src/ic/ic.h - v8/v8 - Git at Google

 // Copyright 2012 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_IC_H_
 #define V8_IC_H_

 #include "src/ic/ic-state.h"
 #include "src/macro-assembler.h"
 #include "src/messages.h"

 namespace v8 {
 namespace internal {

 //
 // IC is the base class for LoadIC, StoreIC, KeyedLoadIC, and KeyedStoreIC.
 //
 class IC {
  public:
   // Alias the inline cache state type to make the IC code more readable.
   typedef InlineCacheState State;

   // The IC code is either invoked with no extra frames on the stack
   // or with a single extra frame for supporting calls.
   enum FrameDepth { NO_EXTRA_FRAME = 0, EXTRA_CALL_FRAME = 1 };

   // Construct the IC structure with the given number of extra
   // JavaScript frames on the stack.
   IC(FrameDepth depth, Isolate* isolate, FeedbackNexus* nexus = NULL);
   virtual ~IC() {}

   State state() const { return state_; }
   inline Address address() const;

   // Compute the current IC state based on the target stub, receiver and name.
   void UpdateState(Handle<Object> receiver, Handle<Object> name);

   bool RecomputeHandlerForName(Handle<Object> name);
   void MarkRecomputeHandler(Handle<Object> name) {
     DCHECK(RecomputeHandlerForName(name));
     old_state_ = state_;
     state_ = RECOMPUTE_HANDLER;
   }

   // Clear the inline cache to initial state.
   static void Clear(Isolate* isolate, Address address, Address constant_pool);

   bool IsAnyLoad() const {
     return IsLoadIC() || IsLoadGlobalIC() || IsKeyedLoadIC();
   }
   bool IsAnyStore() const {
     return IsStoreIC() || IsStoreOwnIC() || IsKeyedStoreIC();
   }

   static inline Handle<Map> GetHandlerCacheHolder(Handle<Map> receiver_map,
                                                   bool receiver_is_holder,
                                                   Isolate* isolate,
                                                   CacheHolderFlag* flag);
   static inline Handle<Map> GetICCacheHolder(Handle<Map> receiver_map,
                                              Isolate* isolate,
                                              CacheHolderFlag* flag);

   static bool ICUseVector(Code::Kind kind) {
     return kind == Code::LOAD_IC || kind == Code::LOAD_GLOBAL_IC ||
            kind == Code::KEYED_LOAD_IC || kind == Code::STORE_IC ||
            kind == Code::KEYED_STORE_IC;
   }
   static bool ICUseVector(FeedbackSlotKind kind) {
     return IsLoadICKind(kind) || IsLoadGlobalICKind(kind) ||
            IsKeyedLoadICKind(kind) || IsStoreICKind(kind) ||
            IsStoreOwnICKind(kind) || IsKeyedStoreICKind(kind);
   }

   // The ICs that don't pass slot and vector through the stack have to
   // save/restore them in the dispatcher.
   static bool ShouldPushPopSlotAndVector(Code::Kind kind);

   static InlineCacheState StateFromCode(Code* code);

   static inline bool IsHandler(Object* object);

   // Nofity the IC system that a feedback has changed.
   static void OnFeedbackChanged(Isolate* isolate, JSFunction* host_function);

  protected:
   Address fp() const { return fp_; }
   Address pc() const { return *pc_address_; }
   Isolate* isolate() const { return isolate_; }

   // Get the caller function object.
   JSFunction* GetHostFunction() const;

   inline bool AddressIsDeoptimizedCode() const;
   inline static bool AddressIsDeoptimizedCode(Isolate* isolate,
                                               Address address);

   // Set the call-site target.
   inline void set_target(Code* code);
   bool is_vector_set() { return vector_set_; }

   bool UseVector() const {
     bool use = ICUseVector(kind());
     // If we are supposed to use the nexus, verify the nexus is non-null.
     DCHECK(!use || nexus_ != nullptr);
     return use;
   }

   // Configure for most states.
   void ConfigureVectorState(IC::State new_state, Handle<Object> key);
   // Configure the vector for MONOMORPHIC.
   void ConfigureVectorState(Handle<Name> name, Handle<Map> map,
                             Handle<Object> handler);
   // Configure the vector for POLYMORPHIC.
   void ConfigureVectorState(Handle<Name> name, MapHandleList* maps,
                             List<Handle<Object>>* handlers);
   // Configure the vector for POLYMORPHIC with transitions (only for element
   // keyed stores).
   void ConfigureVectorState(MapHandleList* maps,
                             MapHandleList* transitioned_maps,
                             List<Handle<Object>>* handlers);

   char TransitionMarkFromState(IC::State state);
   void TraceIC(const char* type, Handle<Object> name);
   void TraceIC(const char* type, Handle<Object> name, State old_state,
                State new_state);

   MaybeHandle<Object> TypeError(MessageTemplate::Template,
                                 Handle<Object> object, Handle<Object> key);
   MaybeHandle<Object> ReferenceError(Handle<Name> name);

   // Access the target code for the given IC address.
   static inline Code* GetTargetAtAddress(Address address,
                                          Address constant_pool);
   static inline void SetTargetAtAddress(Address address, Code* target,
                                         Address constant_pool);
   static void PostPatching(Address address, Code* target, Code* old_target);

   void TraceHandlerCacheHitStats(LookupIterator* lookup);

   // Compute the handler either by compiling or by retrieving a cached version.
   Handle<Object> ComputeHandler(LookupIterator* lookup,
                                 Handle<Object> value = Handle<Code>::null());
   virtual Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) {
     UNREACHABLE();
     return Handle<Code>::null();
   }
   virtual Handle<Object> CompileHandler(LookupIterator* lookup,
                                         Handle<Object> value,
                                         CacheHolderFlag cache_holder) {
     UNREACHABLE();
     return Handle<Object>::null();
   }

   void UpdateMonomorphicIC(Handle<Object> handler, Handle<Name> name);
   bool UpdatePolymorphicIC(Handle<Name> name, Handle<Object> code);
   void UpdateMegamorphicCache(Map* map, Name* name, Object* code);

   StubCache* stub_cache();

   void CopyICToMegamorphicCache(Handle<Name> name);
   bool IsTransitionOfMonomorphicTarget(Map* source_map, Map* target_map);
   void PatchCache(Handle<Name> name, Handle<Object> code);
   FeedbackSlotKind kind() const { return kind_; }
   bool IsLoadIC() const { return IsLoadICKind(kind_); }
   bool IsLoadGlobalIC() const { return IsLoadGlobalICKind(kind_); }
   bool IsKeyedLoadIC() const { return IsKeyedLoadICKind(kind_); }
   bool IsStoreIC() const { return IsStoreICKind(kind_); }
   bool IsStoreOwnIC() const { return IsStoreOwnICKind(kind_); }
   bool IsKeyedStoreIC() const { return IsKeyedStoreICKind(kind_); }
   bool is_keyed() const { return IsKeyedLoadIC() || IsKeyedStoreIC(); }
   Code::Kind handler_kind() const {
     if (IsAnyLoad()) return Code::LOAD_IC;
     DCHECK(IsAnyStore());
     return Code::STORE_IC;
   }
   bool ShouldRecomputeHandler(Handle<String> name);

   ExtraICState extra_ic_state() const { return extra_ic_state_; }

   Handle<Map> receiver_map() { return receiver_map_; }
   void update_receiver_map(Handle<Object> receiver) {
     if (receiver->IsSmi()) {
       receiver_map_ = isolate_->factory()->heap_number_map();
     } else {
       receiver_map_ = handle(HeapObject::cast(*receiver)->map());
     }
   }

   void TargetMaps(MapHandleList* list) {
     FindTargetMaps();
     for (int i = 0; i < target_maps_.length(); i++) {
       list->Add(target_maps_.at(i));
     }
   }

   Map* FirstTargetMap() {
     FindTargetMaps();
     return target_maps_.length() > 0 ? *target_maps_.at(0) : NULL;
   }

   Handle<FeedbackVector> vector() const { return nexus()->vector_handle(); }
   FeedbackSlot slot() const { return nexus()->slot(); }
   State saved_state() const {
     return state() == RECOMPUTE_HANDLER ? old_state_ : state();
   }

   template <class NexusClass>
   NexusClass* casted_nexus() {
     return static_cast<NexusClass*>(nexus_);
   }
   FeedbackNexus* nexus() const { return nexus_; }

   inline Code* target() const;

  private:
   inline Address constant_pool() const;
   inline Address raw_constant_pool() const;

   void FindTargetMaps() {
     if (target_maps_set_) return;
     target_maps_set_ = true;
     DCHECK(UseVector());
     nexus()->ExtractMaps(&target_maps_);
   }

   // Frame pointer for the frame that uses (calls) the IC.
   Address fp_;

   // All access to the program counter and constant pool of an IC structure is
   // indirect to make the code GC safe. This feature is crucial since
   // GetProperty and SetProperty are called and they in turn might
   // invoke the garbage collector.
   Address* pc_address_;

   // The constant pool of the code which originally called the IC (which might
   // be for the breakpointed copy of the original code).
   Address* constant_pool_address_;

   Isolate* isolate_;

   bool vector_set_;
   State old_state_;  // For saving if we marked as prototype failure.
   State state_;
   FeedbackSlotKind kind_;
   Handle<Map> receiver_map_;
   MaybeHandle<Object> maybe_handler_;

   ExtraICState extra_ic_state_;
   MapHandleList target_maps_;
   bool target_maps_set_;

   FeedbackNexus* nexus_;

   DISALLOW_IMPLICIT_CONSTRUCTORS(IC);
 };


 class CallIC : public IC {
  public:
   CallIC(Isolate* isolate, CallICNexus* nexus)
       : IC(EXTRA_CALL_FRAME, isolate, nexus) {
     DCHECK(nexus != NULL);
   }
 };


 class LoadIC : public IC {
  public:
   LoadIC(Isolate* isolate, FeedbackNexus* nexus)
       : IC(NO_EXTRA_FRAME, isolate, nexus) {
     DCHECK(nexus != NULL);
     DCHECK(IsAnyLoad());
   }

   static bool ShouldThrowReferenceError(FeedbackSlotKind kind) {
     return kind == FeedbackSlotKind::kLoadGlobalNotInsideTypeof;
   }

   bool ShouldThrowReferenceError() const {
     return ShouldThrowReferenceError(kind());
   }

   MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
                                            Handle<Name> name);

  protected:
   virtual Handle<Code> slow_stub() const {
     return isolate()->builtins()->LoadIC_Slow();
   }

   // Update the inline cache and the global stub cache based on the
   // lookup result.
   void UpdateCaches(LookupIterator* lookup);

   Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) override;

   Handle<Object> CompileHandler(LookupIterator* lookup, Handle<Object> unused,
                                 CacheHolderFlag cache_holder) override;

  private:
   // Creates a data handler that represents a load of a field by given index.
   static Handle<Object> SimpleFieldLoad(Isolate* isolate, FieldIndex index);

   // Creates a data handler that represents a prototype chain check followed
   // by given Smi-handler that encoded a load from the holder.
   // Can be used only if GetPrototypeCheckCount() returns non negative value.
   Handle<Object> LoadFromPrototype(Handle<Map> receiver_map,
                                    Handle<JSObject> holder, Handle<Name> name,
                                    Handle<Object> smi_handler);

   // Creates a data handler that represents a load of a non-existent property.
   Handle<Object> LoadNonExistent(Handle<Map> receiver_map, Handle<Name> name);

   friend class IC;
   friend class NamedLoadHandlerCompiler;
 };

 class LoadGlobalIC : public LoadIC {
  public:
   LoadGlobalIC(Isolate* isolate, FeedbackNexus* nexus)
       : LoadIC(isolate, nexus) {}

   MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Name> name);

  protected:
   Handle<Code> slow_stub() const override {
     return isolate()->builtins()->LoadGlobalIC_Slow();
   }
 };

 class KeyedLoadIC : public LoadIC {
  public:
   KeyedLoadIC(Isolate* isolate, KeyedLoadICNexus* nexus)
       : LoadIC(isolate, nexus) {
     DCHECK(nexus != NULL);
   }

   MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
                                            Handle<Object> key);

  protected:
   // receiver is HeapObject because it could be a String or a JSObject
   void UpdateLoadElement(Handle<HeapObject> receiver);

  private:
   friend class IC;
 };


 class StoreIC : public IC {
  public:
   StoreIC(Isolate* isolate, FeedbackNexus* nexus)
       : IC(NO_EXTRA_FRAME, isolate, nexus) {
     DCHECK(IsAnyStore());
   }

   LanguageMode language_mode() const {
     return nexus()->vector()->GetLanguageMode(nexus()->slot());
   }

   MUST_USE_RESULT MaybeHandle<Object> Store(
       Handle<Object> object, Handle<Name> name, Handle<Object> value,
       JSReceiver::StoreFromKeyed store_mode =
           JSReceiver::CERTAINLY_NOT_STORE_FROM_KEYED);

   bool LookupForWrite(LookupIterator* it, Handle<Object> value,
                       JSReceiver::StoreFromKeyed store_mode);

  protected:
   // Stub accessors.
   Handle<Code> slow_stub() const {
     // StoreIC and KeyedStoreIC share the same slow stub.
     return isolate()->builtins()->KeyedStoreIC_Slow();
   }

   // Update the inline cache and the global stub cache based on the
   // lookup result.
   void UpdateCaches(LookupIterator* lookup, Handle<Object> value,
                     JSReceiver::StoreFromKeyed store_mode);
   Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) override;
   Handle<Object> CompileHandler(LookupIterator* lookup, Handle<Object> value,
                                 CacheHolderFlag cache_holder) override;

  private:
   Handle<Object> StoreTransition(Handle<Map> receiver_map,
                                  Handle<JSObject> holder,
                                  Handle<Map> transition, Handle<Name> name);

   friend class IC;
 };


 enum KeyedStoreCheckMap { kDontCheckMap, kCheckMap };


 enum KeyedStoreIncrementLength { kDontIncrementLength, kIncrementLength };


 class KeyedStoreIC : public StoreIC {
  public:
   KeyedAccessStoreMode GetKeyedAccessStoreMode() {
     return casted_nexus<KeyedStoreICNexus>()->GetKeyedAccessStoreMode();
   }

   KeyedStoreIC(Isolate* isolate, KeyedStoreICNexus* nexus)
       : StoreIC(isolate, nexus) {}

   MUST_USE_RESULT MaybeHandle<Object> Store(Handle<Object> object,
                                             Handle<Object> name,
                                             Handle<Object> value);

  protected:
   void UpdateStoreElement(Handle<Map> receiver_map,
                           KeyedAccessStoreMode store_mode);

  private:
   Handle<Map> ComputeTransitionedMap(Handle<Map> map,
                                      KeyedAccessStoreMode store_mode);

   friend class IC;
 };


 // Type Recording BinaryOpIC, that records the types of the inputs and outputs.
 class BinaryOpIC : public IC {
  public:
   explicit BinaryOpIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}

   MaybeHandle<Object> Transition(Handle<AllocationSite> allocation_site,
                                  Handle<Object> left,
                                  Handle<Object> right) WARN_UNUSED_RESULT;
 };


 class CompareIC : public IC {
  public:
   CompareIC(Isolate* isolate, Token::Value op)
       : IC(EXTRA_CALL_FRAME, isolate), op_(op) {}

   // Update the inline cache for the given operands.
   Code* UpdateCaches(Handle<Object> x, Handle<Object> y);

   // Helper function for computing the condition for a compare operation.
   static Condition ComputeCondition(Token::Value op);

  private:
   static bool HasInlinedSmiCode(Address address);

   bool strict() const { return op_ == Token::EQ_STRICT; }
   Condition GetCondition() const { return ComputeCondition(op_); }

   static Code* GetRawUninitialized(Isolate* isolate, Token::Value op);

   static void Clear(Isolate* isolate, Address address, Code* target,
                     Address constant_pool);

   Token::Value op_;

   friend class IC;
 };


 class ToBooleanIC : public IC {
  public:
   explicit ToBooleanIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}

   Handle<Object> ToBoolean(Handle<Object> object);
 };


 // Helper for BinaryOpIC and CompareIC.
 enum InlinedSmiCheck { ENABLE_INLINED_SMI_CHECK, DISABLE_INLINED_SMI_CHECK };
 void PatchInlinedSmiCode(Isolate* isolate, Address address,
                          InlinedSmiCheck check);

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_IC_H_
	// Copyright 2012 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_IC_H_
	#define V8_IC_H_

	#include "src/ic/ic-state.h"
	#include "src/macro-assembler.h"
	#include "src/messages.h"

	namespace v8 {
	namespace internal {

	//
	// IC is the base class for LoadIC, StoreIC, KeyedLoadIC, and KeyedStoreIC.
	//
	class IC {
	public:
	// Alias the inline cache state type to make the IC code more readable.
	typedef InlineCacheState State;

	// The IC code is either invoked with no extra frames on the stack
	// or with a single extra frame for supporting calls.
	enum FrameDepth { NO_EXTRA_FRAME = 0, EXTRA_CALL_FRAME = 1 };

	// Construct the IC structure with the given number of extra
	// JavaScript frames on the stack.
	IC(FrameDepth depth, Isolate* isolate, FeedbackNexus* nexus = NULL);
	virtual ~IC() {}

	State state() const { return state_; }
	inline Address address() const;

	// Compute the current IC state based on the target stub, receiver and name.
	void UpdateState(Handle<Object> receiver, Handle<Object> name);

	bool RecomputeHandlerForName(Handle<Object> name);
	void MarkRecomputeHandler(Handle<Object> name) {
	DCHECK(RecomputeHandlerForName(name));
	old_state_ = state_;
	state_ = RECOMPUTE_HANDLER;
	}

	// Clear the inline cache to initial state.
	static void Clear(Isolate* isolate, Address address, Address constant_pool);

	bool IsAnyLoad() const {
	return IsLoadIC() \|\| IsLoadGlobalIC() \|\| IsKeyedLoadIC();
	}
	bool IsAnyStore() const {
	return IsStoreIC() \|\| IsStoreOwnIC() \|\| IsKeyedStoreIC();
	}

	static inline Handle<Map> GetHandlerCacheHolder(Handle<Map> receiver_map,
	bool receiver_is_holder,
	Isolate* isolate,
	CacheHolderFlag* flag);
	static inline Handle<Map> GetICCacheHolder(Handle<Map> receiver_map,
	Isolate* isolate,
	CacheHolderFlag* flag);

	static bool ICUseVector(Code::Kind kind) {
	return kind == Code::LOAD_IC \|\| kind == Code::LOAD_GLOBAL_IC \|\|
	kind == Code::KEYED_LOAD_IC \|\| kind == Code::STORE_IC \|\|
	kind == Code::KEYED_STORE_IC;
	}
	static bool ICUseVector(FeedbackSlotKind kind) {
	return IsLoadICKind(kind) \|\| IsLoadGlobalICKind(kind) \|\|
	IsKeyedLoadICKind(kind) \|\| IsStoreICKind(kind) \|\|
	IsStoreOwnICKind(kind) \|\| IsKeyedStoreICKind(kind);
	}

	// The ICs that don't pass slot and vector through the stack have to
	// save/restore them in the dispatcher.
	static bool ShouldPushPopSlotAndVector(Code::Kind kind);

	static InlineCacheState StateFromCode(Code* code);

	static inline bool IsHandler(Object* object);

	// Nofity the IC system that a feedback has changed.
	static void OnFeedbackChanged(Isolate* isolate, JSFunction* host_function);

	protected:
	Address fp() const { return fp_; }
	Address pc() const { return *pc_address_; }
	Isolate* isolate() const { return isolate_; }

	// Get the caller function object.
	JSFunction* GetHostFunction() const;

	inline bool AddressIsDeoptimizedCode() const;
	inline static bool AddressIsDeoptimizedCode(Isolate* isolate,
	Address address);

	// Set the call-site target.
	inline void set_target(Code* code);
	bool is_vector_set() { return vector_set_; }

	bool UseVector() const {
	bool use = ICUseVector(kind());
	// If we are supposed to use the nexus, verify the nexus is non-null.
	DCHECK(!use \|\| nexus_ != nullptr);
	return use;
	}

	// Configure for most states.
	void ConfigureVectorState(IC::State new_state, Handle<Object> key);
	// Configure the vector for MONOMORPHIC.
	void ConfigureVectorState(Handle<Name> name, Handle<Map> map,
	Handle<Object> handler);
	// Configure the vector for POLYMORPHIC.
	void ConfigureVectorState(Handle<Name> name, MapHandleList* maps,
	List<Handle<Object>>* handlers);
	// Configure the vector for POLYMORPHIC with transitions (only for element
	// keyed stores).
	void ConfigureVectorState(MapHandleList* maps,
	MapHandleList* transitioned_maps,
	List<Handle<Object>>* handlers);

	char TransitionMarkFromState(IC::State state);
	void TraceIC(const char* type, Handle<Object> name);
	void TraceIC(const char* type, Handle<Object> name, State old_state,
	State new_state);

	MaybeHandle<Object> TypeError(MessageTemplate::Template,
	Handle<Object> object, Handle<Object> key);
	MaybeHandle<Object> ReferenceError(Handle<Name> name);

	// Access the target code for the given IC address.
	static inline Code* GetTargetAtAddress(Address address,
	Address constant_pool);
	static inline void SetTargetAtAddress(Address address, Code* target,
	Address constant_pool);
	static void PostPatching(Address address, Code* target, Code* old_target);

	void TraceHandlerCacheHitStats(LookupIterator* lookup);

	// Compute the handler either by compiling or by retrieving a cached version.
	Handle<Object> ComputeHandler(LookupIterator* lookup,
	Handle<Object> value = Handle<Code>::null());
	virtual Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) {
	UNREACHABLE();
	return Handle<Code>::null();
	}
	virtual Handle<Object> CompileHandler(LookupIterator* lookup,
	Handle<Object> value,
	CacheHolderFlag cache_holder) {
	UNREACHABLE();
	return Handle<Object>::null();
	}

	void UpdateMonomorphicIC(Handle<Object> handler, Handle<Name> name);
	bool UpdatePolymorphicIC(Handle<Name> name, Handle<Object> code);
	void UpdateMegamorphicCache(Map* map, Name* name, Object* code);

	StubCache* stub_cache();

	void CopyICToMegamorphicCache(Handle<Name> name);
	bool IsTransitionOfMonomorphicTarget(Map* source_map, Map* target_map);
	void PatchCache(Handle<Name> name, Handle<Object> code);
	FeedbackSlotKind kind() const { return kind_; }
	bool IsLoadIC() const { return IsLoadICKind(kind_); }
	bool IsLoadGlobalIC() const { return IsLoadGlobalICKind(kind_); }
	bool IsKeyedLoadIC() const { return IsKeyedLoadICKind(kind_); }
	bool IsStoreIC() const { return IsStoreICKind(kind_); }
	bool IsStoreOwnIC() const { return IsStoreOwnICKind(kind_); }
	bool IsKeyedStoreIC() const { return IsKeyedStoreICKind(kind_); }
	bool is_keyed() const { return IsKeyedLoadIC() \|\| IsKeyedStoreIC(); }
	Code::Kind handler_kind() const {
	if (IsAnyLoad()) return Code::LOAD_IC;
	DCHECK(IsAnyStore());
	return Code::STORE_IC;
	}
	bool ShouldRecomputeHandler(Handle<String> name);

	ExtraICState extra_ic_state() const { return extra_ic_state_; }

	Handle<Map> receiver_map() { return receiver_map_; }
	void update_receiver_map(Handle<Object> receiver) {
	if (receiver->IsSmi()) {
	receiver_map_ = isolate_->factory()->heap_number_map();
	} else {
	receiver_map_ = handle(HeapObject::cast(*receiver)->map());
	}
	}

	void TargetMaps(MapHandleList* list) {
	FindTargetMaps();
	for (int i = 0; i < target_maps_.length(); i++) {
	list->Add(target_maps_.at(i));
	}
	}

	Map* FirstTargetMap() {
	FindTargetMaps();
	return target_maps_.length() > 0 ? *target_maps_.at(0) : NULL;
	}

	Handle<FeedbackVector> vector() const { return nexus()->vector_handle(); }
	FeedbackSlot slot() const { return nexus()->slot(); }
	State saved_state() const {
	return state() == RECOMPUTE_HANDLER ? old_state_ : state();
	}

	template <class NexusClass>
	NexusClass* casted_nexus() {
	return static_cast<NexusClass*>(nexus_);
	}
	FeedbackNexus* nexus() const { return nexus_; }

	inline Code* target() const;

	private:
	inline Address constant_pool() const;
	inline Address raw_constant_pool() const;

	void FindTargetMaps() {
	if (target_maps_set_) return;
	target_maps_set_ = true;
	DCHECK(UseVector());
	nexus()->ExtractMaps(&target_maps_);
	}

	// Frame pointer for the frame that uses (calls) the IC.
	Address fp_;

	// All access to the program counter and constant pool of an IC structure is
	// indirect to make the code GC safe. This feature is crucial since
	// GetProperty and SetProperty are called and they in turn might
	// invoke the garbage collector.
	Address* pc_address_;

	// The constant pool of the code which originally called the IC (which might
	// be for the breakpointed copy of the original code).
	Address* constant_pool_address_;

	Isolate* isolate_;

	bool vector_set_;
	State old_state_; // For saving if we marked as prototype failure.
	State state_;
	FeedbackSlotKind kind_;
	Handle<Map> receiver_map_;
	MaybeHandle<Object> maybe_handler_;

	ExtraICState extra_ic_state_;
	MapHandleList target_maps_;
	bool target_maps_set_;

	FeedbackNexus* nexus_;

	DISALLOW_IMPLICIT_CONSTRUCTORS(IC);
	};


	class CallIC : public IC {
	public:
	CallIC(Isolate* isolate, CallICNexus* nexus)
	: IC(EXTRA_CALL_FRAME, isolate, nexus) {
	DCHECK(nexus != NULL);
	}
	};


	class LoadIC : public IC {
	public:
	LoadIC(Isolate* isolate, FeedbackNexus* nexus)
	: IC(NO_EXTRA_FRAME, isolate, nexus) {
	DCHECK(nexus != NULL);
	DCHECK(IsAnyLoad());
	}

	static bool ShouldThrowReferenceError(FeedbackSlotKind kind) {
	return kind == FeedbackSlotKind::kLoadGlobalNotInsideTypeof;
	}

	bool ShouldThrowReferenceError() const {
	return ShouldThrowReferenceError(kind());
	}

	MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
	Handle<Name> name);

	protected:
	virtual Handle<Code> slow_stub() const {
	return isolate()->builtins()->LoadIC_Slow();
	}

	// Update the inline cache and the global stub cache based on the
	// lookup result.
	void UpdateCaches(LookupIterator* lookup);

	Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) override;

	Handle<Object> CompileHandler(LookupIterator* lookup, Handle<Object> unused,
	CacheHolderFlag cache_holder) override;

	private:
	// Creates a data handler that represents a load of a field by given index.
	static Handle<Object> SimpleFieldLoad(Isolate* isolate, FieldIndex index);

	// Creates a data handler that represents a prototype chain check followed
	// by given Smi-handler that encoded a load from the holder.
	// Can be used only if GetPrototypeCheckCount() returns non negative value.
	Handle<Object> LoadFromPrototype(Handle<Map> receiver_map,
	Handle<JSObject> holder, Handle<Name> name,
	Handle<Object> smi_handler);

	// Creates a data handler that represents a load of a non-existent property.
	Handle<Object> LoadNonExistent(Handle<Map> receiver_map, Handle<Name> name);

	friend class IC;
	friend class NamedLoadHandlerCompiler;
	};

	class LoadGlobalIC : public LoadIC {
	public:
	LoadGlobalIC(Isolate* isolate, FeedbackNexus* nexus)
	: LoadIC(isolate, nexus) {}

	MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Name> name);

	protected:
	Handle<Code> slow_stub() const override {
	return isolate()->builtins()->LoadGlobalIC_Slow();
	}
	};

	class KeyedLoadIC : public LoadIC {
	public:
	KeyedLoadIC(Isolate* isolate, KeyedLoadICNexus* nexus)
	: LoadIC(isolate, nexus) {
	DCHECK(nexus != NULL);
	}

	MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
	Handle<Object> key);

	protected:
	// receiver is HeapObject because it could be a String or a JSObject
	void UpdateLoadElement(Handle<HeapObject> receiver);

	private:
	friend class IC;
	};


	class StoreIC : public IC {
	public:
	StoreIC(Isolate* isolate, FeedbackNexus* nexus)
	: IC(NO_EXTRA_FRAME, isolate, nexus) {
	DCHECK(IsAnyStore());
	}

	LanguageMode language_mode() const {
	return nexus()->vector()->GetLanguageMode(nexus()->slot());
	}

	MUST_USE_RESULT MaybeHandle<Object> Store(
	Handle<Object> object, Handle<Name> name, Handle<Object> value,
	JSReceiver::StoreFromKeyed store_mode =
	JSReceiver::CERTAINLY_NOT_STORE_FROM_KEYED);

	bool LookupForWrite(LookupIterator* it, Handle<Object> value,
	JSReceiver::StoreFromKeyed store_mode);

	protected:
	// Stub accessors.
	Handle<Code> slow_stub() const {
	// StoreIC and KeyedStoreIC share the same slow stub.
	return isolate()->builtins()->KeyedStoreIC_Slow();
	}

	// Update the inline cache and the global stub cache based on the
	// lookup result.
	void UpdateCaches(LookupIterator* lookup, Handle<Object> value,
	JSReceiver::StoreFromKeyed store_mode);
	Handle<Object> GetMapIndependentHandler(LookupIterator* lookup) override;
	Handle<Object> CompileHandler(LookupIterator* lookup, Handle<Object> value,
	CacheHolderFlag cache_holder) override;

	private:
	Handle<Object> StoreTransition(Handle<Map> receiver_map,
	Handle<JSObject> holder,
	Handle<Map> transition, Handle<Name> name);

	friend class IC;
	};


	enum KeyedStoreCheckMap { kDontCheckMap, kCheckMap };


	enum KeyedStoreIncrementLength { kDontIncrementLength, kIncrementLength };


	class KeyedStoreIC : public StoreIC {
	public:
	KeyedAccessStoreMode GetKeyedAccessStoreMode() {
	return casted_nexus<KeyedStoreICNexus>()->GetKeyedAccessStoreMode();
	}

	KeyedStoreIC(Isolate* isolate, KeyedStoreICNexus* nexus)
	: StoreIC(isolate, nexus) {}

	MUST_USE_RESULT MaybeHandle<Object> Store(Handle<Object> object,
	Handle<Object> name,
	Handle<Object> value);

	protected:
	void UpdateStoreElement(Handle<Map> receiver_map,
	KeyedAccessStoreMode store_mode);

	private:
	Handle<Map> ComputeTransitionedMap(Handle<Map> map,
	KeyedAccessStoreMode store_mode);

	friend class IC;
	};


	// Type Recording BinaryOpIC, that records the types of the inputs and outputs.
	class BinaryOpIC : public IC {
	public:
	explicit BinaryOpIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}

	MaybeHandle<Object> Transition(Handle<AllocationSite> allocation_site,
	Handle<Object> left,
	Handle<Object> right) WARN_UNUSED_RESULT;
	};


	class CompareIC : public IC {
	public:
	CompareIC(Isolate* isolate, Token::Value op)
	: IC(EXTRA_CALL_FRAME, isolate), op_(op) {}

	// Update the inline cache for the given operands.
	Code* UpdateCaches(Handle<Object> x, Handle<Object> y);

	// Helper function for computing the condition for a compare operation.
	static Condition ComputeCondition(Token::Value op);

	private:
	static bool HasInlinedSmiCode(Address address);

	bool strict() const { return op_ == Token::EQ_STRICT; }
	Condition GetCondition() const { return ComputeCondition(op_); }

	static Code* GetRawUninitialized(Isolate* isolate, Token::Value op);

	static void Clear(Isolate* isolate, Address address, Code* target,
	Address constant_pool);

	Token::Value op_;

	friend class IC;
	};


	class ToBooleanIC : public IC {
	public:
	explicit ToBooleanIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}

	Handle<Object> ToBoolean(Handle<Object> object);
	};


	// Helper for BinaryOpIC and CompareIC.
	enum InlinedSmiCheck { ENABLE_INLINED_SMI_CHECK, DISABLE_INLINED_SMI_CHECK };
	void PatchInlinedSmiCode(Isolate* isolate, Address address,
	InlinedSmiCheck check);

	} // namespace internal
	} // namespace v8

	#endif // V8_IC_H_