// Copyright 2009 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/global-handles.h" #include "src/api.h" #include "src/v8.h" #include "src/vm-state-inl.h" namespace v8 { namespace internal { ObjectGroup::~ObjectGroup() { if (info != NULL) info->Dispose(); delete[] objects; } ImplicitRefGroup::~ImplicitRefGroup() { delete[] children; } class GlobalHandles::Node { public: // State transition diagram: // FREE -> NORMAL <-> WEAK -> PENDING -> NEAR_DEATH -> { NORMAL, WEAK, FREE } enum State { FREE = 0, NORMAL, // Normal global handle. WEAK, // Flagged as weak but not yet finalized. PENDING, // Has been recognized as only reachable by weak handles. NEAR_DEATH, // Callback has informed the handle is near death. NUMBER_OF_NODE_STATES }; // Maps handle location (slot) to the containing node. static Node* FromLocation(Object** location) { DCHECK(offsetof(Node, object_) == 0); return reinterpret_cast(location); } Node() { DCHECK(offsetof(Node, class_id_) == Internals::kNodeClassIdOffset); DCHECK(offsetof(Node, flags_) == Internals::kNodeFlagsOffset); STATIC_ASSERT(static_cast(NodeState::kMask) == Internals::kNodeStateMask); STATIC_ASSERT(WEAK == Internals::kNodeStateIsWeakValue); STATIC_ASSERT(PENDING == Internals::kNodeStateIsPendingValue); STATIC_ASSERT(NEAR_DEATH == Internals::kNodeStateIsNearDeathValue); STATIC_ASSERT(static_cast(IsIndependent::kShift) == Internals::kNodeIsIndependentShift); STATIC_ASSERT(static_cast(IsPartiallyDependent::kShift) == Internals::kNodeIsPartiallyDependentShift); STATIC_ASSERT(static_cast(IsActive::kShift) == Internals::kNodeIsActiveShift); } #ifdef ENABLE_HANDLE_ZAPPING ~Node() { // TODO(1428): if it's a weak handle we should have invoked its callback. // Zap the values for eager trapping. object_ = reinterpret_cast(kGlobalHandleZapValue); class_id_ = v8::HeapProfiler::kPersistentHandleNoClassId; index_ = 0; set_independent(false); if (FLAG_scavenge_reclaim_unmodified_objects) { set_active(false); } else { set_partially_dependent(false); } set_in_new_space_list(false); parameter_or_next_free_.next_free = NULL; weak_callback_ = NULL; } #endif void Initialize(int index, Node** first_free) { object_ = reinterpret_cast(kGlobalHandleZapValue); index_ = static_cast(index); DCHECK(static_cast(index_) == index); set_state(FREE); set_weakness_type(NORMAL_WEAK); set_in_new_space_list(false); parameter_or_next_free_.next_free = *first_free; *first_free = this; } void Acquire(Object* object) { DCHECK(state() == FREE); object_ = object; class_id_ = v8::HeapProfiler::kPersistentHandleNoClassId; set_independent(false); if (FLAG_scavenge_reclaim_unmodified_objects) { set_active(false); } else { set_partially_dependent(false); } set_state(NORMAL); parameter_or_next_free_.parameter = NULL; weak_callback_ = NULL; IncreaseBlockUses(); } void Zap() { DCHECK(IsInUse()); // Zap the values for eager trapping. object_ = reinterpret_cast(kGlobalHandleZapValue); } void Release() { DCHECK(IsInUse()); set_state(FREE); // Zap the values for eager trapping. object_ = reinterpret_cast(kGlobalHandleZapValue); class_id_ = v8::HeapProfiler::kPersistentHandleNoClassId; set_independent(false); if (FLAG_scavenge_reclaim_unmodified_objects) { set_active(false); } else { set_partially_dependent(false); } weak_callback_ = NULL; DecreaseBlockUses(); } // Object slot accessors. Object* object() const { return object_; } Object** location() { return &object_; } Handle handle() { return Handle(location()); } // Wrapper class ID accessors. bool has_wrapper_class_id() const { return class_id_ != v8::HeapProfiler::kPersistentHandleNoClassId; } uint16_t wrapper_class_id() const { return class_id_; } // State and flag accessors. State state() const { return NodeState::decode(flags_); } void set_state(State state) { flags_ = NodeState::update(flags_, state); } bool is_independent() { return IsIndependent::decode(flags_); } void set_independent(bool v) { flags_ = IsIndependent::update(flags_, v); } bool is_partially_dependent() { CHECK(!FLAG_scavenge_reclaim_unmodified_objects); return IsPartiallyDependent::decode(flags_); } void set_partially_dependent(bool v) { CHECK(!FLAG_scavenge_reclaim_unmodified_objects); flags_ = IsPartiallyDependent::update(flags_, v); } bool is_active() { CHECK(FLAG_scavenge_reclaim_unmodified_objects); return IsActive::decode(flags_); } void set_active(bool v) { CHECK(FLAG_scavenge_reclaim_unmodified_objects); flags_ = IsActive::update(flags_, v); } bool is_in_new_space_list() { return IsInNewSpaceList::decode(flags_); } void set_in_new_space_list(bool v) { flags_ = IsInNewSpaceList::update(flags_, v); } WeaknessType weakness_type() const { return NodeWeaknessType::decode(flags_); } void set_weakness_type(WeaknessType weakness_type) { flags_ = NodeWeaknessType::update(flags_, weakness_type); } bool IsNearDeath() const { // Check for PENDING to ensure correct answer when processing callbacks. return state() == PENDING || state() == NEAR_DEATH; } bool IsWeak() const { return state() == WEAK; } bool IsInUse() const { return state() != FREE; } bool IsRetainer() const { return state() != FREE && !(state() == NEAR_DEATH && weakness_type() != NORMAL_WEAK); } bool IsStrongRetainer() const { return state() == NORMAL; } bool IsWeakRetainer() const { return state() == WEAK || state() == PENDING || (state() == NEAR_DEATH && weakness_type() == NORMAL_WEAK); } void MarkPending() { DCHECK(state() == WEAK); set_state(PENDING); } // Independent flag accessors. void MarkIndependent() { DCHECK(IsInUse()); set_independent(true); } void MarkPartiallyDependent() { DCHECK(IsInUse()); if (GetGlobalHandles()->isolate()->heap()->InNewSpace(object_)) { set_partially_dependent(true); } } void clear_partially_dependent() { set_partially_dependent(false); } // Callback accessor. // TODO(svenpanne) Re-enable or nuke later. // WeakReferenceCallback callback() { return callback_; } // Callback parameter accessors. void set_parameter(void* parameter) { DCHECK(IsInUse()); parameter_or_next_free_.parameter = parameter; } void* parameter() const { DCHECK(IsInUse()); return parameter_or_next_free_.parameter; } // Accessors for next free node in the free list. Node* next_free() { DCHECK(state() == FREE); return parameter_or_next_free_.next_free; } void set_next_free(Node* value) { DCHECK(state() == FREE); parameter_or_next_free_.next_free = value; } void MakeWeak(void* parameter, WeakCallback weak_callback) { DCHECK(weak_callback != nullptr); DCHECK(IsInUse()); CHECK_NE(object_, reinterpret_cast(kGlobalHandleZapValue)); set_state(WEAK); set_weakness_type(NORMAL_WEAK); set_parameter(parameter); weak_callback_ = weak_callback; } void MakeWeak(void* parameter, WeakCallbackInfo::Callback phantom_callback, v8::WeakCallbackType type) { DCHECK(phantom_callback != nullptr); DCHECK(IsInUse()); CHECK_NE(object_, reinterpret_cast(kGlobalHandleZapValue)); set_state(WEAK); switch (type) { case v8::WeakCallbackType::kParameter: set_weakness_type(PHANTOM_WEAK); break; case v8::WeakCallbackType::kInternalFields: set_weakness_type(PHANTOM_WEAK_2_INTERNAL_FIELDS); break; } set_parameter(parameter); weak_callback_ = reinterpret_cast(phantom_callback); } void* ClearWeakness() { DCHECK(IsInUse()); void* p = parameter(); set_state(NORMAL); set_parameter(NULL); return p; } void CollectPhantomCallbackData( Isolate* isolate, List* pending_phantom_callbacks) { DCHECK(weakness_type() == PHANTOM_WEAK || weakness_type() == PHANTOM_WEAK_2_INTERNAL_FIELDS); DCHECK(state() == PENDING); void* internal_fields[v8::kInternalFieldsInWeakCallback] = {nullptr, nullptr}; if (weakness_type() != PHANTOM_WEAK && object()->IsJSObject()) { auto jsobject = JSObject::cast(object()); int field_count = jsobject->GetInternalFieldCount(); for (int i = 0; i < v8::kInternalFieldsInWeakCallback; ++i) { if (field_count == i) break; auto field = jsobject->GetInternalField(i); if (field->IsSmi()) internal_fields[i] = field; } } // Zap with something dangerous. *location() = reinterpret_cast(0x6057ca11); typedef v8::WeakCallbackInfo Data; auto callback = reinterpret_cast(weak_callback_); pending_phantom_callbacks->Add( PendingPhantomCallback(this, callback, parameter(), internal_fields)); DCHECK(IsInUse()); set_state(NEAR_DEATH); } bool PostGarbageCollectionProcessing(Isolate* isolate) { // Handles only weak handles (not phantom) that are dying. if (state() != Node::PENDING) return false; if (weak_callback_ == NULL) { Release(); return false; } set_state(NEAR_DEATH); // Check that we are not passing a finalized external string to // the callback. DCHECK(!object_->IsExternalOneByteString() || ExternalOneByteString::cast(object_)->resource() != NULL); DCHECK(!object_->IsExternalTwoByteString() || ExternalTwoByteString::cast(object_)->resource() != NULL); if (weakness_type() != NORMAL_WEAK) return false; // Leaving V8. VMState vmstate(isolate); HandleScope handle_scope(isolate); Object** object = location(); Handle handle(*object, isolate); v8::WeakCallbackData data( reinterpret_cast(isolate), parameter(), v8::Utils::ToLocal(handle)); set_parameter(NULL); weak_callback_(data); // Absence of explicit cleanup or revival of weak handle // in most of the cases would lead to memory leak. CHECK(state() != NEAR_DEATH); return true; } inline GlobalHandles* GetGlobalHandles(); private: inline NodeBlock* FindBlock(); inline void IncreaseBlockUses(); inline void DecreaseBlockUses(); // Storage for object pointer. // Placed first to avoid offset computation. Object* object_; // Next word stores class_id, index, state, and independent. // Note: the most aligned fields should go first. // Wrapper class ID. uint16_t class_id_; // Index in the containing handle block. uint8_t index_; // This stores three flags (independent, partially_dependent and // in_new_space_list) and a State. class NodeState : public BitField {}; class IsIndependent : public BitField {}; // The following two fields are mutually exclusive class IsActive : public BitField {}; class IsPartiallyDependent : public BitField {}; class IsInNewSpaceList : public BitField {}; class NodeWeaknessType : public BitField {}; uint8_t flags_; // Handle specific callback - might be a weak reference in disguise. WeakCallback weak_callback_; // Provided data for callback. In FREE state, this is used for // the free list link. union { void* parameter; Node* next_free; } parameter_or_next_free_; DISALLOW_COPY_AND_ASSIGN(Node); }; class GlobalHandles::NodeBlock { public: static const int kSize = 256; explicit NodeBlock(GlobalHandles* global_handles, NodeBlock* next) : next_(next), used_nodes_(0), next_used_(NULL), prev_used_(NULL), global_handles_(global_handles) {} void PutNodesOnFreeList(Node** first_free) { for (int i = kSize - 1; i >= 0; --i) { nodes_[i].Initialize(i, first_free); } } Node* node_at(int index) { DCHECK(0 <= index && index < kSize); return &nodes_[index]; } void IncreaseUses() { DCHECK(used_nodes_ < kSize); if (used_nodes_++ == 0) { NodeBlock* old_first = global_handles_->first_used_block_; global_handles_->first_used_block_ = this; next_used_ = old_first; prev_used_ = NULL; if (old_first == NULL) return; old_first->prev_used_ = this; } } void DecreaseUses() { DCHECK(used_nodes_ > 0); if (--used_nodes_ == 0) { if (next_used_ != NULL) next_used_->prev_used_ = prev_used_; if (prev_used_ != NULL) prev_used_->next_used_ = next_used_; if (this == global_handles_->first_used_block_) { global_handles_->first_used_block_ = next_used_; } } } GlobalHandles* global_handles() { return global_handles_; } // Next block in the list of all blocks. NodeBlock* next() const { return next_; } // Next/previous block in the list of blocks with used nodes. NodeBlock* next_used() const { return next_used_; } NodeBlock* prev_used() const { return prev_used_; } private: Node nodes_[kSize]; NodeBlock* const next_; int used_nodes_; NodeBlock* next_used_; NodeBlock* prev_used_; GlobalHandles* global_handles_; }; GlobalHandles* GlobalHandles::Node::GetGlobalHandles() { return FindBlock()->global_handles(); } GlobalHandles::NodeBlock* GlobalHandles::Node::FindBlock() { intptr_t ptr = reinterpret_cast(this); ptr = ptr - index_ * sizeof(Node); NodeBlock* block = reinterpret_cast(ptr); DCHECK(block->node_at(index_) == this); return block; } void GlobalHandles::Node::IncreaseBlockUses() { NodeBlock* node_block = FindBlock(); node_block->IncreaseUses(); GlobalHandles* global_handles = node_block->global_handles(); global_handles->isolate()->counters()->global_handles()->Increment(); global_handles->number_of_global_handles_++; } void GlobalHandles::Node::DecreaseBlockUses() { NodeBlock* node_block = FindBlock(); GlobalHandles* global_handles = node_block->global_handles(); parameter_or_next_free_.next_free = global_handles->first_free_; global_handles->first_free_ = this; node_block->DecreaseUses(); global_handles->isolate()->counters()->global_handles()->Decrement(); global_handles->number_of_global_handles_--; } class GlobalHandles::NodeIterator { public: explicit NodeIterator(GlobalHandles* global_handles) : block_(global_handles->first_used_block_), index_(0) {} bool done() const { return block_ == NULL; } Node* node() const { DCHECK(!done()); return block_->node_at(index_); } void Advance() { DCHECK(!done()); if (++index_ < NodeBlock::kSize) return; index_ = 0; block_ = block_->next_used(); } private: NodeBlock* block_; int index_; DISALLOW_COPY_AND_ASSIGN(NodeIterator); }; class GlobalHandles::PendingPhantomCallbacksSecondPassTask : public v8::internal::CancelableTask { public: // Takes ownership of the contents of pending_phantom_callbacks, leaving it in // the same state it would be after a call to Clear(). PendingPhantomCallbacksSecondPassTask( List* pending_phantom_callbacks, Isolate* isolate) : CancelableTask(isolate) { pending_phantom_callbacks_.Swap(pending_phantom_callbacks); } void RunInternal() override { isolate()->heap()->CallGCPrologueCallbacks( GCType::kGCTypeProcessWeakCallbacks, kNoGCCallbackFlags); InvokeSecondPassPhantomCallbacks(&pending_phantom_callbacks_, isolate()); isolate()->heap()->CallGCEpilogueCallbacks( GCType::kGCTypeProcessWeakCallbacks, kNoGCCallbackFlags); } private: List pending_phantom_callbacks_; DISALLOW_COPY_AND_ASSIGN(PendingPhantomCallbacksSecondPassTask); }; GlobalHandles::GlobalHandles(Isolate* isolate) : isolate_(isolate), number_of_global_handles_(0), first_block_(NULL), first_used_block_(NULL), first_free_(NULL), post_gc_processing_count_(0), object_group_connections_(kObjectGroupConnectionsCapacity) {} GlobalHandles::~GlobalHandles() { NodeBlock* block = first_block_; while (block != NULL) { NodeBlock* tmp = block->next(); delete block; block = tmp; } first_block_ = NULL; } Handle GlobalHandles::Create(Object* value) { if (first_free_ == NULL) { first_block_ = new NodeBlock(this, first_block_); first_block_->PutNodesOnFreeList(&first_free_); } DCHECK(first_free_ != NULL); // Take the first node in the free list. Node* result = first_free_; first_free_ = result->next_free(); result->Acquire(value); if (isolate_->heap()->InNewSpace(value) && !result->is_in_new_space_list()) { new_space_nodes_.Add(result); result->set_in_new_space_list(true); } return result->handle(); } Handle GlobalHandles::CopyGlobal(Object** location) { DCHECK(location != NULL); return Node::FromLocation(location)->GetGlobalHandles()->Create(*location); } void GlobalHandles::Destroy(Object** location) { if (location != NULL) Node::FromLocation(location)->Release(); } void GlobalHandles::MakeWeak(Object** location, void* parameter, WeakCallback weak_callback) { Node::FromLocation(location)->MakeWeak(parameter, weak_callback); } typedef v8::WeakCallbackInfo::Callback GenericCallback; void GlobalHandles::MakeWeak(Object** location, void* parameter, GenericCallback phantom_callback, v8::WeakCallbackType type) { Node::FromLocation(location)->MakeWeak(parameter, phantom_callback, type); } void* GlobalHandles::ClearWeakness(Object** location) { return Node::FromLocation(location)->ClearWeakness(); } void GlobalHandles::MarkIndependent(Object** location) { Node::FromLocation(location)->MarkIndependent(); } void GlobalHandles::MarkPartiallyDependent(Object** location) { Node::FromLocation(location)->MarkPartiallyDependent(); } bool GlobalHandles::IsIndependent(Object** location) { return Node::FromLocation(location)->is_independent(); } bool GlobalHandles::IsNearDeath(Object** location) { return Node::FromLocation(location)->IsNearDeath(); } bool GlobalHandles::IsWeak(Object** location) { return Node::FromLocation(location)->IsWeak(); } void GlobalHandles::IterateWeakRoots(ObjectVisitor* v) { for (NodeIterator it(this); !it.done(); it.Advance()) { Node* node = it.node(); if (node->IsWeakRetainer()) { // Pending weak phantom handles die immediately. Everything else survives. if (node->state() == Node::PENDING && node->weakness_type() != NORMAL_WEAK) { node->CollectPhantomCallbackData(isolate(), &pending_phantom_callbacks_); } else { v->VisitPointer(node->location()); } } } } void GlobalHandles::IdentifyWeakHandles(WeakSlotCallback f) { for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsWeak() && f(it.node()->location())) { it.node()->MarkPending(); } } } void GlobalHandles::IterateNewSpaceStrongAndDependentRoots(ObjectVisitor* v) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; if (FLAG_scavenge_reclaim_unmodified_objects) { if (node->IsStrongRetainer() || (node->IsWeakRetainer() && !node->is_independent() && node->is_active())) { v->VisitPointer(node->location()); } } else { if (node->IsStrongRetainer() || (node->IsWeakRetainer() && !node->is_independent() && !node->is_partially_dependent())) { v->VisitPointer(node->location()); } } } } void GlobalHandles::IdentifyNewSpaceWeakIndependentHandles( WeakSlotCallbackWithHeap f) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if ((node->is_independent() || node->is_partially_dependent()) && node->IsWeak() && f(isolate_->heap(), node->location())) { node->MarkPending(); } } } void GlobalHandles::IterateNewSpaceWeakIndependentRoots(ObjectVisitor* v) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if ((node->is_independent() || node->is_partially_dependent()) && node->IsWeakRetainer()) { // Pending weak phantom handles die immediately. Everything else survives. if (node->state() == Node::PENDING && node->weakness_type() != NORMAL_WEAK) { node->CollectPhantomCallbackData(isolate(), &pending_phantom_callbacks_); } else { v->VisitPointer(node->location()); } } } } void GlobalHandles::IdentifyWeakUnmodifiedObjects( WeakSlotCallback is_unmodified) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; if (node->IsWeak() && !is_unmodified(node->location())) { node->set_active(true); } } } void GlobalHandles::MarkNewSpaceWeakUnmodifiedObjectsPending( WeakSlotCallbackWithHeap is_unscavenged) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if ((node->is_independent() || !node->is_active()) && node->IsWeak() && is_unscavenged(isolate_->heap(), node->location())) { node->MarkPending(); } } } void GlobalHandles::IterateNewSpaceWeakUnmodifiedRoots(ObjectVisitor* v) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if ((node->is_independent() || !node->is_active()) && node->IsWeakRetainer()) { // Pending weak phantom handles die immediately. Everything else survives. if (node->state() == Node::PENDING && node->weakness_type() != NORMAL_WEAK) { node->CollectPhantomCallbackData(isolate(), &pending_phantom_callbacks_); } else { v->VisitPointer(node->location()); } } } } bool GlobalHandles::IterateObjectGroups(ObjectVisitor* v, WeakSlotCallbackWithHeap can_skip) { ComputeObjectGroupsAndImplicitReferences(); int last = 0; bool any_group_was_visited = false; for (int i = 0; i < object_groups_.length(); i++) { ObjectGroup* entry = object_groups_.at(i); DCHECK(entry != NULL); Object*** objects = entry->objects; bool group_should_be_visited = false; for (size_t j = 0; j < entry->length; j++) { Object* object = *objects[j]; if (object->IsHeapObject()) { if (!can_skip(isolate_->heap(), &object)) { group_should_be_visited = true; break; } } } if (!group_should_be_visited) { object_groups_[last++] = entry; continue; } // An object in the group requires visiting, so iterate over all // objects in the group. for (size_t j = 0; j < entry->length; ++j) { Object* object = *objects[j]; if (object->IsHeapObject()) { v->VisitPointer(&object); any_group_was_visited = true; } } // Once the entire group has been iterated over, set the object // group to NULL so it won't be processed again. delete entry; object_groups_.at(i) = NULL; } object_groups_.Rewind(last); return any_group_was_visited; } void GlobalHandles::InvokeSecondPassPhantomCallbacks( List* callbacks, Isolate* isolate) { while (callbacks->length() != 0) { auto callback = callbacks->RemoveLast(); DCHECK(callback.node() == nullptr); // No second pass callback required. if (callback.callback() == nullptr) continue; // Fire second pass callback callback.Invoke(isolate); } } int GlobalHandles::PostScavengeProcessing( const int initial_post_gc_processing_count) { int freed_nodes = 0; for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if (!node->IsRetainer()) { // Free nodes do not have weak callbacks. Do not use them to compute // the freed_nodes. continue; } // Skip dependent or unmodified handles. Their weak callbacks might expect // to be // called between two global garbage collection callbacks which // are not called for minor collections. if (FLAG_scavenge_reclaim_unmodified_objects) { if (!node->is_independent() && (node->is_active())) { node->set_active(false); continue; } node->set_active(false); } else { if (!node->is_independent() && !node->is_partially_dependent()) { continue; } node->clear_partially_dependent(); } if (node->PostGarbageCollectionProcessing(isolate_)) { if (initial_post_gc_processing_count != post_gc_processing_count_) { // Weak callback triggered another GC and another round of // PostGarbageCollection processing. The current node might // have been deleted in that round, so we need to bail out (or // restart the processing). return freed_nodes; } } if (!node->IsRetainer()) { freed_nodes++; } } return freed_nodes; } int GlobalHandles::PostMarkSweepProcessing( const int initial_post_gc_processing_count) { int freed_nodes = 0; for (NodeIterator it(this); !it.done(); it.Advance()) { if (!it.node()->IsRetainer()) { // Free nodes do not have weak callbacks. Do not use them to compute // the freed_nodes. continue; } if (FLAG_scavenge_reclaim_unmodified_objects) { it.node()->set_active(false); } else { it.node()->clear_partially_dependent(); } if (it.node()->PostGarbageCollectionProcessing(isolate_)) { if (initial_post_gc_processing_count != post_gc_processing_count_) { // See the comment above. return freed_nodes; } } if (!it.node()->IsRetainer()) { freed_nodes++; } } return freed_nodes; } void GlobalHandles::UpdateListOfNewSpaceNodes() { int last = 0; for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; DCHECK(node->is_in_new_space_list()); if (node->IsRetainer()) { if (isolate_->heap()->InNewSpace(node->object())) { new_space_nodes_[last++] = node; isolate_->heap()->IncrementNodesCopiedInNewSpace(); } else { node->set_in_new_space_list(false); isolate_->heap()->IncrementNodesPromoted(); } } else { node->set_in_new_space_list(false); isolate_->heap()->IncrementNodesDiedInNewSpace(); } } new_space_nodes_.Rewind(last); new_space_nodes_.Trim(); } int GlobalHandles::DispatchPendingPhantomCallbacks( bool synchronous_second_pass) { int freed_nodes = 0; { // The initial pass callbacks must simply clear the nodes. for (auto i = pending_phantom_callbacks_.begin(); i != pending_phantom_callbacks_.end(); ++i) { auto callback = i; // Skip callbacks that have already been processed once. if (callback->node() == nullptr) continue; callback->Invoke(isolate()); freed_nodes++; } } if (pending_phantom_callbacks_.length() > 0) { if (FLAG_optimize_for_size || FLAG_predictable || synchronous_second_pass) { isolate()->heap()->CallGCPrologueCallbacks( GCType::kGCTypeProcessWeakCallbacks, kNoGCCallbackFlags); InvokeSecondPassPhantomCallbacks(&pending_phantom_callbacks_, isolate()); isolate()->heap()->CallGCEpilogueCallbacks( GCType::kGCTypeProcessWeakCallbacks, kNoGCCallbackFlags); } else { auto task = new PendingPhantomCallbacksSecondPassTask( &pending_phantom_callbacks_, isolate()); V8::GetCurrentPlatform()->CallOnForegroundThread( reinterpret_cast(isolate()), task); } } pending_phantom_callbacks_.Clear(); return freed_nodes; } void GlobalHandles::PendingPhantomCallback::Invoke(Isolate* isolate) { Data::Callback* callback_addr = nullptr; if (node_ != nullptr) { // Initialize for first pass callback. DCHECK(node_->state() == Node::NEAR_DEATH); callback_addr = &callback_; } Data data(reinterpret_cast(isolate), parameter_, internal_fields_, callback_addr); Data::Callback callback = callback_; callback_ = nullptr; callback(data); if (node_ != nullptr) { // Transition to second pass state. DCHECK(node_->state() == Node::FREE); node_ = nullptr; } } int GlobalHandles::PostGarbageCollectionProcessing( GarbageCollector collector, const v8::GCCallbackFlags gc_callback_flags) { // Process weak global handle callbacks. This must be done after the // GC is completely done, because the callbacks may invoke arbitrary // API functions. DCHECK(isolate_->heap()->gc_state() == Heap::NOT_IN_GC); const int initial_post_gc_processing_count = ++post_gc_processing_count_; int freed_nodes = 0; bool synchronous_second_pass = (gc_callback_flags & (kGCCallbackFlagForced | kGCCallbackFlagSynchronousPhantomCallbackProcessing)) != 0; freed_nodes += DispatchPendingPhantomCallbacks(synchronous_second_pass); if (initial_post_gc_processing_count != post_gc_processing_count_) { // If the callbacks caused a nested GC, then return. See comment in // PostScavengeProcessing. return freed_nodes; } if (collector == SCAVENGER) { freed_nodes += PostScavengeProcessing(initial_post_gc_processing_count); } else { freed_nodes += PostMarkSweepProcessing(initial_post_gc_processing_count); } if (initial_post_gc_processing_count != post_gc_processing_count_) { // If the callbacks caused a nested GC, then return. See comment in // PostScavengeProcessing. return freed_nodes; } if (initial_post_gc_processing_count == post_gc_processing_count_) { UpdateListOfNewSpaceNodes(); } return freed_nodes; } void GlobalHandles::IterateStrongRoots(ObjectVisitor* v) { for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsStrongRetainer()) { v->VisitPointer(it.node()->location()); } } } void GlobalHandles::IterateAllRoots(ObjectVisitor* v) { for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsRetainer()) { v->VisitPointer(it.node()->location()); } } } void GlobalHandles::IterateAllRootsWithClassIds(ObjectVisitor* v) { for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsRetainer() && it.node()->has_wrapper_class_id()) { v->VisitEmbedderReference(it.node()->location(), it.node()->wrapper_class_id()); } } } void GlobalHandles::IterateAllRootsInNewSpaceWithClassIds(ObjectVisitor* v) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; if (node->IsRetainer() && node->has_wrapper_class_id()) { v->VisitEmbedderReference(node->location(), node->wrapper_class_id()); } } } void GlobalHandles::IterateWeakRootsInNewSpaceWithClassIds(ObjectVisitor* v) { for (int i = 0; i < new_space_nodes_.length(); ++i) { Node* node = new_space_nodes_[i]; if (node->has_wrapper_class_id() && node->IsWeak()) { v->VisitEmbedderReference(node->location(), node->wrapper_class_id()); } } } int GlobalHandles::NumberOfWeakHandles() { int count = 0; for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsWeakRetainer()) { count++; } } return count; } int GlobalHandles::NumberOfGlobalObjectWeakHandles() { int count = 0; for (NodeIterator it(this); !it.done(); it.Advance()) { if (it.node()->IsWeakRetainer() && it.node()->object()->IsJSGlobalObject()) { count++; } } return count; } void GlobalHandles::RecordStats(HeapStats* stats) { *stats->global_handle_count = 0; *stats->weak_global_handle_count = 0; *stats->pending_global_handle_count = 0; *stats->near_death_global_handle_count = 0; *stats->free_global_handle_count = 0; for (NodeIterator it(this); !it.done(); it.Advance()) { *stats->global_handle_count += 1; if (it.node()->state() == Node::WEAK) { *stats->weak_global_handle_count += 1; } else if (it.node()->state() == Node::PENDING) { *stats->pending_global_handle_count += 1; } else if (it.node()->state() == Node::NEAR_DEATH) { *stats->near_death_global_handle_count += 1; } else if (it.node()->state() == Node::FREE) { *stats->free_global_handle_count += 1; } } } #ifdef DEBUG void GlobalHandles::PrintStats() { int total = 0; int weak = 0; int pending = 0; int near_death = 0; int destroyed = 0; for (NodeIterator it(this); !it.done(); it.Advance()) { total++; if (it.node()->state() == Node::WEAK) weak++; if (it.node()->state() == Node::PENDING) pending++; if (it.node()->state() == Node::NEAR_DEATH) near_death++; if (it.node()->state() == Node::FREE) destroyed++; } PrintF("Global Handle Statistics:\n"); PrintF(" allocated memory = %" V8_PTR_PREFIX "dB\n", sizeof(Node) * total); PrintF(" # weak = %d\n", weak); PrintF(" # pending = %d\n", pending); PrintF(" # near_death = %d\n", near_death); PrintF(" # free = %d\n", destroyed); PrintF(" # total = %d\n", total); } void GlobalHandles::Print() { PrintF("Global handles:\n"); for (NodeIterator it(this); !it.done(); it.Advance()) { PrintF(" handle %p to %p%s\n", reinterpret_cast(it.node()->location()), reinterpret_cast(it.node()->object()), it.node()->IsWeak() ? " (weak)" : ""); } } #endif void GlobalHandles::AddObjectGroup(Object*** handles, size_t length, v8::RetainedObjectInfo* info) { #ifdef DEBUG for (size_t i = 0; i < length; ++i) { DCHECK(!Node::FromLocation(handles[i])->is_independent()); } #endif if (length == 0) { if (info != NULL) info->Dispose(); return; } ObjectGroup* group = new ObjectGroup(length); for (size_t i = 0; i < length; ++i) group->objects[i] = handles[i]; group->info = info; object_groups_.Add(group); } void GlobalHandles::SetObjectGroupId(Object** handle, UniqueId id) { object_group_connections_.Add(ObjectGroupConnection(id, handle)); } void GlobalHandles::SetRetainedObjectInfo(UniqueId id, RetainedObjectInfo* info) { retainer_infos_.Add(ObjectGroupRetainerInfo(id, info)); } void GlobalHandles::SetReferenceFromGroup(UniqueId id, Object** child) { DCHECK(!Node::FromLocation(child)->is_independent()); implicit_ref_connections_.Add(ObjectGroupConnection(id, child)); } void GlobalHandles::SetReference(HeapObject** parent, Object** child) { DCHECK(!Node::FromLocation(child)->is_independent()); ImplicitRefGroup* group = new ImplicitRefGroup(parent, 1); group->children[0] = child; implicit_ref_groups_.Add(group); } void GlobalHandles::RemoveObjectGroups() { for (int i = 0; i < object_groups_.length(); i++) delete object_groups_.at(i); object_groups_.Clear(); for (int i = 0; i < retainer_infos_.length(); ++i) retainer_infos_[i].info->Dispose(); retainer_infos_.Clear(); object_group_connections_.Clear(); object_group_connections_.Initialize(kObjectGroupConnectionsCapacity); } void GlobalHandles::RemoveImplicitRefGroups() { for (int i = 0; i < implicit_ref_groups_.length(); i++) { delete implicit_ref_groups_.at(i); } implicit_ref_groups_.Clear(); implicit_ref_connections_.Clear(); } void GlobalHandles::TearDown() { // TODO(1428): invoke weak callbacks. } void GlobalHandles::ComputeObjectGroupsAndImplicitReferences() { if (object_group_connections_.length() == 0) { for (int i = 0; i < retainer_infos_.length(); ++i) retainer_infos_[i].info->Dispose(); retainer_infos_.Clear(); implicit_ref_connections_.Clear(); return; } object_group_connections_.Sort(); retainer_infos_.Sort(); implicit_ref_connections_.Sort(); int info_index = 0; // For iterating retainer_infos_. UniqueId current_group_id(0); int current_group_start = 0; int current_implicit_refs_start = 0; int current_implicit_refs_end = 0; for (int i = 0; i <= object_group_connections_.length(); ++i) { if (i == 0) current_group_id = object_group_connections_[i].id; if (i == object_group_connections_.length() || current_group_id != object_group_connections_[i].id) { // Group detected: objects in indices [current_group_start, i[. // Find out which implicit references are related to this group. (We want // to ignore object groups which only have 1 object, but that object is // needed as a representative object for the implicit refrerence group.) while (current_implicit_refs_start < implicit_ref_connections_.length() && implicit_ref_connections_[current_implicit_refs_start].id < current_group_id) ++current_implicit_refs_start; current_implicit_refs_end = current_implicit_refs_start; while (current_implicit_refs_end < implicit_ref_connections_.length() && implicit_ref_connections_[current_implicit_refs_end].id == current_group_id) ++current_implicit_refs_end; if (current_implicit_refs_end > current_implicit_refs_start) { // Find a representative object for the implicit references. HeapObject** representative = NULL; for (int j = current_group_start; j < i; ++j) { Object** object = object_group_connections_[j].object; if ((*object)->IsHeapObject()) { representative = reinterpret_cast(object); break; } } if (representative) { ImplicitRefGroup* group = new ImplicitRefGroup( representative, current_implicit_refs_end - current_implicit_refs_start); for (int j = current_implicit_refs_start; j < current_implicit_refs_end; ++j) { group->children[j - current_implicit_refs_start] = implicit_ref_connections_[j].object; } implicit_ref_groups_.Add(group); } current_implicit_refs_start = current_implicit_refs_end; } // Find a RetainedObjectInfo for the group. RetainedObjectInfo* info = NULL; while (info_index < retainer_infos_.length() && retainer_infos_[info_index].id < current_group_id) { retainer_infos_[info_index].info->Dispose(); ++info_index; } if (info_index < retainer_infos_.length() && retainer_infos_[info_index].id == current_group_id) { // This object group has an associated ObjectGroupRetainerInfo. info = retainer_infos_[info_index].info; ++info_index; } // Ignore groups which only contain one object. if (i > current_group_start + 1) { ObjectGroup* group = new ObjectGroup(i - current_group_start); for (int j = current_group_start; j < i; ++j) { group->objects[j - current_group_start] = object_group_connections_[j].object; } group->info = info; object_groups_.Add(group); } else if (info) { info->Dispose(); } if (i < object_group_connections_.length()) { current_group_id = object_group_connections_[i].id; current_group_start = i; } } } object_group_connections_.Clear(); object_group_connections_.Initialize(kObjectGroupConnectionsCapacity); retainer_infos_.Clear(); implicit_ref_connections_.Clear(); } EternalHandles::EternalHandles() : size_(0) { for (unsigned i = 0; i < arraysize(singleton_handles_); i++) { singleton_handles_[i] = kInvalidIndex; } } EternalHandles::~EternalHandles() { for (int i = 0; i < blocks_.length(); i++) delete[] blocks_[i]; } void EternalHandles::IterateAllRoots(ObjectVisitor* visitor) { int limit = size_; for (int i = 0; i < blocks_.length(); i++) { DCHECK(limit > 0); Object** block = blocks_[i]; visitor->VisitPointers(block, block + Min(limit, kSize)); limit -= kSize; } } void EternalHandles::IterateNewSpaceRoots(ObjectVisitor* visitor) { for (int i = 0; i < new_space_indices_.length(); i++) { visitor->VisitPointer(GetLocation(new_space_indices_[i])); } } void EternalHandles::PostGarbageCollectionProcessing(Heap* heap) { int last = 0; for (int i = 0; i < new_space_indices_.length(); i++) { int index = new_space_indices_[i]; if (heap->InNewSpace(*GetLocation(index))) { new_space_indices_[last++] = index; } } new_space_indices_.Rewind(last); } void EternalHandles::Create(Isolate* isolate, Object* object, int* index) { DCHECK_EQ(kInvalidIndex, *index); if (object == NULL) return; DCHECK_NE(isolate->heap()->the_hole_value(), object); int block = size_ >> kShift; int offset = size_ & kMask; // need to resize if (offset == 0) { Object** next_block = new Object*[kSize]; Object* the_hole = isolate->heap()->the_hole_value(); MemsetPointer(next_block, the_hole, kSize); blocks_.Add(next_block); } DCHECK_EQ(isolate->heap()->the_hole_value(), blocks_[block][offset]); blocks_[block][offset] = object; if (isolate->heap()->InNewSpace(object)) { new_space_indices_.Add(size_); } *index = size_++; } } // namespace internal } // namespace v8