src/heap/objects-visiting.cc - v8/v8 - Git at Google

 // Copyright 2011 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/objects-visiting.h"

 #include "src/heap/heap-inl.h"
 #include "src/heap/mark-compact-inl.h"
 #include "src/heap/objects-visiting-inl.h"

 namespace v8 {
 namespace internal {

 // We don't record weak slots during marking or scavenges. Instead we do it
 // once when we complete mark-compact cycle.  Note that write barrier has no
 // effect if we are already in the middle of compacting mark-sweep cycle and we
 // have to record slots manually.
 static bool MustRecordSlots(Heap* heap) {
   return heap->gc_state() == Heap::MARK_COMPACT &&
          heap->mark_compact_collector()->is_compacting();
 }


 template <class T>
 struct WeakListVisitor;

 template <class T>
 Object* VisitWeakList(Heap* heap, Object* list, WeakObjectRetainer* retainer) {
   Object* undefined = ReadOnlyRoots(heap).undefined_value();
   Object* head = undefined;
   T* tail = nullptr;
   bool record_slots = MustRecordSlots(heap);

   while (list != undefined) {
     // Check whether to keep the candidate in the list.
     T* candidate = reinterpret_cast<T*>(list);

     Object* retained = retainer->RetainAs(list);

     // Move to the next element before the WeakNext is cleared.
     list = WeakListVisitor<T>::WeakNext(candidate);

     if (retained != nullptr) {
       if (head == undefined) {
         // First element in the list.
         head = retained;
       } else {
         // Subsequent elements in the list.
         DCHECK_NOT_NULL(tail);
         WeakListVisitor<T>::SetWeakNext(tail, retained);
         if (record_slots) {
           HeapObject* slot_holder = WeakListVisitor<T>::WeakNextHolder(tail);
           int slot_offset = WeakListVisitor<T>::WeakNextOffset();
           ObjectSlot slot = HeapObject::RawField(slot_holder, slot_offset);
           MarkCompactCollector::RecordSlot(slot_holder, slot,
                                            HeapObject::cast(retained));
         }
       }
       // Retained object is new tail.
       DCHECK(!retained->IsUndefined(heap->isolate()));
       candidate = reinterpret_cast<T*>(retained);
       tail = candidate;

       // tail is a live object, visit it.
       WeakListVisitor<T>::VisitLiveObject(heap, tail, retainer);

     } else {
       WeakListVisitor<T>::VisitPhantomObject(heap, candidate);
     }
   }

   // Terminate the list if there is one or more elements.
   if (tail != nullptr) WeakListVisitor<T>::SetWeakNext(tail, undefined);
   return head;
 }

 // TODO(3770): Replacement for the above, temporarily separate to allow
 // incremental transition. Assumes that T derives from ObjectPtr.
 template <class T>
 Object* VisitWeakList2(Heap* heap, Object* list, WeakObjectRetainer* retainer) {
   Object* undefined = ReadOnlyRoots(heap).undefined_value();
   Object* head = undefined;
   T tail;
   bool record_slots = MustRecordSlots(heap);

   while (list != undefined) {
     // Check whether to keep the candidate in the list.
     T candidate = T::cast(list);

     Object* retained = retainer->RetainAs(list);

     // Move to the next element before the WeakNext is cleared.
     list = WeakListVisitor<T>::WeakNext(candidate);

     if (retained != nullptr) {
       if (head == undefined) {
         // First element in the list.
         head = retained;
       } else {
         // Subsequent elements in the list.
         DCHECK(tail);
         WeakListVisitor<T>::SetWeakNext(tail, retained);
         if (record_slots) {
           HeapObject* slot_holder = WeakListVisitor<T>::WeakNextHolder(tail);
           int slot_offset = WeakListVisitor<T>::WeakNextOffset();
           ObjectSlot slot = HeapObject::RawField(slot_holder, slot_offset);
           MarkCompactCollector::RecordSlot(slot_holder, slot,
                                            HeapObject::cast(retained));
         }
       }
       // Retained object is new tail.
       DCHECK(!retained->IsUndefined(heap->isolate()));
       candidate = T::cast(retained);
       tail = candidate;

       // tail is a live object, visit it.
       WeakListVisitor<T>::VisitLiveObject(heap, tail, retainer);

     } else {
       WeakListVisitor<T>::VisitPhantomObject(heap, candidate);
     }
   }

   // Terminate the list if there is one or more elements.
   if (!tail.is_null()) WeakListVisitor<T>::SetWeakNext(tail, undefined);
   return head;
 }

 template <class T>
 static void ClearWeakList(Heap* heap, Object* list) {
   Object* undefined = ReadOnlyRoots(heap).undefined_value();
   while (list != undefined) {
     T candidate = T::cast(list);
     list = WeakListVisitor<T>::WeakNext(candidate);
     WeakListVisitor<T>::SetWeakNext(candidate, undefined);
   }
 }

 template <>
 struct WeakListVisitor<Code> {
   static void SetWeakNext(Code code, Object* next) {
     code->code_data_container()->set_next_code_link(next,
                                                     UPDATE_WEAK_WRITE_BARRIER);
   }

   static Object* WeakNext(Code code) {
     return code->code_data_container()->next_code_link();
   }

   static HeapObject* WeakNextHolder(Code code) {
     return code->code_data_container();
   }

   static int WeakNextOffset() { return CodeDataContainer::kNextCodeLinkOffset; }

   static void VisitLiveObject(Heap*, Code, WeakObjectRetainer*) {}

   static void VisitPhantomObject(Heap* heap, Code code) {
     // Even though the code is dying, its code_data_container can still be
     // alive. Clear the next_code_link slot to avoid a dangling pointer.
     SetWeakNext(code, ReadOnlyRoots(heap).undefined_value());
   }
 };


 template <>
 struct WeakListVisitor<Context> {
   static void SetWeakNext(Context* context, Object* next) {
     context->set(Context::NEXT_CONTEXT_LINK, next, UPDATE_WEAK_WRITE_BARRIER);
   }

   static Object* WeakNext(Context* context) {
     return context->next_context_link();
   }

   static HeapObject* WeakNextHolder(Context* context) { return context; }

   static int WeakNextOffset() {
     return FixedArray::SizeFor(Context::NEXT_CONTEXT_LINK);
   }

   static void VisitLiveObject(Heap* heap, Context* context,
                               WeakObjectRetainer* retainer) {
     if (heap->gc_state() == Heap::MARK_COMPACT) {
       // Record the slots of the weak entries in the native context.
       for (int idx = Context::FIRST_WEAK_SLOT;
            idx < Context::NATIVE_CONTEXT_SLOTS; ++idx) {
         ObjectSlot slot = Context::cast(context)->RawFieldOfElementAt(idx);
         MarkCompactCollector::RecordSlot(context, slot,
                                          HeapObject::cast(*slot));
       }
       // Code objects are always allocated in Code space, we do not have to
       // visit them during scavenges.
       DoWeakList<Code>(heap, context, retainer, Context::OPTIMIZED_CODE_LIST);
       DoWeakList<Code>(heap, context, retainer, Context::DEOPTIMIZED_CODE_LIST);
     }
   }

   template <class T>
   static void DoWeakList(Heap* heap, Context* context,
                          WeakObjectRetainer* retainer, int index) {
     // Visit the weak list, removing dead intermediate elements.
     Object* list_head = VisitWeakList2<T>(heap, context->get(index), retainer);

     // Update the list head.
     context->set(index, list_head, UPDATE_WRITE_BARRIER);

     if (MustRecordSlots(heap)) {
       // Record the updated slot if necessary.
       ObjectSlot head_slot =
           HeapObject::RawField(context, FixedArray::SizeFor(index));
       heap->mark_compact_collector()->RecordSlot(context, head_slot,
                                                  HeapObject::cast(list_head));
     }
   }

   static void VisitPhantomObject(Heap* heap, Context* context) {
     ClearWeakList<Code>(heap, context->get(Context::OPTIMIZED_CODE_LIST));
     ClearWeakList<Code>(heap, context->get(Context::DEOPTIMIZED_CODE_LIST));
   }
 };


 template <>
 struct WeakListVisitor<AllocationSite> {
   static void SetWeakNext(AllocationSite* obj, Object* next) {
     obj->set_weak_next(next, UPDATE_WEAK_WRITE_BARRIER);
   }

   static Object* WeakNext(AllocationSite* obj) { return obj->weak_next(); }

   static HeapObject* WeakNextHolder(AllocationSite* obj) { return obj; }

   static int WeakNextOffset() { return AllocationSite::kWeakNextOffset; }

   static void VisitLiveObject(Heap*, AllocationSite*, WeakObjectRetainer*) {}

   static void VisitPhantomObject(Heap*, AllocationSite*) {}
 };


 template Object* VisitWeakList<Context>(Heap* heap, Object* list,
                                         WeakObjectRetainer* retainer);

 template Object* VisitWeakList<AllocationSite>(Heap* heap, Object* list,
                                                WeakObjectRetainer* retainer);
 }  // namespace internal
 }  // namespace v8
	// Copyright 2011 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/objects-visiting.h"

	#include "src/heap/heap-inl.h"
	#include "src/heap/mark-compact-inl.h"
	#include "src/heap/objects-visiting-inl.h"

	namespace v8 {
	namespace internal {

	// We don't record weak slots during marking or scavenges. Instead we do it
	// once when we complete mark-compact cycle. Note that write barrier has no
	// effect if we are already in the middle of compacting mark-sweep cycle and we
	// have to record slots manually.
	static bool MustRecordSlots(Heap* heap) {
	return heap->gc_state() == Heap::MARK_COMPACT &&
	heap->mark_compact_collector()->is_compacting();
	}


	template <class T>
	struct WeakListVisitor;

	template <class T>
	Object* VisitWeakList(Heap* heap, Object* list, WeakObjectRetainer* retainer) {
	Object* undefined = ReadOnlyRoots(heap).undefined_value();
	Object* head = undefined;
	T* tail = nullptr;
	bool record_slots = MustRecordSlots(heap);

	while (list != undefined) {
	// Check whether to keep the candidate in the list.
	T* candidate = reinterpret_cast<T*>(list);

	Object* retained = retainer->RetainAs(list);

	// Move to the next element before the WeakNext is cleared.
	list = WeakListVisitor<T>::WeakNext(candidate);

	if (retained != nullptr) {
	if (head == undefined) {
	// First element in the list.
	head = retained;
	} else {
	// Subsequent elements in the list.
	DCHECK_NOT_NULL(tail);
	WeakListVisitor<T>::SetWeakNext(tail, retained);
	if (record_slots) {
	HeapObject* slot_holder = WeakListVisitor<T>::WeakNextHolder(tail);
	int slot_offset = WeakListVisitor<T>::WeakNextOffset();
	ObjectSlot slot = HeapObject::RawField(slot_holder, slot_offset);
	MarkCompactCollector::RecordSlot(slot_holder, slot,
	HeapObject::cast(retained));
	}
	}
	// Retained object is new tail.
	DCHECK(!retained->IsUndefined(heap->isolate()));
	candidate = reinterpret_cast<T*>(retained);
	tail = candidate;

	// tail is a live object, visit it.
	WeakListVisitor<T>::VisitLiveObject(heap, tail, retainer);

	} else {
	WeakListVisitor<T>::VisitPhantomObject(heap, candidate);
	}
	}

	// Terminate the list if there is one or more elements.
	if (tail != nullptr) WeakListVisitor<T>::SetWeakNext(tail, undefined);
	return head;
	}

	// TODO(3770): Replacement for the above, temporarily separate to allow
	// incremental transition. Assumes that T derives from ObjectPtr.
	template <class T>
	Object* VisitWeakList2(Heap* heap, Object* list, WeakObjectRetainer* retainer) {
	Object* undefined = ReadOnlyRoots(heap).undefined_value();
	Object* head = undefined;
	T tail;
	bool record_slots = MustRecordSlots(heap);

	while (list != undefined) {
	// Check whether to keep the candidate in the list.
	T candidate = T::cast(list);

	Object* retained = retainer->RetainAs(list);

	// Move to the next element before the WeakNext is cleared.
	list = WeakListVisitor<T>::WeakNext(candidate);

	if (retained != nullptr) {
	if (head == undefined) {
	// First element in the list.
	head = retained;
	} else {
	// Subsequent elements in the list.
	DCHECK(tail);
	WeakListVisitor<T>::SetWeakNext(tail, retained);
	if (record_slots) {
	HeapObject* slot_holder = WeakListVisitor<T>::WeakNextHolder(tail);
	int slot_offset = WeakListVisitor<T>::WeakNextOffset();
	ObjectSlot slot = HeapObject::RawField(slot_holder, slot_offset);
	MarkCompactCollector::RecordSlot(slot_holder, slot,
	HeapObject::cast(retained));
	}
	}
	// Retained object is new tail.
	DCHECK(!retained->IsUndefined(heap->isolate()));
	candidate = T::cast(retained);
	tail = candidate;

	// tail is a live object, visit it.
	WeakListVisitor<T>::VisitLiveObject(heap, tail, retainer);

	} else {
	WeakListVisitor<T>::VisitPhantomObject(heap, candidate);
	}
	}

	// Terminate the list if there is one or more elements.
	if (!tail.is_null()) WeakListVisitor<T>::SetWeakNext(tail, undefined);
	return head;
	}

	template <class T>
	static void ClearWeakList(Heap* heap, Object* list) {
	Object* undefined = ReadOnlyRoots(heap).undefined_value();
	while (list != undefined) {
	T candidate = T::cast(list);
	list = WeakListVisitor<T>::WeakNext(candidate);
	WeakListVisitor<T>::SetWeakNext(candidate, undefined);
	}
	}

	template <>
	struct WeakListVisitor<Code> {
	static void SetWeakNext(Code code, Object* next) {
	code->code_data_container()->set_next_code_link(next,
	UPDATE_WEAK_WRITE_BARRIER);
	}

	static Object* WeakNext(Code code) {
	return code->code_data_container()->next_code_link();
	}

	static HeapObject* WeakNextHolder(Code code) {
	return code->code_data_container();
	}

	static int WeakNextOffset() { return CodeDataContainer::kNextCodeLinkOffset; }

	static void VisitLiveObject(Heap, Code, WeakObjectRetainer) {}

	static void VisitPhantomObject(Heap* heap, Code code) {
	// Even though the code is dying, its code_data_container can still be
	// alive. Clear the next_code_link slot to avoid a dangling pointer.
	SetWeakNext(code, ReadOnlyRoots(heap).undefined_value());
	}
	};


	template <>
	struct WeakListVisitor<Context> {
	static void SetWeakNext(Context* context, Object* next) {
	context->set(Context::NEXT_CONTEXT_LINK, next, UPDATE_WEAK_WRITE_BARRIER);
	}

	static Object* WeakNext(Context* context) {
	return context->next_context_link();
	}

	static HeapObject* WeakNextHolder(Context* context) { return context; }

	static int WeakNextOffset() {
	return FixedArray::SizeFor(Context::NEXT_CONTEXT_LINK);
	}

	static void VisitLiveObject(Heap* heap, Context* context,
	WeakObjectRetainer* retainer) {
	if (heap->gc_state() == Heap::MARK_COMPACT) {
	// Record the slots of the weak entries in the native context.
	for (int idx = Context::FIRST_WEAK_SLOT;
	idx < Context::NATIVE_CONTEXT_SLOTS; ++idx) {
	ObjectSlot slot = Context::cast(context)->RawFieldOfElementAt(idx);
	MarkCompactCollector::RecordSlot(context, slot,
	HeapObject::cast(*slot));
	}
	// Code objects are always allocated in Code space, we do not have to
	// visit them during scavenges.
	DoWeakList<Code>(heap, context, retainer, Context::OPTIMIZED_CODE_LIST);
	DoWeakList<Code>(heap, context, retainer, Context::DEOPTIMIZED_CODE_LIST);
	}
	}

	template <class T>
	static void DoWeakList(Heap* heap, Context* context,
	WeakObjectRetainer* retainer, int index) {
	// Visit the weak list, removing dead intermediate elements.
	Object* list_head = VisitWeakList2<T>(heap, context->get(index), retainer);

	// Update the list head.
	context->set(index, list_head, UPDATE_WRITE_BARRIER);

	if (MustRecordSlots(heap)) {
	// Record the updated slot if necessary.
	ObjectSlot head_slot =
	HeapObject::RawField(context, FixedArray::SizeFor(index));
	heap->mark_compact_collector()->RecordSlot(context, head_slot,
	HeapObject::cast(list_head));
	}
	}

	static void VisitPhantomObject(Heap* heap, Context* context) {
	ClearWeakList<Code>(heap, context->get(Context::OPTIMIZED_CODE_LIST));
	ClearWeakList<Code>(heap, context->get(Context::DEOPTIMIZED_CODE_LIST));
	}
	};


	template <>
	struct WeakListVisitor<AllocationSite> {
	static void SetWeakNext(AllocationSite* obj, Object* next) {
	obj->set_weak_next(next, UPDATE_WEAK_WRITE_BARRIER);
	}

	static Object* WeakNext(AllocationSite* obj) { return obj->weak_next(); }

	static HeapObject* WeakNextHolder(AllocationSite* obj) { return obj; }

	static int WeakNextOffset() { return AllocationSite::kWeakNextOffset; }

	static void VisitLiveObject(Heap, AllocationSite, WeakObjectRetainer*) {}

	static void VisitPhantomObject(Heap, AllocationSite) {}
	};


	template Object* VisitWeakList<Context>(Heap* heap, Object* list,
	WeakObjectRetainer* retainer);

	template Object* VisitWeakList<AllocationSite>(Heap* heap, Object* list,
	WeakObjectRetainer* retainer);
	} // namespace internal
	} // namespace v8