// Copyright 2019 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. #include "src/heap/read-only-heap.h" #include #include #include "src/base/lazy-instance.h" #include "src/base/platform/mutex.h" #include "src/common/ptr-compr-inl.h" #include "src/heap/basic-memory-chunk.h" #include "src/heap/heap-write-barrier-inl.h" #include "src/heap/memory-chunk.h" #include "src/heap/read-only-spaces.h" #include "src/heap/third-party/heap-api.h" #include "src/objects/heap-object-inl.h" #include "src/objects/objects-inl.h" #include "src/objects/smi.h" #include "src/snapshot/read-only-deserializer.h" #include "src/utils/allocation.h" namespace v8 { namespace internal { namespace { // Mutex used to ensure that ReadOnlyArtifacts creation is only done once. base::LazyMutex read_only_heap_creation_mutex_ = LAZY_MUTEX_INITIALIZER; // Weak pointer holding ReadOnlyArtifacts. ReadOnlyHeap::SetUp creates a // std::shared_ptr from this when it attempts to reuse it. Since all Isolates // hold a std::shared_ptr to this, the object is destroyed when no Isolates // remain. base::LazyInstance>::type read_only_artifacts_ = LAZY_INSTANCE_INITIALIZER; std::shared_ptr InitializeSharedReadOnlyArtifacts() { std::shared_ptr artifacts; if (COMPRESS_POINTERS_IN_ISOLATE_CAGE_BOOL) { artifacts = std::make_shared(); } else { artifacts = std::make_shared(); } *read_only_artifacts_.Pointer() = artifacts; return artifacts; } } // namespace bool ReadOnlyHeap::IsSharedMemoryAvailable() { static bool shared_memory_allocation_supported = GetPlatformPageAllocator()->CanAllocateSharedPages(); return shared_memory_allocation_supported; } // This ReadOnlyHeap instance will only be accessed by Isolates that are already // set up. As such it doesn't need to be guarded by a mutex or shared_ptrs, // since an already set up Isolate will hold a shared_ptr to // read_only_artifacts_. SoleReadOnlyHeap* SoleReadOnlyHeap::shared_ro_heap_ = nullptr; // static void ReadOnlyHeap::SetUp(Isolate* isolate, SnapshotData* read_only_snapshot_data, bool can_rehash) { DCHECK_NOT_NULL(isolate); if (IsReadOnlySpaceShared()) { ReadOnlyHeap* ro_heap; if (read_only_snapshot_data != nullptr) { bool read_only_heap_created = false; base::MutexGuard guard(read_only_heap_creation_mutex_.Pointer()); std::shared_ptr artifacts = read_only_artifacts_.Get().lock(); if (!artifacts) { artifacts = InitializeSharedReadOnlyArtifacts(); artifacts->InitializeChecksum(read_only_snapshot_data); ro_heap = CreateInitalHeapForBootstrapping(isolate, artifacts); ro_heap->DeseralizeIntoIsolate(isolate, read_only_snapshot_data, can_rehash); read_only_heap_created = true; } else { // With pointer compression, there is one ReadOnlyHeap per Isolate. // Without PC, there is only one shared between all Isolates. ro_heap = artifacts->GetReadOnlyHeapForIsolate(isolate); isolate->SetUpFromReadOnlyArtifacts(artifacts, ro_heap); } artifacts->VerifyChecksum(read_only_snapshot_data, read_only_heap_created); ro_heap->InitializeIsolateRoots(isolate); } else { // This path should only be taken in mksnapshot, should only be run once // before tearing down the Isolate that holds this ReadOnlyArtifacts and // is not thread-safe. std::shared_ptr artifacts = read_only_artifacts_.Get().lock(); CHECK(!artifacts); artifacts = InitializeSharedReadOnlyArtifacts(); ro_heap = CreateInitalHeapForBootstrapping(isolate, artifacts); artifacts->VerifyChecksum(read_only_snapshot_data, true); } } else { auto* ro_heap = new ReadOnlyHeap(new ReadOnlySpace(isolate->heap())); isolate->SetUpFromReadOnlyArtifacts(nullptr, ro_heap); if (read_only_snapshot_data != nullptr) { ro_heap->DeseralizeIntoIsolate(isolate, read_only_snapshot_data, can_rehash); } } } void ReadOnlyHeap::DeseralizeIntoIsolate(Isolate* isolate, SnapshotData* read_only_snapshot_data, bool can_rehash) { DCHECK_NOT_NULL(read_only_snapshot_data); ReadOnlyDeserializer des(isolate, read_only_snapshot_data, can_rehash); des.DeserializeIntoIsolate(); InitFromIsolate(isolate); } void ReadOnlyHeap::OnCreateHeapObjectsComplete(Isolate* isolate) { DCHECK_NOT_NULL(isolate); InitFromIsolate(isolate); } // Only for compressed spaces ReadOnlyHeap::ReadOnlyHeap(ReadOnlyHeap* ro_heap, ReadOnlySpace* ro_space) : read_only_space_(ro_space), read_only_object_cache_(ro_heap->read_only_object_cache_) { DCHECK(ReadOnlyHeap::IsReadOnlySpaceShared()); DCHECK(COMPRESS_POINTERS_IN_ISOLATE_CAGE_BOOL); } // static ReadOnlyHeap* ReadOnlyHeap::CreateInitalHeapForBootstrapping( Isolate* isolate, std::shared_ptr artifacts) { DCHECK(IsReadOnlySpaceShared()); std::unique_ptr ro_heap; auto* ro_space = new ReadOnlySpace(isolate->heap()); if (COMPRESS_POINTERS_IN_ISOLATE_CAGE_BOOL) { ro_heap.reset(new ReadOnlyHeap(ro_space)); } else { std::unique_ptr sole_ro_heap( new SoleReadOnlyHeap(ro_space)); // The global shared ReadOnlyHeap is only used without pointer compression. SoleReadOnlyHeap::shared_ro_heap_ = sole_ro_heap.get(); ro_heap = std::move(sole_ro_heap); } artifacts->set_read_only_heap(std::move(ro_heap)); isolate->SetUpFromReadOnlyArtifacts(artifacts, artifacts->read_only_heap()); return artifacts->read_only_heap(); } void SoleReadOnlyHeap::InitializeIsolateRoots(Isolate* isolate) { void* const isolate_ro_roots = isolate->roots_table().read_only_roots_begin().location(); std::memcpy(isolate_ro_roots, read_only_roots_, kEntriesCount * sizeof(Address)); } void SoleReadOnlyHeap::InitializeFromIsolateRoots(Isolate* isolate) { void* const isolate_ro_roots = isolate->roots_table().read_only_roots_begin().location(); std::memcpy(read_only_roots_, isolate_ro_roots, kEntriesCount * sizeof(Address)); } void ReadOnlyHeap::InitFromIsolate(Isolate* isolate) { DCHECK(!init_complete_); read_only_space_->ShrinkPages(); if (IsReadOnlySpaceShared()) { InitializeFromIsolateRoots(isolate); std::shared_ptr artifacts( *read_only_artifacts_.Pointer()); read_only_space()->DetachPagesAndAddToArtifacts(artifacts); artifacts->ReinstallReadOnlySpace(isolate); read_only_space_ = artifacts->shared_read_only_space(); #ifdef DEBUG artifacts->VerifyHeapAndSpaceRelationships(isolate); #endif } else { read_only_space_->Seal(ReadOnlySpace::SealMode::kDoNotDetachFromHeap); } init_complete_ = true; } void ReadOnlyHeap::OnHeapTearDown(Heap* heap) { read_only_space_->TearDown(heap->memory_allocator()); delete read_only_space_; } void SoleReadOnlyHeap::OnHeapTearDown(Heap* heap) { // Do nothing as ReadOnlyHeap is shared between all Isolates. } // static void ReadOnlyHeap::PopulateReadOnlySpaceStatistics( SharedMemoryStatistics* statistics) { statistics->read_only_space_size_ = 0; statistics->read_only_space_used_size_ = 0; statistics->read_only_space_physical_size_ = 0; if (IsReadOnlySpaceShared()) { std::shared_ptr artifacts = read_only_artifacts_.Get().lock(); if (artifacts) { auto* ro_space = artifacts->shared_read_only_space(); statistics->read_only_space_size_ = ro_space->CommittedMemory(); statistics->read_only_space_used_size_ = ro_space->Size(); statistics->read_only_space_physical_size_ = ro_space->CommittedPhysicalMemory(); } } } // static bool ReadOnlyHeap::Contains(Address address) { if (V8_ENABLE_THIRD_PARTY_HEAP_BOOL) { return third_party_heap::Heap::InReadOnlySpace(address); } else { return BasicMemoryChunk::FromAddress(address)->InReadOnlySpace(); } } // static bool ReadOnlyHeap::Contains(HeapObject object) { if (V8_ENABLE_THIRD_PARTY_HEAP_BOOL) { return third_party_heap::Heap::InReadOnlySpace(object.address()); } else { return BasicMemoryChunk::FromHeapObject(object)->InReadOnlySpace(); } } Object* ReadOnlyHeap::ExtendReadOnlyObjectCache() { read_only_object_cache_.push_back(Smi::zero()); return &read_only_object_cache_.back(); } Object ReadOnlyHeap::cached_read_only_object(size_t i) const { DCHECK_LE(i, read_only_object_cache_.size()); return read_only_object_cache_[i]; } bool ReadOnlyHeap::read_only_object_cache_is_initialized() const { return read_only_object_cache_.size() > 0; } size_t ReadOnlyHeap::read_only_object_cache_size() const { return read_only_object_cache_.size(); } ReadOnlyHeapObjectIterator::ReadOnlyHeapObjectIterator( const ReadOnlyHeap* ro_heap) : ReadOnlyHeapObjectIterator(ro_heap->read_only_space()) {} ReadOnlyHeapObjectIterator::ReadOnlyHeapObjectIterator( const ReadOnlySpace* ro_space) : ro_space_(ro_space), current_page_(V8_ENABLE_THIRD_PARTY_HEAP_BOOL ? std::vector::iterator() : ro_space->pages().begin()), current_addr_(V8_ENABLE_THIRD_PARTY_HEAP_BOOL ? Address() : (*current_page_)->GetAreaStart()) {} HeapObject ReadOnlyHeapObjectIterator::Next() { if (V8_ENABLE_THIRD_PARTY_HEAP_BOOL) { return HeapObject(); // Unsupported } if (current_page_ == ro_space_->pages().end()) { return HeapObject(); } ReadOnlyPage* current_page = *current_page_; for (;;) { Address end = current_page->address() + current_page->area_size() + MemoryChunkLayout::ObjectStartOffsetInMemoryChunk(RO_SPACE); DCHECK_LE(current_addr_, end); if (current_addr_ == end) { // Progress to the next page. ++current_page_; if (current_page_ == ro_space_->pages().end()) { return HeapObject(); } current_page = *current_page_; current_addr_ = current_page->GetAreaStart(); } if (current_addr_ == ro_space_->top() && current_addr_ != ro_space_->limit()) { current_addr_ = ro_space_->limit(); continue; } HeapObject object = HeapObject::FromAddress(current_addr_); const int object_size = object.Size(); current_addr_ += object_size; if (object.IsFreeSpaceOrFiller()) { continue; } DCHECK_OBJECT_SIZE(object_size); return object; } } } // namespace internal } // namespace v8