/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * Hierarchy of SpiderMonkey system memory allocators: * * - System {m,c,re}alloc/new/free: Overridden by jemalloc in most * environments. Do not use these functions directly. * * - js_{m,c,re}alloc/new/free: Wraps the system allocators and adds a * failure injection framework for use by the fuzzers as well as templated, * typesafe variants. See js/public/Utility.h. * * - AllocPolicy: An interface for the js allocators, for use with templates. * These allocators are for system memory whose lifetime is not associated * with a GC thing. See js/src/jsalloc.h. * * - SystemAllocPolicy: No extra functionality over bare allocators. * * - TempAllocPolicy: Adds automatic error reporting to the provided * JSContext when allocations fail. * * - RuntimeAllocPolicy: Forwards to the JSRuntime MallocProvider. * * - ZoneAllocPolicy: Forwards to the Zone MallocProvider. * * - MallocProvider. A mixin base class that handles automatically updating * the GC's state in response to allocations that are tied to a GC lifetime * or are for a particular GC purpose. These allocators must only be used * for memory that will be freed when a GC thing is swept. * * - gc::Zone: Automatically triggers zone GC. * - JSRuntime: Automatically triggers full GC. * - ThreadsafeContext > ExclusiveContext > JSContext: * Dispatches directly to the runtime. */ #ifndef vm_MallocProvider_h #define vm_MallocProvider_h #include "mozilla/Attributes.h" #include "mozilla/Likely.h" #include "js/UniquePtr.h" #include "js/Utility.h" namespace js { template struct MallocProvider { template T* maybe_pod_malloc(size_t numElems) { T* p = js_pod_malloc(numElems); if (MOZ_LIKELY(p)) client()->updateMallocCounter(numElems * sizeof(T)); return p; } template T* maybe_pod_calloc(size_t numElems) { T* p = js_pod_calloc(numElems); if (MOZ_LIKELY(p)) client()->updateMallocCounter(numElems * sizeof(T)); return p; } template T* maybe_pod_realloc(T* prior, size_t oldSize, size_t newSize) { T* p = js_pod_realloc(prior, oldSize, newSize); if (MOZ_LIKELY(p)) { // For compatibility we do not account for realloc that decreases // previously allocated memory. if (newSize > oldSize) client()->updateMallocCounter((newSize - oldSize) * sizeof(T)); } return p; } template T* pod_malloc() { return pod_malloc(1); } template T* pod_malloc(size_t numElems) { T* p = maybe_pod_malloc(numElems); if (MOZ_LIKELY(p)) return p; size_t bytes; if (MOZ_UNLIKELY(!CalculateAllocSize(numElems, &bytes))) { client()->reportAllocationOverflow(); return nullptr; } p = (T*)client()->onOutOfMemory(AllocFunction::Malloc, bytes); if (p) client()->updateMallocCounter(bytes); return p; } template T* pod_malloc_with_extra(size_t numExtra) { size_t bytes; if (MOZ_UNLIKELY((!CalculateAllocSizeWithExtra(numExtra, &bytes)))) { client()->reportAllocationOverflow(); return nullptr; } T* p = static_cast(js_malloc(bytes)); if (MOZ_LIKELY(p)) { client()->updateMallocCounter(bytes); return p; } p = (T*)client()->onOutOfMemory(AllocFunction::Malloc, bytes); if (p) client()->updateMallocCounter(bytes); return p; } template UniquePtr make_pod_array(size_t numElems) { return UniquePtr(pod_malloc(numElems)); } template T* pod_calloc() { return pod_calloc(1); } template T* pod_calloc(size_t numElems) { T* p = maybe_pod_calloc(numElems); if (MOZ_LIKELY(p)) return p; size_t bytes; if (MOZ_UNLIKELY(!CalculateAllocSize(numElems, &bytes))) { client()->reportAllocationOverflow(); return nullptr; } p = (T*)client()->onOutOfMemory(AllocFunction::Calloc, bytes); if (p) client()->updateMallocCounter(bytes); return p; } template T* pod_calloc_with_extra(size_t numExtra) { size_t bytes; if (MOZ_UNLIKELY((!CalculateAllocSizeWithExtra(numExtra, &bytes)))) { client()->reportAllocationOverflow(); return nullptr; } T* p = static_cast(js_calloc(bytes)); if (p) { client()->updateMallocCounter(bytes); return p; } p = (T*)client()->onOutOfMemory(AllocFunction::Calloc, bytes); if (p) client()->updateMallocCounter(bytes); return p; } template UniquePtr make_zeroed_pod_array(size_t numElems) { return UniquePtr(pod_calloc(numElems)); } template T* pod_realloc(T* prior, size_t oldSize, size_t newSize) { T* p = maybe_pod_realloc(prior, oldSize, newSize); if (MOZ_LIKELY(p)) return p; size_t bytes; if (MOZ_UNLIKELY(!CalculateAllocSize(newSize, &bytes))) { client()->reportAllocationOverflow(); return nullptr; } p = (T*)client()->onOutOfMemory(AllocFunction::Realloc, bytes, prior); if (p && newSize > oldSize) client()->updateMallocCounter((newSize - oldSize) * sizeof(T)); return p; } JS_DECLARE_NEW_METHODS(new_, pod_malloc, MOZ_ALWAYS_INLINE) JS_DECLARE_MAKE_METHODS(make_unique, new_, MOZ_ALWAYS_INLINE) private: Client* client() { return static_cast(this); } }; } /* namespace js */ #endif /* vm_MallocProvider_h */