src/objects/heap-object.h - v8/v8 - Git at Google

 // Copyright 2018 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 V8_OBJECTS_HEAP_OBJECT_H_
 #define V8_OBJECTS_HEAP_OBJECT_H_

 #include "src/globals.h"

 #include "src/objects.h"

 // Has to be the last include (doesn't have include guards):
 #include "src/objects/object-macros.h"

 namespace v8 {
 namespace internal {

 // HeapObject is the superclass for all classes describing heap allocated
 // objects.
 class HeapObject : public Object {
  public:
   bool is_null() const { return ptr() == kNullAddress; }

   // [map]: Contains a map which contains the object's reflective
   // information.
   inline Map map() const;
   inline void set_map(Map value);

   inline MapWordSlot map_slot() const;

   // The no-write-barrier version.  This is OK if the object is white and in
   // new space, or if the value is an immortal immutable object, like the maps
   // of primitive (non-JS) objects like strings, heap numbers etc.
   inline void set_map_no_write_barrier(Map value);

   // Get the map using acquire load.
   inline Map synchronized_map() const;
   inline MapWord synchronized_map_word() const;

   // Set the map using release store
   inline void synchronized_set_map(Map value);
   inline void synchronized_set_map_word(MapWord map_word);

   // Initialize the map immediately after the object is allocated.
   // Do not use this outside Heap.
   inline void set_map_after_allocation(
       Map value, WriteBarrierMode mode = UPDATE_WRITE_BARRIER);

   // During garbage collection, the map word of a heap object does not
   // necessarily contain a map pointer.
   inline MapWord map_word() const;
   inline void set_map_word(MapWord map_word);

   // TODO(v8:7464): Once RO_SPACE is shared between isolates, this method can be
   // removed as ReadOnlyRoots will be accessible from a global variable. For now
   // this method exists to help remove GetIsolate/GetHeap from HeapObject, in a
   // way that doesn't require passing Isolate/Heap down huge call chains or to
   // places where it might not be safe to access it.
   inline ReadOnlyRoots GetReadOnlyRoots() const;

 #define IS_TYPE_FUNCTION_DECL(Type) V8_INLINE bool Is##Type() const;
   HEAP_OBJECT_TYPE_LIST(IS_TYPE_FUNCTION_DECL)
 #undef IS_TYPE_FUNCTION_DECL

   bool IsExternal(Isolate* isolate) const;

 // Oddball checks are faster when they are raw pointer comparisons, so the
 // isolate/read-only roots overloads should be preferred where possible.
 #define IS_TYPE_FUNCTION_DECL(Type, Value)            \
   V8_INLINE bool Is##Type(Isolate* isolate) const;    \
   V8_INLINE bool Is##Type(ReadOnlyRoots roots) const; \
   V8_INLINE bool Is##Type() const;
   ODDBALL_LIST(IS_TYPE_FUNCTION_DECL)
 #undef IS_TYPE_FUNCTION_DECL

   V8_INLINE bool IsNullOrUndefined(Isolate* isolate) const;
   V8_INLINE bool IsNullOrUndefined(ReadOnlyRoots roots) const;
   V8_INLINE bool IsNullOrUndefined() const;

 #define DECL_STRUCT_PREDICATE(NAME, Name, name) V8_INLINE bool Is##Name() const;
   STRUCT_LIST(DECL_STRUCT_PREDICATE)
 #undef DECL_STRUCT_PREDICATE

   // Converts an address to a HeapObject pointer.
   static inline HeapObject FromAddress(Address address);

   // Returns the address of this HeapObject.
   inline Address address() const { return ptr() - kHeapObjectTag; }

   // Iterates over pointers contained in the object (including the Map).
   // If it's not performance critical iteration use the non-templatized
   // version.
   void Iterate(ObjectVisitor* v);

   template <typename ObjectVisitor>
   inline void IterateFast(ObjectVisitor* v);

   // Iterates over all pointers contained in the object except the
   // first map pointer.  The object type is given in the first
   // parameter. This function does not access the map pointer in the
   // object, and so is safe to call while the map pointer is modified.
   // If it's not performance critical iteration use the non-templatized
   // version.
   void IterateBody(ObjectVisitor* v);
   void IterateBody(Map map, int object_size, ObjectVisitor* v);

   template <typename ObjectVisitor>
   inline void IterateBodyFast(ObjectVisitor* v);

   template <typename ObjectVisitor>
   inline void IterateBodyFast(Map map, int object_size, ObjectVisitor* v);

   // Returns true if the object contains a tagged value at given offset.
   // It is used for invalid slots filtering. If the offset points outside
   // of the object or to the map word, the result is UNDEFINED (!!!).
   bool IsValidSlot(Map map, int offset);

   // Returns the heap object's size in bytes
   inline int Size() const;

   // Given a heap object's map pointer, returns the heap size in bytes
   // Useful when the map pointer field is used for other purposes.
   // GC internal.
   V8_EXPORT_PRIVATE int SizeFromMap(Map map) const;

   // Returns the field at offset in obj, as a read/write Object reference.
   // Does no checking, and is safe to use during GC, while maps are invalid.
   // Does not invoke write barrier, so should only be assigned to
   // during marking GC.
   inline ObjectSlot RawField(int byte_offset) const;
   static inline ObjectSlot RawField(const HeapObject obj, int offset);
   inline MaybeObjectSlot RawMaybeWeakField(int byte_offset) const;
   static inline MaybeObjectSlot RawMaybeWeakField(HeapObject obj, int offset);

   DECL_CAST(HeapObject)

   // Return the write barrier mode for this. Callers of this function
   // must be able to present a reference to an DisallowHeapAllocation
   // object as a sign that they are not going to use this function
   // from code that allocates and thus invalidates the returned write
   // barrier mode.
   inline WriteBarrierMode GetWriteBarrierMode(
       const DisallowHeapAllocation& promise);

   // Dispatched behavior.
   void HeapObjectShortPrint(std::ostream& os);  // NOLINT
 #ifdef OBJECT_PRINT
   void PrintHeader(std::ostream& os, const char* id);  // NOLINT
 #endif
   DECL_PRINTER(HeapObject)
   DECL_VERIFIER(HeapObject)
 #ifdef VERIFY_HEAP
   inline void VerifyObjectField(Isolate* isolate, int offset);
   inline void VerifySmiField(int offset);
   inline void VerifyMaybeObjectField(Isolate* isolate, int offset);

   // Verify a pointer is a valid HeapObject pointer that points to object
   // areas in the heap.
   static void VerifyHeapPointer(Isolate* isolate, Object p);
 #endif

   static inline AllocationAlignment RequiredAlignment(Map map);

   // Whether the object needs rehashing. That is the case if the object's
   // content depends on FLAG_hash_seed. When the object is deserialized into
   // a heap with a different hash seed, these objects need to adapt.
   bool NeedsRehashing() const;

   // Rehashing support is not implemented for all objects that need rehashing.
   // With objects that need rehashing but cannot be rehashed, rehashing has to
   // be disabled.
   bool CanBeRehashed() const;

   // Rehash the object based on the layout inferred from its map.
   void RehashBasedOnMap(Isolate* isolate);

   // Layout description.
 #define HEAP_OBJECT_FIELDS(V) \
   V(kMapOffset, kTaggedSize)  \
   /* Header size. */          \
   V(kHeaderSize, 0)

   DEFINE_FIELD_OFFSET_CONSTANTS(Object::kHeaderSize, HEAP_OBJECT_FIELDS)
 #undef HEAP_OBJECT_FIELDS

   STATIC_ASSERT(kMapOffset == Internals::kHeapObjectMapOffset);

   inline Address GetFieldAddress(int field_offset) const;

  protected:
   // Special-purpose constructor for subclasses that have fast paths where
   // their ptr() is a Smi.
   enum class AllowInlineSmiStorage { kRequireHeapObjectTag, kAllowBeingASmi };
   inline HeapObject(Address ptr, AllowInlineSmiStorage allow_smi);

   OBJECT_CONSTRUCTORS(HeapObject, Object);
 };

 // Helper class for objects that can never be in RO space.
 class NeverReadOnlySpaceObject {
  public:
   // The Heap the object was allocated in. Used also to access Isolate.
   static inline Heap* GetHeap(const HeapObject object);

   // Convenience method to get current isolate.
   static inline Isolate* GetIsolate(const HeapObject object);
 };

 }  // namespace internal
 }  // namespace v8

 #include "src/objects/object-macros-undef.h"

 #endif  // V8_OBJECTS_HEAP_OBJECT_H_
	// Copyright 2018 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 V8_OBJECTS_HEAP_OBJECT_H_
	#define V8_OBJECTS_HEAP_OBJECT_H_

	#include "src/globals.h"

	#include "src/objects.h"

	// Has to be the last include (doesn't have include guards):
	#include "src/objects/object-macros.h"

	namespace v8 {
	namespace internal {

	// HeapObject is the superclass for all classes describing heap allocated
	// objects.
	class HeapObject : public Object {
	public:
	bool is_null() const { return ptr() == kNullAddress; }

	// [map]: Contains a map which contains the object's reflective
	// information.
	inline Map map() const;
	inline void set_map(Map value);

	inline MapWordSlot map_slot() const;

	// The no-write-barrier version. This is OK if the object is white and in
	// new space, or if the value is an immortal immutable object, like the maps
	// of primitive (non-JS) objects like strings, heap numbers etc.
	inline void set_map_no_write_barrier(Map value);

	// Get the map using acquire load.
	inline Map synchronized_map() const;
	inline MapWord synchronized_map_word() const;

	// Set the map using release store
	inline void synchronized_set_map(Map value);
	inline void synchronized_set_map_word(MapWord map_word);

	// Initialize the map immediately after the object is allocated.
	// Do not use this outside Heap.
	inline void set_map_after_allocation(
	Map value, WriteBarrierMode mode = UPDATE_WRITE_BARRIER);

	// During garbage collection, the map word of a heap object does not
	// necessarily contain a map pointer.
	inline MapWord map_word() const;
	inline void set_map_word(MapWord map_word);

	// TODO(v8:7464): Once RO_SPACE is shared between isolates, this method can be
	// removed as ReadOnlyRoots will be accessible from a global variable. For now
	// this method exists to help remove GetIsolate/GetHeap from HeapObject, in a
	// way that doesn't require passing Isolate/Heap down huge call chains or to
	// places where it might not be safe to access it.
	inline ReadOnlyRoots GetReadOnlyRoots() const;

	#define IS_TYPE_FUNCTION_DECL(Type) V8_INLINE bool Is##Type() const;
	HEAP_OBJECT_TYPE_LIST(IS_TYPE_FUNCTION_DECL)
	#undef IS_TYPE_FUNCTION_DECL

	bool IsExternal(Isolate* isolate) const;

	// Oddball checks are faster when they are raw pointer comparisons, so the
	// isolate/read-only roots overloads should be preferred where possible.
	#define IS_TYPE_FUNCTION_DECL(Type, Value) \
	V8_INLINE bool Is##Type(Isolate* isolate) const; \
	V8_INLINE bool Is##Type(ReadOnlyRoots roots) const; \
	V8_INLINE bool Is##Type() const;
	ODDBALL_LIST(IS_TYPE_FUNCTION_DECL)
	#undef IS_TYPE_FUNCTION_DECL

	V8_INLINE bool IsNullOrUndefined(Isolate* isolate) const;
	V8_INLINE bool IsNullOrUndefined(ReadOnlyRoots roots) const;
	V8_INLINE bool IsNullOrUndefined() const;

	#define DECL_STRUCT_PREDICATE(NAME, Name, name) V8_INLINE bool Is##Name() const;
	STRUCT_LIST(DECL_STRUCT_PREDICATE)
	#undef DECL_STRUCT_PREDICATE

	// Converts an address to a HeapObject pointer.
	static inline HeapObject FromAddress(Address address);

	// Returns the address of this HeapObject.
	inline Address address() const { return ptr() - kHeapObjectTag; }

	// Iterates over pointers contained in the object (including the Map).
	// If it's not performance critical iteration use the non-templatized
	// version.
	void Iterate(ObjectVisitor* v);

	template <typename ObjectVisitor>
	inline void IterateFast(ObjectVisitor* v);

	// Iterates over all pointers contained in the object except the
	// first map pointer. The object type is given in the first
	// parameter. This function does not access the map pointer in the
	// object, and so is safe to call while the map pointer is modified.
	// If it's not performance critical iteration use the non-templatized
	// version.
	void IterateBody(ObjectVisitor* v);
	void IterateBody(Map map, int object_size, ObjectVisitor* v);

	template <typename ObjectVisitor>
	inline void IterateBodyFast(ObjectVisitor* v);

	template <typename ObjectVisitor>
	inline void IterateBodyFast(Map map, int object_size, ObjectVisitor* v);

	// Returns true if the object contains a tagged value at given offset.
	// It is used for invalid slots filtering. If the offset points outside
	// of the object or to the map word, the result is UNDEFINED (!!!).
	bool IsValidSlot(Map map, int offset);

	// Returns the heap object's size in bytes
	inline int Size() const;

	// Given a heap object's map pointer, returns the heap size in bytes
	// Useful when the map pointer field is used for other purposes.
	// GC internal.
	V8_EXPORT_PRIVATE int SizeFromMap(Map map) const;

	// Returns the field at offset in obj, as a read/write Object reference.
	// Does no checking, and is safe to use during GC, while maps are invalid.
	// Does not invoke write barrier, so should only be assigned to
	// during marking GC.
	inline ObjectSlot RawField(int byte_offset) const;
	static inline ObjectSlot RawField(const HeapObject obj, int offset);
	inline MaybeObjectSlot RawMaybeWeakField(int byte_offset) const;
	static inline MaybeObjectSlot RawMaybeWeakField(HeapObject obj, int offset);

	DECL_CAST(HeapObject)

	// Return the write barrier mode for this. Callers of this function
	// must be able to present a reference to an DisallowHeapAllocation
	// object as a sign that they are not going to use this function
	// from code that allocates and thus invalidates the returned write
	// barrier mode.
	inline WriteBarrierMode GetWriteBarrierMode(
	const DisallowHeapAllocation& promise);

	// Dispatched behavior.
	void HeapObjectShortPrint(std::ostream& os); // NOLINT
	#ifdef OBJECT_PRINT
	void PrintHeader(std::ostream& os, const char* id); // NOLINT
	#endif
	DECL_PRINTER(HeapObject)
	DECL_VERIFIER(HeapObject)
	#ifdef VERIFY_HEAP
	inline void VerifyObjectField(Isolate* isolate, int offset);
	inline void VerifySmiField(int offset);
	inline void VerifyMaybeObjectField(Isolate* isolate, int offset);

	// Verify a pointer is a valid HeapObject pointer that points to object
	// areas in the heap.
	static void VerifyHeapPointer(Isolate* isolate, Object p);
	#endif

	static inline AllocationAlignment RequiredAlignment(Map map);

	// Whether the object needs rehashing. That is the case if the object's
	// content depends on FLAG_hash_seed. When the object is deserialized into
	// a heap with a different hash seed, these objects need to adapt.
	bool NeedsRehashing() const;

	// Rehashing support is not implemented for all objects that need rehashing.
	// With objects that need rehashing but cannot be rehashed, rehashing has to
	// be disabled.
	bool CanBeRehashed() const;

	// Rehash the object based on the layout inferred from its map.
	void RehashBasedOnMap(Isolate* isolate);

	// Layout description.
	#define HEAP_OBJECT_FIELDS(V) \
	V(kMapOffset, kTaggedSize) \
	/* Header size. */ \
	V(kHeaderSize, 0)

	DEFINE_FIELD_OFFSET_CONSTANTS(Object::kHeaderSize, HEAP_OBJECT_FIELDS)
	#undef HEAP_OBJECT_FIELDS

	STATIC_ASSERT(kMapOffset == Internals::kHeapObjectMapOffset);

	inline Address GetFieldAddress(int field_offset) const;

	protected:
	// Special-purpose constructor for subclasses that have fast paths where
	// their ptr() is a Smi.
	enum class AllowInlineSmiStorage { kRequireHeapObjectTag, kAllowBeingASmi };
	inline HeapObject(Address ptr, AllowInlineSmiStorage allow_smi);

	OBJECT_CONSTRUCTORS(HeapObject, Object);
	};

	// Helper class for objects that can never be in RO space.
	class NeverReadOnlySpaceObject {
	public:
	// The Heap the object was allocated in. Used also to access Isolate.
	static inline Heap* GetHeap(const HeapObject object);

	// Convenience method to get current isolate.
	static inline Isolate* GetIsolate(const HeapObject object);
	};

	} // namespace internal
	} // namespace v8

	#include "src/objects/object-macros-undef.h"

	#endif // V8_OBJECTS_HEAP_OBJECT_H_