// Copyright 2017 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // This file contains all the logic necessary to intercept allocations on // macOS. "malloc zones" are an abstraction that allows the process to intercept // all malloc-related functions. There is no good mechanism [short of // interposition] to determine new malloc zones are added, so there's no clean // mechanism to intercept all malloc zones. This file contains logic to // intercept the default and purgeable zones, which always exist. A cursory // review of Chrome seems to imply that non-default zones are almost never used. // // This file also contains logic to intercept Core Foundation and Objective-C // allocations. The implementations forward to the default malloc zone, so the // only reason to intercept these calls is to re-label OOM crashes with slightly // more details. #include "base/allocator/allocator_interception_mac.h" #include #import #include #include #include #import #include #include #include "base/allocator/buildflags.h" #include "base/allocator/malloc_zone_functions_mac.h" #include "base/bind.h" #include "base/logging.h" #include "base/mac/mac_util.h" #include "base/mac/mach_logging.h" #include "base/process/memory.h" #include "base/scoped_clear_errno.h" #include "base/threading/sequenced_task_runner_handle.h" #include "build/build_config.h" #include "third_party/apple_apsl/CFBase.h" namespace base { namespace allocator { bool g_replaced_default_zone = false; namespace { bool g_oom_killer_enabled; // Starting with Mac OS X 10.7, the zone allocators set up by the system are // read-only, to prevent them from being overwritten in an attack. However, // blindly unprotecting and reprotecting the zone allocators fails with // GuardMalloc because GuardMalloc sets up its zone allocator using a block of // memory in its bss. Explicit saving/restoring of the protection is required. // // This function takes a pointer to a malloc zone, de-protects it if necessary, // and returns (in the out parameters) a region of memory (if any) to be // re-protected when modifications are complete. This approach assumes that // there is no contention for the protection of this memory. void DeprotectMallocZone(ChromeMallocZone* default_zone, mach_vm_address_t* reprotection_start, mach_vm_size_t* reprotection_length, vm_prot_t* reprotection_value) { mach_port_t unused; *reprotection_start = reinterpret_cast(default_zone); struct vm_region_basic_info_64 info; mach_msg_type_number_t count = VM_REGION_BASIC_INFO_COUNT_64; kern_return_t result = mach_vm_region( mach_task_self(), reprotection_start, reprotection_length, VM_REGION_BASIC_INFO_64, reinterpret_cast(&info), &count, &unused); MACH_CHECK(result == KERN_SUCCESS, result) << "mach_vm_region"; // The kernel always returns a null object for VM_REGION_BASIC_INFO_64, but // balance it with a deallocate in case this ever changes. See 10.9.2 // xnu-2422.90.20/osfmk/vm/vm_map.c vm_map_region. mach_port_deallocate(mach_task_self(), unused); // Does the region fully enclose the zone pointers? Possibly unwarranted // simplification used: using the size of a full version 8 malloc zone rather // than the actual smaller size if the passed-in zone is not version 8. CHECK(*reprotection_start <= reinterpret_cast(default_zone)); mach_vm_size_t zone_offset = reinterpret_cast(default_zone) - reinterpret_cast(*reprotection_start); CHECK(zone_offset + sizeof(ChromeMallocZone) <= *reprotection_length); if (info.protection & VM_PROT_WRITE) { // No change needed; the zone is already writable. *reprotection_start = 0; *reprotection_length = 0; *reprotection_value = VM_PROT_NONE; } else { *reprotection_value = info.protection; result = mach_vm_protect(mach_task_self(), *reprotection_start, *reprotection_length, false, info.protection | VM_PROT_WRITE); MACH_CHECK(result == KERN_SUCCESS, result) << "mach_vm_protect"; } } #if !defined(ADDRESS_SANITIZER) MallocZoneFunctions g_old_zone; MallocZoneFunctions g_old_purgeable_zone; void* oom_killer_malloc(struct _malloc_zone_t* zone, size_t size) { void* result = g_old_zone.malloc(zone, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void* oom_killer_calloc(struct _malloc_zone_t* zone, size_t num_items, size_t size) { void* result = g_old_zone.calloc(zone, num_items, size); if (!result && num_items && size) TerminateBecauseOutOfMemory(num_items * size); return result; } void* oom_killer_valloc(struct _malloc_zone_t* zone, size_t size) { void* result = g_old_zone.valloc(zone, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void oom_killer_free(struct _malloc_zone_t* zone, void* ptr) { g_old_zone.free(zone, ptr); } void* oom_killer_realloc(struct _malloc_zone_t* zone, void* ptr, size_t size) { void* result = g_old_zone.realloc(zone, ptr, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void* oom_killer_memalign(struct _malloc_zone_t* zone, size_t alignment, size_t size) { void* result = g_old_zone.memalign(zone, alignment, size); // Only die if posix_memalign would have returned ENOMEM, since there are // other reasons why NULL might be returned (see // http://opensource.apple.com/source/Libc/Libc-583/gen/malloc.c ). if (!result && size && alignment >= sizeof(void*) && (alignment & (alignment - 1)) == 0) { TerminateBecauseOutOfMemory(size); } return result; } void* oom_killer_malloc_purgeable(struct _malloc_zone_t* zone, size_t size) { void* result = g_old_purgeable_zone.malloc(zone, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void* oom_killer_calloc_purgeable(struct _malloc_zone_t* zone, size_t num_items, size_t size) { void* result = g_old_purgeable_zone.calloc(zone, num_items, size); if (!result && num_items && size) TerminateBecauseOutOfMemory(num_items * size); return result; } void* oom_killer_valloc_purgeable(struct _malloc_zone_t* zone, size_t size) { void* result = g_old_purgeable_zone.valloc(zone, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void oom_killer_free_purgeable(struct _malloc_zone_t* zone, void* ptr) { g_old_purgeable_zone.free(zone, ptr); } void* oom_killer_realloc_purgeable(struct _malloc_zone_t* zone, void* ptr, size_t size) { void* result = g_old_purgeable_zone.realloc(zone, ptr, size); if (!result && size) TerminateBecauseOutOfMemory(size); return result; } void* oom_killer_memalign_purgeable(struct _malloc_zone_t* zone, size_t alignment, size_t size) { void* result = g_old_purgeable_zone.memalign(zone, alignment, size); // Only die if posix_memalign would have returned ENOMEM, since there are // other reasons why NULL might be returned (see // http://opensource.apple.com/source/Libc/Libc-583/gen/malloc.c ). if (!result && size && alignment >= sizeof(void*) && (alignment & (alignment - 1)) == 0) { TerminateBecauseOutOfMemory(size); } return result; } #endif // !defined(ADDRESS_SANITIZER) #if !defined(ADDRESS_SANITIZER) // === Core Foundation CFAllocators === bool CanGetContextForCFAllocator() { return !base::mac::IsOSLaterThan10_14_DontCallThis(); } CFAllocatorContext* ContextForCFAllocator(CFAllocatorRef allocator) { ChromeCFAllocatorLions* our_allocator = const_cast( reinterpret_cast(allocator)); return &our_allocator->_context; } CFAllocatorAllocateCallBack g_old_cfallocator_system_default; CFAllocatorAllocateCallBack g_old_cfallocator_malloc; CFAllocatorAllocateCallBack g_old_cfallocator_malloc_zone; void* oom_killer_cfallocator_system_default(CFIndex alloc_size, CFOptionFlags hint, void* info) { void* result = g_old_cfallocator_system_default(alloc_size, hint, info); if (!result) TerminateBecauseOutOfMemory(alloc_size); return result; } void* oom_killer_cfallocator_malloc(CFIndex alloc_size, CFOptionFlags hint, void* info) { void* result = g_old_cfallocator_malloc(alloc_size, hint, info); if (!result) TerminateBecauseOutOfMemory(alloc_size); return result; } void* oom_killer_cfallocator_malloc_zone(CFIndex alloc_size, CFOptionFlags hint, void* info) { void* result = g_old_cfallocator_malloc_zone(alloc_size, hint, info); if (!result) TerminateBecauseOutOfMemory(alloc_size); return result; } #endif // !defined(ADDRESS_SANITIZER) // === Cocoa NSObject allocation === typedef id (*allocWithZone_t)(id, SEL, NSZone*); allocWithZone_t g_old_allocWithZone; id oom_killer_allocWithZone(id self, SEL _cmd, NSZone* zone) { id result = g_old_allocWithZone(self, _cmd, zone); if (!result) TerminateBecauseOutOfMemory(0); return result; } void UninterceptMallocZoneForTesting(struct _malloc_zone_t* zone) { ChromeMallocZone* chrome_zone = reinterpret_cast(zone); if (!IsMallocZoneAlreadyStored(chrome_zone)) return; MallocZoneFunctions& functions = GetFunctionsForZone(zone); ReplaceZoneFunctions(chrome_zone, &functions); } } // namespace bool UncheckedMallocMac(size_t size, void** result) { #if defined(ADDRESS_SANITIZER) *result = malloc(size); #else if (g_old_zone.malloc) { *result = g_old_zone.malloc(malloc_default_zone(), size); } else { *result = malloc(size); } #endif // defined(ADDRESS_SANITIZER) return *result != NULL; } bool UncheckedCallocMac(size_t num_items, size_t size, void** result) { #if defined(ADDRESS_SANITIZER) *result = calloc(num_items, size); #else if (g_old_zone.calloc) { *result = g_old_zone.calloc(malloc_default_zone(), num_items, size); } else { *result = calloc(num_items, size); } #endif // defined(ADDRESS_SANITIZER) return *result != NULL; } void StoreFunctionsForDefaultZone() { ChromeMallocZone* default_zone = reinterpret_cast( malloc_default_zone()); StoreMallocZone(default_zone); } void StoreFunctionsForAllZones() { // This ensures that the default zone is always at the front of the array, // which is important for performance. StoreFunctionsForDefaultZone(); vm_address_t* zones; unsigned int count; kern_return_t kr = malloc_get_all_zones(mach_task_self(), 0, &zones, &count); if (kr != KERN_SUCCESS) return; for (unsigned int i = 0; i < count; ++i) { ChromeMallocZone* zone = reinterpret_cast(zones[i]); StoreMallocZone(zone); } } void ReplaceFunctionsForStoredZones(const MallocZoneFunctions* functions) { // The default zone does not get returned in malloc_get_all_zones(). ChromeMallocZone* default_zone = reinterpret_cast(malloc_default_zone()); if (DoesMallocZoneNeedReplacing(default_zone, functions)) { ReplaceZoneFunctions(default_zone, functions); } vm_address_t* zones; unsigned int count; kern_return_t kr = malloc_get_all_zones(mach_task_self(), nullptr, &zones, &count); if (kr != KERN_SUCCESS) return; for (unsigned int i = 0; i < count; ++i) { ChromeMallocZone* zone = reinterpret_cast(zones[i]); if (DoesMallocZoneNeedReplacing(zone, functions)) { ReplaceZoneFunctions(zone, functions); } } g_replaced_default_zone = true; } void InterceptAllocationsMac() { if (g_oom_killer_enabled) return; g_oom_killer_enabled = true; // === C malloc/calloc/valloc/realloc/posix_memalign === // This approach is not perfect, as requests for amounts of memory larger than // MALLOC_ABSOLUTE_MAX_SIZE (currently SIZE_T_MAX - (2 * PAGE_SIZE)) will // still fail with a NULL rather than dying (see // http://opensource.apple.com/source/Libc/Libc-583/gen/malloc.c for details). // Unfortunately, it's the best we can do. Also note that this does not affect // allocations from non-default zones. #if !defined(ADDRESS_SANITIZER) // Don't do anything special on OOM for the malloc zones replaced by // AddressSanitizer, as modifying or protecting them may not work correctly. ChromeMallocZone* default_zone = reinterpret_cast(malloc_default_zone()); if (!IsMallocZoneAlreadyStored(default_zone)) { StoreZoneFunctions(default_zone, &g_old_zone); MallocZoneFunctions new_functions = {}; new_functions.malloc = oom_killer_malloc; new_functions.calloc = oom_killer_calloc; new_functions.valloc = oom_killer_valloc; new_functions.free = oom_killer_free; new_functions.realloc = oom_killer_realloc; new_functions.memalign = oom_killer_memalign; ReplaceZoneFunctions(default_zone, &new_functions); g_replaced_default_zone = true; } ChromeMallocZone* purgeable_zone = reinterpret_cast(malloc_default_purgeable_zone()); if (purgeable_zone && !IsMallocZoneAlreadyStored(purgeable_zone)) { StoreZoneFunctions(purgeable_zone, &g_old_purgeable_zone); MallocZoneFunctions new_functions = {}; new_functions.malloc = oom_killer_malloc_purgeable; new_functions.calloc = oom_killer_calloc_purgeable; new_functions.valloc = oom_killer_valloc_purgeable; new_functions.free = oom_killer_free_purgeable; new_functions.realloc = oom_killer_realloc_purgeable; new_functions.memalign = oom_killer_memalign_purgeable; ReplaceZoneFunctions(purgeable_zone, &new_functions); } #endif // === C malloc_zone_batch_malloc === // batch_malloc is omitted because the default malloc zone's implementation // only supports batch_malloc for "tiny" allocations from the free list. It // will fail for allocations larger than "tiny", and will only allocate as // many blocks as it's able to from the free list. These factors mean that it // can return less than the requested memory even in a non-out-of-memory // situation. There's no good way to detect whether a batch_malloc failure is // due to these other factors, or due to genuine memory or address space // exhaustion. The fact that it only allocates space from the "tiny" free list // means that it's likely that a failure will not be due to memory exhaustion. // Similarly, these constraints on batch_malloc mean that callers must always // be expecting to receive less memory than was requested, even in situations // where memory pressure is not a concern. Finally, the only public interface // to batch_malloc is malloc_zone_batch_malloc, which is specific to the // system's malloc implementation. It's unlikely that anyone's even heard of // it. #ifndef ADDRESS_SANITIZER // === Core Foundation CFAllocators === // This will not catch allocation done by custom allocators, but will catch // all allocation done by system-provided ones. CHECK(!g_old_cfallocator_system_default && !g_old_cfallocator_malloc && !g_old_cfallocator_malloc_zone) << "Old allocators unexpectedly non-null"; bool cf_allocator_internals_known = CanGetContextForCFAllocator(); if (cf_allocator_internals_known) { CFAllocatorContext* context = ContextForCFAllocator(kCFAllocatorSystemDefault); CHECK(context) << "Failed to get context for kCFAllocatorSystemDefault."; g_old_cfallocator_system_default = context->allocate; CHECK(g_old_cfallocator_system_default) << "Failed to get kCFAllocatorSystemDefault allocation function."; context->allocate = oom_killer_cfallocator_system_default; context = ContextForCFAllocator(kCFAllocatorMalloc); CHECK(context) << "Failed to get context for kCFAllocatorMalloc."; g_old_cfallocator_malloc = context->allocate; CHECK(g_old_cfallocator_malloc) << "Failed to get kCFAllocatorMalloc allocation function."; context->allocate = oom_killer_cfallocator_malloc; context = ContextForCFAllocator(kCFAllocatorMallocZone); CHECK(context) << "Failed to get context for kCFAllocatorMallocZone."; g_old_cfallocator_malloc_zone = context->allocate; CHECK(g_old_cfallocator_malloc_zone) << "Failed to get kCFAllocatorMallocZone allocation function."; context->allocate = oom_killer_cfallocator_malloc_zone; } else { DLOG(WARNING) << "Internals of CFAllocator not known; out-of-memory " "failures via CFAllocator will not result in termination. " "http://crbug.com/45650"; } #endif // === Cocoa NSObject allocation === // Note that both +[NSObject new] and +[NSObject alloc] call through to // +[NSObject allocWithZone:]. CHECK(!g_old_allocWithZone) << "Old allocator unexpectedly non-null"; Class nsobject_class = [NSObject class]; Method orig_method = class_getClassMethod(nsobject_class, @selector(allocWithZone:)); g_old_allocWithZone = reinterpret_cast(method_getImplementation(orig_method)); CHECK(g_old_allocWithZone) << "Failed to get allocWithZone allocation function."; method_setImplementation(orig_method, reinterpret_cast(oom_killer_allocWithZone)); } void UninterceptMallocZonesForTesting() { UninterceptMallocZoneForTesting(malloc_default_zone()); vm_address_t* zones; unsigned int count; kern_return_t kr = malloc_get_all_zones(mach_task_self(), 0, &zones, &count); CHECK(kr == KERN_SUCCESS); for (unsigned int i = 0; i < count; ++i) { UninterceptMallocZoneForTesting( reinterpret_cast(zones[i])); } ClearAllMallocZonesForTesting(); } namespace { void ShimNewMallocZonesAndReschedule(base::Time end_time, base::TimeDelta delay) { ShimNewMallocZones(); if (base::Time::Now() > end_time) return; base::TimeDelta next_delay = delay * 2; SequencedTaskRunnerHandle::Get()->PostDelayedTask( FROM_HERE, base::Bind(&ShimNewMallocZonesAndReschedule, end_time, next_delay), delay); } } // namespace void PeriodicallyShimNewMallocZones() { base::Time end_time = base::Time::Now() + base::TimeDelta::FromMinutes(1); base::TimeDelta initial_delay = base::TimeDelta::FromSeconds(1); ShimNewMallocZonesAndReschedule(end_time, initial_delay); } void ShimNewMallocZones() { StoreFunctionsForAllZones(); // Use the functions for the default zone as a template to replace those // new zones. ChromeMallocZone* default_zone = reinterpret_cast(malloc_default_zone()); DCHECK(IsMallocZoneAlreadyStored(default_zone)); MallocZoneFunctions new_functions; StoreZoneFunctions(default_zone, &new_functions); ReplaceFunctionsForStoredZones(&new_functions); } void ReplaceZoneFunctions(ChromeMallocZone* zone, const MallocZoneFunctions* functions) { // Remove protection. mach_vm_address_t reprotection_start = 0; mach_vm_size_t reprotection_length = 0; vm_prot_t reprotection_value = VM_PROT_NONE; DeprotectMallocZone(zone, &reprotection_start, &reprotection_length, &reprotection_value); CHECK(functions->malloc && functions->calloc && functions->valloc && functions->free && functions->realloc); zone->malloc = functions->malloc; zone->calloc = functions->calloc; zone->valloc = functions->valloc; zone->free = functions->free; zone->realloc = functions->realloc; if (functions->batch_malloc) zone->batch_malloc = functions->batch_malloc; if (functions->batch_free) zone->batch_free = functions->batch_free; if (functions->size) zone->size = functions->size; if (zone->version >= 5 && functions->memalign) { zone->memalign = functions->memalign; } if (zone->version >= 6 && functions->free_definite_size) { zone->free_definite_size = functions->free_definite_size; } // Restore protection if it was active. if (reprotection_start) { kern_return_t result = mach_vm_protect(mach_task_self(), reprotection_start, reprotection_length, false, reprotection_value); MACH_CHECK(result == KERN_SUCCESS, result) << "mach_vm_protect"; } } } // namespace allocator } // namespace base