1 // Copyright 2012 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4 
5 #ifndef V8_IC_H_
6 #define V8_IC_H_
7 
8 #include "src/ic/ic-state.h"
9 #include "src/macro-assembler.h"
10 
11 namespace v8 {
12 namespace internal {
13 
14 
15 // IC_UTIL_LIST defines all utility functions called from generated
16 // inline caching code. The argument for the macro, ICU, is the function name.
17 #define IC_UTIL_LIST(ICU)              \
18   ICU(LoadIC_Miss)                     \
19   ICU(KeyedLoadIC_Miss)                \
20   ICU(CallIC_Miss)                     \
21   ICU(CallIC_Customization_Miss)       \
22   ICU(StoreIC_Miss)                    \
23   ICU(StoreIC_Slow)                    \
24   ICU(SharedStoreIC_ExtendStorage)     \
25   ICU(KeyedStoreIC_Miss)               \
26   ICU(KeyedStoreIC_Slow)               \
27   /* Utilities for IC stubs. */        \
28   ICU(StoreCallbackProperty)           \
29   ICU(LoadPropertyWithInterceptorOnly) \
30   ICU(LoadPropertyWithInterceptor)     \
31   ICU(LoadElementWithInterceptor)      \
32   ICU(StorePropertyWithInterceptor)    \
33   ICU(CompareIC_Miss)                  \
34   ICU(BinaryOpIC_Miss)                 \
35   ICU(CompareNilIC_Miss)               \
36   ICU(Unreachable)                     \
37   ICU(ToBooleanIC_Miss)
38 //
39 // IC is the base class for LoadIC, StoreIC, KeyedLoadIC, and KeyedStoreIC.
40 //
41 class IC {
42  public:
43   // The ids for utility called from the generated code.
44   enum UtilityId {
45 #define CONST_NAME(name) k##name,
46     IC_UTIL_LIST(CONST_NAME)
47 #undef CONST_NAME
48     kUtilityCount
49   };
50 
51   // Looks up the address of the named utility.
52   static Address AddressFromUtilityId(UtilityId id);
53 
54   // Alias the inline cache state type to make the IC code more readable.
55   typedef InlineCacheState State;
56 
57   // The IC code is either invoked with no extra frames on the stack
58   // or with a single extra frame for supporting calls.
59   enum FrameDepth { NO_EXTRA_FRAME = 0, EXTRA_CALL_FRAME = 1 };
60 
61   // Construct the IC structure with the given number of extra
62   // JavaScript frames on the stack.
63   IC(FrameDepth depth, Isolate* isolate);
~IC()64   virtual ~IC() {}
65 
state()66   State state() const { return state_; }
67   inline Address address() const;
68 
69   // Compute the current IC state based on the target stub, receiver and name.
70   void UpdateState(Handle<Object> receiver, Handle<Object> name);
71 
72   bool IsNameCompatibleWithPrototypeFailure(Handle<Object> name);
MarkPrototypeFailure(Handle<Object> name)73   void MarkPrototypeFailure(Handle<Object> name) {
74     DCHECK(IsNameCompatibleWithPrototypeFailure(name));
75     state_ = PROTOTYPE_FAILURE;
76   }
77 
78   // If the stub contains weak maps then this function adds the stub to
79   // the dependent code array of each weak map.
80   static void RegisterWeakMapDependency(Handle<Code> stub);
81 
82   // This function is called when a weak map in the stub is dying,
83   // invalidates the stub by setting maps in it to undefined.
84   static void InvalidateMaps(Code* stub);
85 
86   // Clear the inline cache to initial state.
87   static void Clear(Isolate* isolate, Address address,
88                     ConstantPoolArray* constant_pool);
89 
90 #ifdef DEBUG
IsLoadStub()91   bool IsLoadStub() const {
92     return target()->is_load_stub() || target()->is_keyed_load_stub();
93   }
94 
IsStoreStub()95   bool IsStoreStub() const {
96     return target()->is_store_stub() || target()->is_keyed_store_stub();
97   }
98 
IsCallStub()99   bool IsCallStub() const { return target()->is_call_stub(); }
100 #endif
101 
102   template <class TypeClass>
103   static JSFunction* GetRootConstructor(TypeClass* type,
104                                         Context* native_context);
105   static inline Handle<Map> GetHandlerCacheHolder(HeapType* type,
106                                                   bool receiver_is_holder,
107                                                   Isolate* isolate,
108                                                   CacheHolderFlag* flag);
109   static inline Handle<Map> GetICCacheHolder(HeapType* type, Isolate* isolate,
110                                              CacheHolderFlag* flag);
111 
IsCleared(Code * code)112   static bool IsCleared(Code* code) {
113     InlineCacheState state = code->ic_state();
114     return state == UNINITIALIZED || state == PREMONOMORPHIC;
115   }
116 
117   // Utility functions to convert maps to types and back. There are two special
118   // cases:
119   // - The heap_number_map is used as a marker which includes heap numbers as
120   //   well as smis.
121   // - The oddball map is only used for booleans.
122   static Handle<Map> TypeToMap(HeapType* type, Isolate* isolate);
123   template <class T>
124   static typename T::TypeHandle MapToType(Handle<Map> map,
125                                           typename T::Region* region);
126 
127   static Handle<HeapType> CurrentTypeOf(Handle<Object> object,
128                                         Isolate* isolate);
129 
130  protected:
131   // Get the call-site target; used for determining the state.
target()132   Handle<Code> target() const { return target_; }
133 
fp()134   Address fp() const { return fp_; }
pc()135   Address pc() const { return *pc_address_; }
isolate()136   Isolate* isolate() const { return isolate_; }
137 
138   // Get the shared function info of the caller.
139   SharedFunctionInfo* GetSharedFunctionInfo() const;
140   // Get the code object of the caller.
141   Code* GetCode() const;
142   // Get the original (non-breakpointed) code object of the caller.
143   Code* GetOriginalCode() const;
144 
145   // Set the call-site target.
146   inline void set_target(Code* code);
is_target_set()147   bool is_target_set() { return target_set_; }
148 
149   char TransitionMarkFromState(IC::State state);
150   void TraceIC(const char* type, Handle<Object> name);
151   void TraceIC(const char* type, Handle<Object> name, State old_state,
152                State new_state);
153 
154   MaybeHandle<Object> TypeError(const char* type, Handle<Object> object,
155                                 Handle<Object> key);
156   MaybeHandle<Object> ReferenceError(const char* type, Handle<Name> name);
157 
158   // Access the target code for the given IC address.
159   static inline Code* GetTargetAtAddress(Address address,
160                                          ConstantPoolArray* constant_pool);
161   static inline void SetTargetAtAddress(Address address, Code* target,
162                                         ConstantPoolArray* constant_pool);
163   static void OnTypeFeedbackChanged(Isolate* isolate, Address address,
164                                     State old_state, State new_state,
165                                     bool target_remains_ic_stub);
166   static void PostPatching(Address address, Code* target, Code* old_target);
167 
168   // Compute the handler either by compiling or by retrieving a cached version.
169   Handle<Code> ComputeHandler(LookupIterator* lookup,
170                               Handle<Object> value = Handle<Code>::null());
CompileHandler(LookupIterator * lookup,Handle<Object> value,CacheHolderFlag cache_holder)171   virtual Handle<Code> CompileHandler(LookupIterator* lookup,
172                                       Handle<Object> value,
173                                       CacheHolderFlag cache_holder) {
174     UNREACHABLE();
175     return Handle<Code>::null();
176   }
177 
178   void UpdateMonomorphicIC(Handle<Code> handler, Handle<Name> name);
179   bool UpdatePolymorphicIC(Handle<Name> name, Handle<Code> code);
180   void UpdateMegamorphicCache(HeapType* type, Name* name, Code* code);
181 
182   void CopyICToMegamorphicCache(Handle<Name> name);
183   bool IsTransitionOfMonomorphicTarget(Map* source_map, Map* target_map);
184   void PatchCache(Handle<Name> name, Handle<Code> code);
kind()185   Code::Kind kind() const { return kind_; }
handler_kind()186   Code::Kind handler_kind() const {
187     if (kind_ == Code::KEYED_LOAD_IC) return Code::LOAD_IC;
188     DCHECK(kind_ == Code::LOAD_IC || kind_ == Code::STORE_IC ||
189            kind_ == Code::KEYED_STORE_IC);
190     return kind_;
191   }
megamorphic_stub()192   virtual Handle<Code> megamorphic_stub() {
193     UNREACHABLE();
194     return Handle<Code>::null();
195   }
196 
197   bool TryRemoveInvalidPrototypeDependentStub(Handle<Object> receiver,
198                                               Handle<String> name);
199 
extra_ic_state()200   ExtraICState extra_ic_state() const { return extra_ic_state_; }
set_extra_ic_state(ExtraICState state)201   void set_extra_ic_state(ExtraICState state) { extra_ic_state_ = state; }
202 
receiver_type()203   Handle<HeapType> receiver_type() { return receiver_type_; }
update_receiver_type(Handle<Object> receiver)204   void update_receiver_type(Handle<Object> receiver) {
205     receiver_type_ = CurrentTypeOf(receiver, isolate_);
206   }
207 
TargetMaps(MapHandleList * list)208   void TargetMaps(MapHandleList* list) {
209     FindTargetMaps();
210     for (int i = 0; i < target_maps_.length(); i++) {
211       list->Add(target_maps_.at(i));
212     }
213   }
214 
TargetTypes(TypeHandleList * list)215   void TargetTypes(TypeHandleList* list) {
216     FindTargetMaps();
217     for (int i = 0; i < target_maps_.length(); i++) {
218       list->Add(MapToType<HeapType>(target_maps_.at(i), isolate_));
219     }
220   }
221 
FirstTargetMap()222   Map* FirstTargetMap() {
223     FindTargetMaps();
224     return target_maps_.length() > 0 ? *target_maps_.at(0) : NULL;
225   }
226 
227  protected:
228   inline void UpdateTarget();
229 
230  private:
231   inline Code* raw_target() const;
232   inline ConstantPoolArray* constant_pool() const;
233   inline ConstantPoolArray* raw_constant_pool() const;
234 
FindTargetMaps()235   void FindTargetMaps() {
236     if (target_maps_set_) return;
237     target_maps_set_ = true;
238     if (state_ == MONOMORPHIC) {
239       Map* map = target_->FindFirstMap();
240       if (map != NULL) target_maps_.Add(handle(map));
241     } else if (state_ != UNINITIALIZED && state_ != PREMONOMORPHIC) {
242       target_->FindAllMaps(&target_maps_);
243     }
244   }
245 
246   // Frame pointer for the frame that uses (calls) the IC.
247   Address fp_;
248 
249   // All access to the program counter of an IC structure is indirect
250   // to make the code GC safe. This feature is crucial since
251   // GetProperty and SetProperty are called and they in turn might
252   // invoke the garbage collector.
253   Address* pc_address_;
254 
255   Isolate* isolate_;
256 
257   // The constant pool of the code which originally called the IC (which might
258   // be for the breakpointed copy of the original code).
259   Handle<ConstantPoolArray> raw_constant_pool_;
260 
261   // The original code target that missed.
262   Handle<Code> target_;
263   bool target_set_;
264   State state_;
265   Code::Kind kind_;
266   Handle<HeapType> receiver_type_;
267   MaybeHandle<Code> maybe_handler_;
268 
269   ExtraICState extra_ic_state_;
270   MapHandleList target_maps_;
271   bool target_maps_set_;
272 
273   DISALLOW_IMPLICIT_CONSTRUCTORS(IC);
274 };
275 
276 
277 // An IC_Utility encapsulates IC::UtilityId. It exists mainly because you
278 // cannot make forward declarations to an enum.
279 class IC_Utility {
280  public:
IC_Utility(IC::UtilityId id)281   explicit IC_Utility(IC::UtilityId id)
282       : address_(IC::AddressFromUtilityId(id)), id_(id) {}
283 
address()284   Address address() const { return address_; }
285 
id()286   IC::UtilityId id() const { return id_; }
287 
288  private:
289   Address address_;
290   IC::UtilityId id_;
291 };
292 
293 
294 class CallIC : public IC {
295  public:
CallIC(Isolate * isolate)296   explicit CallIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}
297 
298   void PatchMegamorphic(Handle<Object> function,
299                         Handle<TypeFeedbackVector> vector, Handle<Smi> slot);
300 
301   void HandleMiss(Handle<Object> receiver, Handle<Object> function,
302                   Handle<TypeFeedbackVector> vector, Handle<Smi> slot);
303 
304   // Returns true if a custom handler was installed.
305   bool DoCustomHandler(Handle<Object> receiver, Handle<Object> function,
306                        Handle<TypeFeedbackVector> vector, Handle<Smi> slot,
307                        const CallICState& state);
308 
309   // Code generator routines.
310   static Handle<Code> initialize_stub(Isolate* isolate, int argc,
311                                       CallICState::CallType call_type);
312 
313   static void Clear(Isolate* isolate, Address address, Code* target,
314                     ConstantPoolArray* constant_pool);
315 
316  private:
317   inline IC::State FeedbackToState(Handle<TypeFeedbackVector> vector,
318                                    Handle<Smi> slot) const;
319 };
320 
321 
322 class LoadIC : public IC {
323  public:
ComputeExtraICState(ContextualMode contextual_mode)324   static ExtraICState ComputeExtraICState(ContextualMode contextual_mode) {
325     return LoadICState(contextual_mode).GetExtraICState();
326   }
327 
contextual_mode()328   ContextualMode contextual_mode() const {
329     return LoadICState::GetContextualMode(extra_ic_state());
330   }
331 
LoadIC(FrameDepth depth,Isolate * isolate)332   explicit LoadIC(FrameDepth depth, Isolate* isolate) : IC(depth, isolate) {
333     DCHECK(IsLoadStub());
334   }
335 
336   // Returns if this IC is for contextual (no explicit receiver)
337   // access to properties.
IsUndeclaredGlobal(Handle<Object> receiver)338   bool IsUndeclaredGlobal(Handle<Object> receiver) {
339     if (receiver->IsGlobalObject()) {
340       return contextual_mode() == CONTEXTUAL;
341     } else {
342       DCHECK(contextual_mode() != CONTEXTUAL);
343       return false;
344     }
345   }
346 
347   // Code generator routines.
GenerateInitialize(MacroAssembler * masm)348   static void GenerateInitialize(MacroAssembler* masm) { GenerateMiss(masm); }
GeneratePreMonomorphic(MacroAssembler * masm)349   static void GeneratePreMonomorphic(MacroAssembler* masm) {
350     GenerateMiss(masm);
351   }
352   static void GenerateMiss(MacroAssembler* masm);
353   static void GenerateNormal(MacroAssembler* masm);
354   static void GenerateRuntimeGetProperty(MacroAssembler* masm);
355 
356   static Handle<Code> initialize_stub(Isolate* isolate,
357                                       ExtraICState extra_state);
358 
359   MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
360                                            Handle<Name> name);
361 
362  protected:
363   inline void set_target(Code* code);
364 
slow_stub()365   Handle<Code> slow_stub() const {
366     if (kind() == Code::LOAD_IC) {
367       return isolate()->builtins()->LoadIC_Slow();
368     } else {
369       DCHECK_EQ(Code::KEYED_LOAD_IC, kind());
370       return isolate()->builtins()->KeyedLoadIC_Slow();
371     }
372   }
373 
374   virtual Handle<Code> megamorphic_stub() OVERRIDE;
375 
376   // Update the inline cache and the global stub cache based on the
377   // lookup result.
378   void UpdateCaches(LookupIterator* lookup);
379 
380   virtual Handle<Code> CompileHandler(LookupIterator* lookup,
381                                       Handle<Object> unused,
382                                       CacheHolderFlag cache_holder);
383 
384  private:
385   virtual Handle<Code> pre_monomorphic_stub() const;
386   static Handle<Code> pre_monomorphic_stub(Isolate* isolate,
387                                            ExtraICState extra_state);
388 
389   Handle<Code> SimpleFieldLoad(FieldIndex index);
390 
391   static void Clear(Isolate* isolate, Address address, Code* target,
392                     ConstantPoolArray* constant_pool);
393 
394   friend class IC;
395 };
396 
397 
398 class KeyedLoadIC : public LoadIC {
399  public:
KeyedLoadIC(FrameDepth depth,Isolate * isolate)400   explicit KeyedLoadIC(FrameDepth depth, Isolate* isolate)
401       : LoadIC(depth, isolate) {
402     DCHECK(target()->is_keyed_load_stub());
403   }
404 
405   MUST_USE_RESULT MaybeHandle<Object> Load(Handle<Object> object,
406                                            Handle<Object> key);
407 
408   // Code generator routines.
409   static void GenerateMiss(MacroAssembler* masm);
410   static void GenerateRuntimeGetProperty(MacroAssembler* masm);
GenerateInitialize(MacroAssembler * masm)411   static void GenerateInitialize(MacroAssembler* masm) { GenerateMiss(masm); }
GeneratePreMonomorphic(MacroAssembler * masm)412   static void GeneratePreMonomorphic(MacroAssembler* masm) {
413     GenerateMiss(masm);
414   }
415   static void GenerateGeneric(MacroAssembler* masm);
416   static void GenerateString(MacroAssembler* masm);
417 
418   // Bit mask to be tested against bit field for the cases when
419   // generic stub should go into slow case.
420   // Access check is necessary explicitly since generic stub does not perform
421   // map checks.
422   static const int kSlowCaseBitFieldMask =
423       (1 << Map::kIsAccessCheckNeeded) | (1 << Map::kHasIndexedInterceptor);
424 
425   static Handle<Code> generic_stub(Isolate* isolate);
426   static Handle<Code> pre_monomorphic_stub(Isolate* isolate);
427 
428  protected:
429   Handle<Code> LoadElementStub(Handle<JSObject> receiver);
pre_monomorphic_stub()430   virtual Handle<Code> pre_monomorphic_stub() const {
431     return pre_monomorphic_stub(isolate());
432   }
433 
434  private:
generic_stub()435   Handle<Code> generic_stub() const { return generic_stub(isolate()); }
string_stub()436   Handle<Code> string_stub() {
437     return isolate()->builtins()->KeyedLoadIC_String();
438   }
439 
440   static void Clear(Isolate* isolate, Address address, Code* target,
441                     ConstantPoolArray* constant_pool);
442 
443   friend class IC;
444 };
445 
446 
447 class StoreIC : public IC {
448  public:
449   class StrictModeState : public BitField<StrictMode, 1, 1> {};
ComputeExtraICState(StrictMode flag)450   static ExtraICState ComputeExtraICState(StrictMode flag) {
451     return StrictModeState::encode(flag);
452   }
GetStrictMode(ExtraICState state)453   static StrictMode GetStrictMode(ExtraICState state) {
454     return StrictModeState::decode(state);
455   }
456 
457   // For convenience, a statically declared encoding of strict mode extra
458   // IC state.
459   static const ExtraICState kStrictModeState = 1 << StrictModeState::kShift;
460 
StoreIC(FrameDepth depth,Isolate * isolate)461   StoreIC(FrameDepth depth, Isolate* isolate) : IC(depth, isolate) {
462     DCHECK(IsStoreStub());
463   }
464 
strict_mode()465   StrictMode strict_mode() const {
466     return StrictModeState::decode(extra_ic_state());
467   }
468 
469   // Code generators for stub routines. Only called once at startup.
470   static void GenerateSlow(MacroAssembler* masm);
GenerateInitialize(MacroAssembler * masm)471   static void GenerateInitialize(MacroAssembler* masm) { GenerateMiss(masm); }
GeneratePreMonomorphic(MacroAssembler * masm)472   static void GeneratePreMonomorphic(MacroAssembler* masm) {
473     GenerateMiss(masm);
474   }
475   static void GenerateMiss(MacroAssembler* masm);
476   static void GenerateMegamorphic(MacroAssembler* masm);
477   static void GenerateNormal(MacroAssembler* masm);
478   static void GenerateRuntimeSetProperty(MacroAssembler* masm,
479                                          StrictMode strict_mode);
480 
481   static Handle<Code> initialize_stub(Isolate* isolate, StrictMode strict_mode);
482 
483   MUST_USE_RESULT MaybeHandle<Object> Store(
484       Handle<Object> object, Handle<Name> name, Handle<Object> value,
485       JSReceiver::StoreFromKeyed store_mode =
486           JSReceiver::CERTAINLY_NOT_STORE_FROM_KEYED);
487 
488   bool LookupForWrite(LookupIterator* it, Handle<Object> value,
489                       JSReceiver::StoreFromKeyed store_mode);
490 
491  protected:
492   virtual Handle<Code> megamorphic_stub() OVERRIDE;
493 
494   // Stub accessors.
495   Handle<Code> generic_stub() const;
496 
497   Handle<Code> slow_stub() const;
498 
pre_monomorphic_stub()499   virtual Handle<Code> pre_monomorphic_stub() const {
500     return pre_monomorphic_stub(isolate(), strict_mode());
501   }
502 
503   static Handle<Code> pre_monomorphic_stub(Isolate* isolate,
504                                            StrictMode strict_mode);
505 
506   // Update the inline cache and the global stub cache based on the
507   // lookup result.
508   void UpdateCaches(LookupIterator* lookup, Handle<Object> value,
509                     JSReceiver::StoreFromKeyed store_mode);
510   virtual Handle<Code> CompileHandler(LookupIterator* lookup,
511                                       Handle<Object> value,
512                                       CacheHolderFlag cache_holder);
513 
514  private:
515   inline void set_target(Code* code);
516 
517   static void Clear(Isolate* isolate, Address address, Code* target,
518                     ConstantPoolArray* constant_pool);
519 
520   friend class IC;
521 };
522 
523 
524 enum KeyedStoreCheckMap { kDontCheckMap, kCheckMap };
525 
526 
527 enum KeyedStoreIncrementLength { kDontIncrementLength, kIncrementLength };
528 
529 
530 class KeyedStoreIC : public StoreIC {
531  public:
532   // ExtraICState bits (building on IC)
533   // ExtraICState bits
534   class ExtraICStateKeyedAccessStoreMode
535       : public BitField<KeyedAccessStoreMode, 2, 4> {};  // NOLINT
536 
ComputeExtraICState(StrictMode flag,KeyedAccessStoreMode mode)537   static ExtraICState ComputeExtraICState(StrictMode flag,
538                                           KeyedAccessStoreMode mode) {
539     return StrictModeState::encode(flag) |
540            ExtraICStateKeyedAccessStoreMode::encode(mode);
541   }
542 
GetKeyedAccessStoreMode(ExtraICState extra_state)543   static KeyedAccessStoreMode GetKeyedAccessStoreMode(
544       ExtraICState extra_state) {
545     return ExtraICStateKeyedAccessStoreMode::decode(extra_state);
546   }
547 
KeyedStoreIC(FrameDepth depth,Isolate * isolate)548   KeyedStoreIC(FrameDepth depth, Isolate* isolate) : StoreIC(depth, isolate) {
549     DCHECK(target()->is_keyed_store_stub());
550   }
551 
552   MUST_USE_RESULT MaybeHandle<Object> Store(Handle<Object> object,
553                                             Handle<Object> name,
554                                             Handle<Object> value);
555 
556   // Code generators for stub routines.  Only called once at startup.
GenerateInitialize(MacroAssembler * masm)557   static void GenerateInitialize(MacroAssembler* masm) { GenerateMiss(masm); }
GeneratePreMonomorphic(MacroAssembler * masm)558   static void GeneratePreMonomorphic(MacroAssembler* masm) {
559     GenerateMiss(masm);
560   }
561   static void GenerateMiss(MacroAssembler* masm);
562   static void GenerateSlow(MacroAssembler* masm);
563   static void GenerateGeneric(MacroAssembler* masm, StrictMode strict_mode);
564   static void GenerateSloppyArguments(MacroAssembler* masm);
565 
566  protected:
pre_monomorphic_stub()567   virtual Handle<Code> pre_monomorphic_stub() const {
568     return pre_monomorphic_stub(isolate(), strict_mode());
569   }
pre_monomorphic_stub(Isolate * isolate,StrictMode strict_mode)570   static Handle<Code> pre_monomorphic_stub(Isolate* isolate,
571                                            StrictMode strict_mode) {
572     if (strict_mode == STRICT) {
573       return isolate->builtins()->KeyedStoreIC_PreMonomorphic_Strict();
574     } else {
575       return isolate->builtins()->KeyedStoreIC_PreMonomorphic();
576     }
577   }
578 
579   Handle<Code> StoreElementStub(Handle<JSObject> receiver,
580                                 KeyedAccessStoreMode store_mode);
581 
582  private:
583   inline void set_target(Code* code);
584 
585   // Stub accessors.
sloppy_arguments_stub()586   Handle<Code> sloppy_arguments_stub() {
587     return isolate()->builtins()->KeyedStoreIC_SloppyArguments();
588   }
589 
590   static void Clear(Isolate* isolate, Address address, Code* target,
591                     ConstantPoolArray* constant_pool);
592 
593   KeyedAccessStoreMode GetStoreMode(Handle<JSObject> receiver,
594                                     Handle<Object> key, Handle<Object> value);
595 
596   Handle<Map> ComputeTransitionedMap(Handle<Map> map,
597                                      KeyedAccessStoreMode store_mode);
598 
599   friend class IC;
600 };
601 
602 
603 // Type Recording BinaryOpIC, that records the types of the inputs and outputs.
604 class BinaryOpIC : public IC {
605  public:
BinaryOpIC(Isolate * isolate)606   explicit BinaryOpIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}
607 
608   static Builtins::JavaScript TokenToJSBuiltin(Token::Value op);
609 
610   MaybeHandle<Object> Transition(Handle<AllocationSite> allocation_site,
611                                  Handle<Object> left,
612                                  Handle<Object> right) WARN_UNUSED_RESULT;
613 };
614 
615 
616 class CompareIC : public IC {
617  public:
CompareIC(Isolate * isolate,Token::Value op)618   CompareIC(Isolate* isolate, Token::Value op)
619       : IC(EXTRA_CALL_FRAME, isolate), op_(op) {}
620 
621   // Update the inline cache for the given operands.
622   Code* UpdateCaches(Handle<Object> x, Handle<Object> y);
623 
624   // Helper function for computing the condition for a compare operation.
625   static Condition ComputeCondition(Token::Value op);
626 
627   // Factory method for getting an uninitialized compare stub.
628   static Handle<Code> GetUninitialized(Isolate* isolate, Token::Value op);
629 
630  private:
631   static bool HasInlinedSmiCode(Address address);
632 
strict()633   bool strict() const { return op_ == Token::EQ_STRICT; }
GetCondition()634   Condition GetCondition() const { return ComputeCondition(op_); }
635 
636   static Code* GetRawUninitialized(Isolate* isolate, Token::Value op);
637 
638   static void Clear(Isolate* isolate, Address address, Code* target,
639                     ConstantPoolArray* constant_pool);
640 
641   Token::Value op_;
642 
643   friend class IC;
644 };
645 
646 
647 class CompareNilIC : public IC {
648  public:
CompareNilIC(Isolate * isolate)649   explicit CompareNilIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}
650 
651   Handle<Object> CompareNil(Handle<Object> object);
652 
653   static Handle<Code> GetUninitialized();
654 
655   static void Clear(Address address, Code* target,
656                     ConstantPoolArray* constant_pool);
657 
658   static Handle<Object> DoCompareNilSlow(Isolate* isolate, NilValue nil,
659                                          Handle<Object> object);
660 };
661 
662 
663 class ToBooleanIC : public IC {
664  public:
ToBooleanIC(Isolate * isolate)665   explicit ToBooleanIC(Isolate* isolate) : IC(EXTRA_CALL_FRAME, isolate) {}
666 
667   Handle<Object> ToBoolean(Handle<Object> object);
668 };
669 
670 
671 // Helper for BinaryOpIC and CompareIC.
672 enum InlinedSmiCheck { ENABLE_INLINED_SMI_CHECK, DISABLE_INLINED_SMI_CHECK };
673 void PatchInlinedSmiCode(Address address, InlinedSmiCheck check);
674 
675 DECLARE_RUNTIME_FUNCTION(KeyedLoadIC_MissFromStubFailure);
676 DECLARE_RUNTIME_FUNCTION(KeyedStoreIC_MissFromStubFailure);
677 DECLARE_RUNTIME_FUNCTION(UnaryOpIC_Miss);
678 DECLARE_RUNTIME_FUNCTION(StoreIC_MissFromStubFailure);
679 DECLARE_RUNTIME_FUNCTION(ElementsTransitionAndStoreIC_Miss);
680 DECLARE_RUNTIME_FUNCTION(BinaryOpIC_Miss);
681 DECLARE_RUNTIME_FUNCTION(BinaryOpIC_MissWithAllocationSite);
682 DECLARE_RUNTIME_FUNCTION(CompareNilIC_Miss);
683 DECLARE_RUNTIME_FUNCTION(ToBooleanIC_Miss);
684 DECLARE_RUNTIME_FUNCTION(VectorLoadIC_MissFromStubFailure);
685 DECLARE_RUNTIME_FUNCTION(VectorKeyedLoadIC_MissFromStubFailure);
686 
687 // Support functions for callbacks handlers.
688 DECLARE_RUNTIME_FUNCTION(StoreCallbackProperty);
689 
690 // Support functions for interceptor handlers.
691 DECLARE_RUNTIME_FUNCTION(LoadPropertyWithInterceptorOnly);
692 DECLARE_RUNTIME_FUNCTION(LoadPropertyWithInterceptor);
693 DECLARE_RUNTIME_FUNCTION(LoadElementWithInterceptor);
694 DECLARE_RUNTIME_FUNCTION(StorePropertyWithInterceptor);
695 }
696 }  // namespace v8::internal
697 
698 #endif  // V8_IC_H_
699