); if (err) { fprintf(stderr, "*** malloc[%d]: malloc_get_all_zones: error reading zones at 0x%x\n", getpid(), (unsigned)&zones_address); return err; } // printf("malloc_get_all_zones succesfully read %d zones\n", num_zones); return err; } /********* Debug helpers ************/ void malloc_zone_print_ptr_info(void *ptr) { malloc_zone_t *zone; if (!ptr) return; zone = find_registered_zone(ptr, NULL); if (zone) { printf("ptr %p in registered zone %p\n", ptr, zone); } else { printf("ptr %p not in heap\n", ptr); } } boolean_t malloc_zone_check(malloc_zone_t *zone) { boolean_t ok = 1; if (!zone) { unsigned index = 0; while (index < malloc_num_zones) { zone = malloc_zones[index++]; if (!zone->introspect->check(zone)) ok = 0; } } else { ok = zone->introspect->check(zone); } return ok; } void malloc_zone_print(malloc_zone_t *zone, boolean_t verbose) { if (!zone) { unsigned index = 0; while (index < malloc_num_zones) { zone = malloc_zones[index++]; zone->introspect->print(zone, verbose); } } else { zone->introspect->print(zone, verbose); } } void malloc_zone_log(malloc_zone_t *zone, void *address) { if (!zone) { unsigned index = 0; while (index < malloc_num_zones) { zone = malloc_zones[index++]; zone->introspect->log(zone, address); } } else { zone->introspect->log(zone, address); } } /********* Misc other entry points ************/ static void DefaultMallocError(int x) { fprintf(stderr, "*** malloc[%d]: error %d\n", getpid(), x); #if USE_SLEEP_RATHER_THAN_ABORT sleep(3600); #else abort(); #endif } void (*malloc_error(void (*func)(int)))(int) { return DefaultMallocError; } void _malloc_fork_prepare() { /* Prepare the malloc module for a fork by insuring that no thread is in a malloc critical section */ unsigned index = 0; MALLOC_LOCK(); while (index < malloc_num_zones) { malloc_zone_t *zone = malloc_zones[index++]; zone->introspect->force_lock(zone); } } void _malloc_fork_parent() { /* Called in the parent process after a fork() to resume normal operation. */ unsigned index = 0; MALLOC_UNLOCK(); while (index < malloc_num_zones) { malloc_zone_t *zone = malloc_zones[index++]; zone->introspect->force_unlock(zone); } } void _malloc_fork_child() { /* Called in the child process after a fork() to resume normal operation. In the MTASK case we also have to change memory inheritance so that the child does not share memory with the parent. */ unsigned index = 0; MALLOC_UNLOCK(); while (index < malloc_num_zones) { malloc_zone_t *zone = malloc_zones[index++]; zone->introspect->force_unlock(zone); } } size_t mstats(void) { malloc_zone_print(NULL, 0); return 1; } /***************** OBSOLETE ENTRY POINTS ********************/ #if PHASE_OUT_OLD_MALLOC #error PHASE OUT THE FOLLOWING FUNCTIONS #else #warning PHASE OUT THE FOLLOWING FUNCTIONS #endif void set_malloc_singlethreaded(boolean_t single) { static boolean_t warned = 0; if (!warned) { #if PHASE_OUT_OLD_MALLOC fprintf(stderr, "*** malloc[%d]: OBSOLETE: set_malloc_singlethreaded(%d)\n", getpid(), single); #endif warned = 1; } } void malloc_singlethreaded() { static boolean_t warned = 0; if (!warned) { fprintf(stderr, "*** malloc[%d]: OBSOLETE: malloc_singlethreaded()\n", getpid()); warned = 1; } } int malloc_debug(int level) { fprintf(stderr, "*** malloc[%d]: OBSOLETE: malloc_debug()\n", getpid()); return 0; } /********* exo_zone - FOR emacs freeze drying ************/ typedef struct { malloc_zone_t basic_zone; vm_range_t range; unsigned flags; } exo_zone_t; #define MALLOC_EXO_ZONE_SIZE_IS_OLD 1 #define MALLOC_EXO_ZONE_SIZE_IS_SCALABLE 2 typedef struct { unsigned int lastguyfree:1; unsigned int free:1; unsigned int size:30; } old_header_t; #define THIS_FREE 0x8000 // indicates this block is free #define PREV_FREE 0x4000 // indicates previous block is free #define SHIFT_QUANTUM 4 static size_t exo_zone_size(exo_zone_t *zone, const void *ptr) { if (zone->flags == MALLOC_EXO_ZONE_SIZE_IS_OLD) { if (ptr == (void *)zone->range.address) return zone->range.size; return ((old_header_t *)ptr)[-1].size - sizeof(old_header_t); } if (zone->flags == MALLOC_EXO_ZONE_SIZE_IS_SCALABLE) { // this is indeed a valid pointer unsigned short msize_and_free = ((unsigned short *)ptr)[-1]; return (msize_and_free & THIS_FREE) ? 0 : ((msize_and_free & ~PREV_FREE) << SHIFT_QUANTUM) - sizeof(unsigned short); } fprintf(stderr, "*** malloc[%d]: exo_zone_size unknown flags()\n", getpid()); return 0; } static void *exo_zone_malloc(exo_zone_t *zone, size_t new_size) { return malloc(new_size); } static void *exo_zone_calloc(exo_zone_t *zone, size_t num_items, size_t size) { return calloc(num_items, size); } static void *exo_zone_valloc(exo_zone_t *zone, size_t new_size) { return valloc(new_size); } static void *exo_zone_realloc(exo_zone_t *zone, void *ptr, size_t new_size) { size_t old_size = exo_zone_size(zone, ptr); void *new_ptr; if (new_size <= old_size) return ptr; new_ptr = malloc(new_size); if (old_size) memcpy(new_ptr, ptr, old_size); return new_ptr; } static void exo_zone_free(exo_zone_t *zone, void *ptr) { } static void exo_zone_destroy(exo_zone_t *zone) { free(zone); } static kern_return_t exo_zone_noop(void) { return 0; } static size_t exo_zone_good_size(exo_zone_t *zone, size_t size) { return size; } static struct malloc_introspection_t exo_zone_introspect = {(void *)exo_zone_noop, (void *)exo_zone_good_size, (void *)exo_zone_noop, (void *)exo_zone_noop, (void *)exo_zone_noop, (void *)exo_zone_noop, (void *)exo_zone_noop}; static malloc_zone_t *create_exo_zone(vm_address_t start, vm_size_t size, unsigned flags) { exo_zone_t *zone = calloc(sizeof(exo_zone_t), 1); zone->basic_zone.size = (void *)exo_zone_size; zone->basic_zone.malloc = (void *)exo_zone_malloc; zone->basic_zone.calloc = (void *)exo_zone_calloc; zone->basic_zone.valloc = (void *)exo_zone_valloc; zone->basic_zone.free = (void *)exo_zone_free; zone->basic_zone.realloc = (void *)exo_zone_realloc; zone->basic_zone.destroy = (void *)exo_zone_destroy; zone->basic_zone.introspect = &exo_zone_introspect; zone->flags = flags; return (malloc_zone_t *)zone; } /********* Support for emacs FreezeDrying ************/ #define OLD_MALLOC_VERSION 1 #define SCALABLE_MALLOC_VERSION 2 #define MAX_RANGES 1023 typedef struct { unsigned version; unsigned num; vm_range_t ranges[MAX_RANGES]; } malloc_freezedry_ranges; static void malloc_freezedry_recorder(task_t task, void *rr, unsigned type, vm_range_t *ranges, unsigned num) { malloc_freezedry_ranges *recorded = rr; while (num && (recorded->num < MAX_RANGES)) { recorded->ranges[recorded->num++] = *ranges; ranges++; num--; } if (recorded->num == MAX_RANGES) fprintf(stderr, "*** malloc[%d]: malloc_freezedry_recorder: exceeding capacity\n", getpid()); } #define ADDINT(cp,i) (*((int *)cp) = i, cp += sizeof(int)) static kern_return_t default_reader(task_t task, vm_address_t address, vm_size_t size, void **ptr) { *ptr = (void *)address; return 0; } int malloc_freezedry(void) { malloc_freezedry_ranges rr; unsigned index = 0; char *cp; size_t size; rr.version = SCALABLE_MALLOC_VERSION; rr.num = 0; while (index < malloc_num_zones) { malloc_zone_t *zone = malloc_zones[index++]; zone->introspect->enumerator(mach_task_self(), &rr, MALLOC_PTR_REGION_RANGE_TYPE | MALLOC_ADMIN_REGION_RANGE_TYPE, (vm_address_t)zone, default_reader, malloc_freezedry_recorder); } size = sizeof(rr) - (MAX_RANGES - rr.num) * sizeof(vm_range_t); cp = valloc(size); memcpy(cp, (void *)&rr, size); return (int)cp; } #define FETCHINT(i) (i = *((int *)cp), cp += sizeof(int)) int malloc_jumpstart(int cookie) { char *cp = (char *)cookie; int version, regions; FETCHINT(version); if ((version != OLD_MALLOC_VERSION) && (version != SCALABLE_MALLOC_VERSION)) return 1; FETCHINT(regions); // fprintf(stderr, "malloc_jumpstart got (version %d): %d regions\n", version, regions); while (--regions >= 0) { malloc_zone_t *zone; void **region = (void **)cp; if (version == OLD_MALLOC_VERSION) { cp += 3 * sizeof(void *); // printf("Should add region beginadd=%p endadd=%p zone=%p\n", region[0], region[1], region[2]); zone = create_exo_zone((vm_address_t)(region[0]), (vm_size_t)(region[1] - region[0]), MALLOC_EXO_ZONE_SIZE_IS_OLD); } else { cp += 2 * sizeof(void *); // printf("Should add region beginadd=%p endadd=%p zone=%p\n", region[0], region[1], region[2]); zone = create_exo_zone((vm_address_t)(region[0]), (vm_size_t)region[1], MALLOC_EXO_ZONE_SIZE_IS_SCALABLE); } malloc_zone_register(zone); } return 0; }