// Copyright 2020 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef INCLUDE_CPPGC_ALLOCATION_H_ #define INCLUDE_CPPGC_ALLOCATION_H_ #include #include #include #include #include #include #include "cppgc/custom-space.h" #include "cppgc/internal/api-constants.h" #include "cppgc/internal/gc-info.h" #include "cppgc/type-traits.h" #include "v8config.h" // NOLINT(build/include_directory) #if defined(__has_attribute) #if __has_attribute(assume_aligned) #define CPPGC_DEFAULT_ALIGNED \ __attribute__((assume_aligned(api_constants::kDefaultAlignment))) #define CPPGC_DOUBLE_WORD_ALIGNED \ __attribute__((assume_aligned(2 * api_constants::kDefaultAlignment))) #endif // __has_attribute(assume_aligned) #endif // defined(__has_attribute) #if !defined(CPPGC_DEFAULT_ALIGNED) #define CPPGC_DEFAULT_ALIGNED #endif #if !defined(CPPGC_DOUBLE_WORD_ALIGNED) #define CPPGC_DOUBLE_WORD_ALIGNED #endif namespace cppgc { /** * AllocationHandle is used to allocate garbage-collected objects. */ class AllocationHandle; namespace internal { // Similar to C++17 std::align_val_t; enum class AlignVal : size_t {}; class V8_EXPORT MakeGarbageCollectedTraitInternal { protected: static inline void MarkObjectAsFullyConstructed(const void* payload) { // See api_constants for an explanation of the constants. std::atomic* atomic_mutable_bitfield = reinterpret_cast*>( const_cast(reinterpret_cast( reinterpret_cast(payload) - api_constants::kFullyConstructedBitFieldOffsetFromPayload))); // It's safe to split use load+store here (instead of a read-modify-write // operation), since it's guaranteed that this 16-bit bitfield is only // modified by a single thread. This is cheaper in terms of code bloat (on // ARM) and performance. uint16_t value = atomic_mutable_bitfield->load(std::memory_order_relaxed); value |= api_constants::kFullyConstructedBitMask; atomic_mutable_bitfield->store(value, std::memory_order_release); } // Dispatch based on compile-time information. // // Default implementation is for a custom space with >`kDefaultAlignment` byte // alignment. template struct AllocationDispatcher final { static void* Invoke(AllocationHandle& handle, size_t size) { static_assert(std::is_base_of::value, "Custom space must inherit from CustomSpaceBase."); static_assert( !CustomSpace::kSupportsCompaction, "Custom spaces that support compaction do not support allocating " "objects with non-default (i.e. word-sized) alignment."); return MakeGarbageCollectedTraitInternal::Allocate( handle, size, static_cast(alignment), internal::GCInfoTrait::Index(), CustomSpace::kSpaceIndex); } }; // Fast path for regular allocations for the default space with // `kDefaultAlignment` byte alignment. template struct AllocationDispatcher final { static void* Invoke(AllocationHandle& handle, size_t size) { return MakeGarbageCollectedTraitInternal::Allocate( handle, size, internal::GCInfoTrait::Index()); } }; // Default space with >`kDefaultAlignment` byte alignment. template struct AllocationDispatcher final { static void* Invoke(AllocationHandle& handle, size_t size) { return MakeGarbageCollectedTraitInternal::Allocate( handle, size, static_cast(alignment), internal::GCInfoTrait::Index()); } }; // Custom space with `kDefaultAlignment` byte alignment. template struct AllocationDispatcher final { static void* Invoke(AllocationHandle& handle, size_t size) { static_assert(std::is_base_of::value, "Custom space must inherit from CustomSpaceBase."); return MakeGarbageCollectedTraitInternal::Allocate( handle, size, internal::GCInfoTrait::Index(), CustomSpace::kSpaceIndex); } }; private: static void* CPPGC_DEFAULT_ALIGNED Allocate(cppgc::AllocationHandle&, size_t, GCInfoIndex); static void* CPPGC_DOUBLE_WORD_ALIGNED Allocate(cppgc::AllocationHandle&, size_t, AlignVal, GCInfoIndex); static void* CPPGC_DEFAULT_ALIGNED Allocate(cppgc::AllocationHandle&, size_t, GCInfoIndex, CustomSpaceIndex); static void* CPPGC_DOUBLE_WORD_ALIGNED Allocate(cppgc::AllocationHandle&, size_t, AlignVal, GCInfoIndex, CustomSpaceIndex); friend class HeapObjectHeader; }; } // namespace internal /** * Base trait that provides utilities for advancers users that have custom * allocation needs (e.g., overriding size). It's expected that users override * MakeGarbageCollectedTrait (see below) and inherit from * MakeGarbageCollectedTraitBase and make use of the low-level primitives * offered to allocate and construct an object. */ template class MakeGarbageCollectedTraitBase : private internal::MakeGarbageCollectedTraitInternal { private: static_assert(internal::IsGarbageCollectedType::value, "T needs to be a garbage collected object"); static_assert(!IsGarbageCollectedWithMixinTypeV || sizeof(T) <= internal::api_constants::kLargeObjectSizeThreshold, "GarbageCollectedMixin may not be a large object"); protected: /** * Allocates memory for an object of type T. * * \param handle AllocationHandle identifying the heap to allocate the object * on. * \param size The size that should be reserved for the object. * \returns the memory to construct an object of type T on. */ V8_INLINE static void* Allocate(AllocationHandle& handle, size_t size) { static_assert( std::is_base_of::value, "U of GarbageCollected must be a base of T. Check " "GarbageCollected base class inheritance."); static constexpr size_t kWantedAlignment = alignof(T) < internal::api_constants::kDefaultAlignment ? internal::api_constants::kDefaultAlignment : alignof(T); static_assert( kWantedAlignment <= internal::api_constants::kMaxSupportedAlignment, "Requested alignment larger than alignof(std::max_align_t) bytes. " "Please file a bug to possibly get this restriction lifted."); return AllocationDispatcher< typename internal::GCInfoFolding< T, typename T::ParentMostGarbageCollectedType>::ResultType, typename SpaceTrait::Space, kWantedAlignment>::Invoke(handle, size); } /** * Marks an object as fully constructed, resulting in precise handling by the * garbage collector. * * \param payload The base pointer the object is allocated at. */ V8_INLINE static void MarkObjectAsFullyConstructed(const void* payload) { internal::MakeGarbageCollectedTraitInternal::MarkObjectAsFullyConstructed( payload); } }; /** * Passed to MakeGarbageCollected to specify how many bytes should be appended * to the allocated object. * * Example: * \code * class InlinedArray final : public GarbageCollected { * public: * explicit InlinedArray(size_t bytes) : size(bytes), byte_array(this + 1) {} * void Trace(Visitor*) const {} * size_t size; * char* byte_array; * }; * * auto* inlined_array = MakeGarbageCollectedbyte_array[i]); * } * \endcode */ struct AdditionalBytes { constexpr explicit AdditionalBytes(size_t bytes) : value(bytes) {} const size_t value; }; /** * Default trait class that specifies how to construct an object of type T. * Advanced users may override how an object is constructed using the utilities * that are provided through MakeGarbageCollectedTraitBase. * * Any trait overriding construction must * - allocate through `MakeGarbageCollectedTraitBase::Allocate`; * - mark the object as fully constructed using * `MakeGarbageCollectedTraitBase::MarkObjectAsFullyConstructed`; */ template class MakeGarbageCollectedTrait : public MakeGarbageCollectedTraitBase { public: template static T* Call(AllocationHandle& handle, Args&&... args) { void* memory = MakeGarbageCollectedTraitBase::Allocate(handle, sizeof(T)); T* object = ::new (memory) T(std::forward(args)...); MakeGarbageCollectedTraitBase::MarkObjectAsFullyConstructed(object); return object; } template static T* Call(AllocationHandle& handle, AdditionalBytes additional_bytes, Args&&... args) { void* memory = MakeGarbageCollectedTraitBase::Allocate( handle, sizeof(T) + additional_bytes.value); T* object = ::new (memory) T(std::forward(args)...); MakeGarbageCollectedTraitBase::MarkObjectAsFullyConstructed(object); return object; } }; /** * Allows users to specify a post-construction callback for specific types. The * callback is invoked on the instance of type T right after it has been * constructed. This can be useful when the callback requires a * fully-constructed object to be able to dispatch to virtual methods. */ template struct PostConstructionCallbackTrait { static void Call(T*) {} }; /** * Constructs a managed object of type T where T transitively inherits from * GarbageCollected. * * \param args List of arguments with which an instance of T will be * constructed. * \returns an instance of type T. */ template V8_INLINE T* MakeGarbageCollected(AllocationHandle& handle, Args&&... args) { T* object = MakeGarbageCollectedTrait::Call(handle, std::forward(args)...); PostConstructionCallbackTrait::Call(object); return object; } /** * Constructs a managed object of type T where T transitively inherits from * GarbageCollected. Created objects will have additional bytes appended to * it. Allocated memory would suffice for `sizeof(T) + additional_bytes`. * * \param additional_bytes Denotes how many bytes to append to T. * \param args List of arguments with which an instance of T will be * constructed. * \returns an instance of type T. */ template V8_INLINE T* MakeGarbageCollected(AllocationHandle& handle, AdditionalBytes additional_bytes, Args&&... args) { T* object = MakeGarbageCollectedTrait::Call(handle, additional_bytes, std::forward(args)...); PostConstructionCallbackTrait::Call(object); return object; } } // namespace cppgc #undef CPPGC_DEFAULT_ALIGNED #undef CPPGC_DOUBLE_WORD_ALIGNED #endif // INCLUDE_CPPGC_ALLOCATION_H_