src/type-info.cc - v8/v8.git - 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.

 #include "src/type-info.h"

 #include "src/ast/ast.h"
 #include "src/code-stubs.h"
 #include "src/ic/ic.h"
 #include "src/ic/stub-cache.h"
 #include "src/objects-inl.h"

 namespace v8 {
 namespace internal {


 TypeFeedbackOracle::TypeFeedbackOracle(
     Isolate* isolate, Zone* zone, Handle<Code> code,
     Handle<TypeFeedbackVector> feedback_vector, Handle<Context> native_context)
     : native_context_(native_context), isolate_(isolate), zone_(zone) {
   BuildDictionary(code);
   DCHECK(dictionary_->IsUnseededNumberDictionary());
   // We make a copy of the feedback vector because a GC could clear
   // the type feedback info contained therein.
   // TODO(mvstanton): revisit the decision to copy when we weakly
   // traverse the feedback vector at GC time.
   feedback_vector_ = TypeFeedbackVector::Copy(isolate, feedback_vector);
 }


 static uint32_t IdToKey(TypeFeedbackId ast_id) {
   return static_cast<uint32_t>(ast_id.ToInt());
 }


 Handle<Object> TypeFeedbackOracle::GetInfo(TypeFeedbackId ast_id) {
   int entry = dictionary_->FindEntry(IdToKey(ast_id));
   if (entry != UnseededNumberDictionary::kNotFound) {
     Object* value = dictionary_->ValueAt(entry);
     if (value->IsCell()) {
       Cell* cell = Cell::cast(value);
       return Handle<Object>(cell->value(), isolate());
     } else {
       return Handle<Object>(value, isolate());
     }
   }
   return Handle<Object>::cast(isolate()->factory()->undefined_value());
 }


 Handle<Object> TypeFeedbackOracle::GetInfo(FeedbackVectorSlot slot) {
   DCHECK(slot.ToInt() >= 0 && slot.ToInt() < feedback_vector_->length());
   Handle<Object> undefined =
       Handle<Object>::cast(isolate()->factory()->undefined_value());
   Object* obj = feedback_vector_->Get(slot);

   // Slots do not embed direct pointers to maps, functions. Instead
   // a WeakCell is always used.
   if (obj->IsWeakCell()) {
     WeakCell* cell = WeakCell::cast(obj);
     if (cell->cleared()) return undefined;
     obj = cell->value();
   }

   if (obj->IsJSFunction() || obj->IsAllocationSite() || obj->IsSymbol() ||
       obj->IsSimd128Value()) {
     return Handle<Object>(obj, isolate());
   }

   return undefined;
 }


 InlineCacheState TypeFeedbackOracle::LoadInlineCacheState(
     FeedbackVectorSlot slot) {
   if (!slot.IsInvalid()) {
     FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
     if (kind == FeedbackVectorSlotKind::LOAD_IC) {
       LoadICNexus nexus(feedback_vector_, slot);
       return nexus.StateFromFeedback();
     } else if (kind == FeedbackVectorSlotKind::KEYED_LOAD_IC) {
       KeyedLoadICNexus nexus(feedback_vector_, slot);
       return nexus.StateFromFeedback();
     }
   }

   // If we can't find an IC, assume we've seen *something*, but we don't know
   // what. PREMONOMORPHIC roughly encodes this meaning.
   return PREMONOMORPHIC;
 }


 bool TypeFeedbackOracle::StoreIsUninitialized(FeedbackVectorSlot slot) {
   if (!slot.IsInvalid()) {
     FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
     if (kind == FeedbackVectorSlotKind::STORE_IC) {
       StoreICNexus nexus(feedback_vector_, slot);
       return nexus.StateFromFeedback() == UNINITIALIZED;
     } else if (kind == FeedbackVectorSlotKind::KEYED_STORE_IC) {
       KeyedStoreICNexus nexus(feedback_vector_, slot);
       return nexus.StateFromFeedback() == UNINITIALIZED;
     }
   }
   return true;
 }


 bool TypeFeedbackOracle::CallIsUninitialized(FeedbackVectorSlot slot) {
   Handle<Object> value = GetInfo(slot);
   return value->IsUndefined(isolate()) ||
          value.is_identical_to(
              TypeFeedbackVector::UninitializedSentinel(isolate()));
 }


 bool TypeFeedbackOracle::CallIsMonomorphic(FeedbackVectorSlot slot) {
   Handle<Object> value = GetInfo(slot);
   return value->IsAllocationSite() || value->IsJSFunction();
 }


 bool TypeFeedbackOracle::CallNewIsMonomorphic(FeedbackVectorSlot slot) {
   Handle<Object> info = GetInfo(slot);
   return info->IsAllocationSite() || info->IsJSFunction();
 }


 byte TypeFeedbackOracle::ForInType(FeedbackVectorSlot feedback_vector_slot) {
   Handle<Object> value = GetInfo(feedback_vector_slot);
   return value.is_identical_to(
              TypeFeedbackVector::UninitializedSentinel(isolate()))
              ? ForInStatement::FAST_FOR_IN
              : ForInStatement::SLOW_FOR_IN;
 }


 void TypeFeedbackOracle::GetStoreModeAndKeyType(
     FeedbackVectorSlot slot, KeyedAccessStoreMode* store_mode,
     IcCheckType* key_type) {
   if (!slot.IsInvalid() &&
       feedback_vector_->GetKind(slot) ==
           FeedbackVectorSlotKind::KEYED_STORE_IC) {
     KeyedStoreICNexus nexus(feedback_vector_, slot);
     *store_mode = nexus.GetKeyedAccessStoreMode();
     *key_type = nexus.GetKeyType();
   } else {
     *store_mode = STANDARD_STORE;
     *key_type = ELEMENT;
   }
 }


 Handle<JSFunction> TypeFeedbackOracle::GetCallTarget(FeedbackVectorSlot slot) {
   Handle<Object> info = GetInfo(slot);
   if (info->IsAllocationSite()) {
     return Handle<JSFunction>(isolate()->native_context()->array_function());
   }

   return Handle<JSFunction>::cast(info);
 }


 Handle<JSFunction> TypeFeedbackOracle::GetCallNewTarget(
     FeedbackVectorSlot slot) {
   Handle<Object> info = GetInfo(slot);
   if (info->IsJSFunction()) {
     return Handle<JSFunction>::cast(info);
   }

   DCHECK(info->IsAllocationSite());
   return Handle<JSFunction>(isolate()->native_context()->array_function());
 }


 Handle<AllocationSite> TypeFeedbackOracle::GetCallAllocationSite(
     FeedbackVectorSlot slot) {
   Handle<Object> info = GetInfo(slot);
   if (info->IsAllocationSite()) {
     return Handle<AllocationSite>::cast(info);
   }
   return Handle<AllocationSite>::null();
 }


 Handle<AllocationSite> TypeFeedbackOracle::GetCallNewAllocationSite(
     FeedbackVectorSlot slot) {
   Handle<Object> info = GetInfo(slot);
   if (info->IsAllocationSite()) {
     return Handle<AllocationSite>::cast(info);
   }
   return Handle<AllocationSite>::null();
 }

 namespace {

 AstType* CompareOpHintToType(CompareOperationHint hint) {
   switch (hint) {
     case CompareOperationHint::kNone:
       return AstType::None();
     case CompareOperationHint::kSignedSmall:
       return AstType::SignedSmall();
     case CompareOperationHint::kNumber:
       return AstType::Number();
     case CompareOperationHint::kNumberOrOddball:
       return AstType::NumberOrOddball();
     case CompareOperationHint::kAny:
       return AstType::Any();
   }
   UNREACHABLE();
   return AstType::None();
 }

 AstType* BinaryOpFeedbackToType(int hint) {
   switch (hint) {
     case BinaryOperationFeedback::kNone:
       return AstType::None();
     case BinaryOperationFeedback::kSignedSmall:
       return AstType::SignedSmall();
     case BinaryOperationFeedback::kNumber:
       return AstType::Number();
     case BinaryOperationFeedback::kString:
       return AstType::String();
     // TODO(mythria): Merge Number and NumberOrOddball feedback, after
     // fixing crankshaft to handle Oddballs along with Numbers.
     case BinaryOperationFeedback::kNumberOrOddball:
     case BinaryOperationFeedback::kAny:
     default:
       return AstType::Any();
   }
   UNREACHABLE();
   return AstType::None();
 }

 }  // end anonymous namespace

 void TypeFeedbackOracle::CompareType(TypeFeedbackId id, FeedbackVectorSlot slot,
                                      AstType** left_type, AstType** right_type,
                                      AstType** combined_type) {
   Handle<Object> info = GetInfo(id);
   // A check for a valid slot is not sufficient here. InstanceOf collects
   // type feedback in a General slot.
   if (!info->IsCode()) {
     // For some comparisons we don't have type feedback, e.g.
     // LiteralCompareTypeof.
     *left_type = *right_type = *combined_type = AstType::None();
     return;
   }

   // Feedback from Ignition. The feedback slot will be allocated and initialized
   // to AstType::None() even when ignition is not enabled. So it is safe to get
   // feedback from the type feedback vector.
   DCHECK(!slot.IsInvalid());
   CompareICNexus nexus(feedback_vector_, slot);
   *left_type = *right_type = *combined_type =
       CompareOpHintToType(nexus.GetCompareOperationFeedback());

   // Merge the feedback from full-codegen if available.
   Handle<Code> code = Handle<Code>::cast(info);
   Handle<Map> map;
   Map* raw_map = code->FindFirstMap();
   if (raw_map != NULL) Map::TryUpdate(handle(raw_map)).ToHandle(&map);

   if (code->is_compare_ic_stub()) {
     CompareICStub stub(code->stub_key(), isolate());
     AstType* left_type_from_ic =
         CompareICState::StateToType(zone(), stub.left());
     *left_type = AstType::Union(*left_type, left_type_from_ic, zone());
     AstType* right_type_from_ic =
         CompareICState::StateToType(zone(), stub.right());
     *right_type = AstType::Union(*right_type, right_type_from_ic, zone());
     AstType* combined_type_from_ic =
         CompareICState::StateToType(zone(), stub.state(), map);
     *combined_type =
         AstType::Union(*combined_type, combined_type_from_ic, zone());
   }
 }

 void TypeFeedbackOracle::BinaryType(TypeFeedbackId id, FeedbackVectorSlot slot,
                                     AstType** left, AstType** right,
                                     AstType** result,
                                     Maybe<int>* fixed_right_arg,
                                     Handle<AllocationSite>* allocation_site,
                                     Token::Value op) {
   Handle<Object> object = GetInfo(id);
   if (slot.IsInvalid()) {
     // For some binary ops we don't have ICs or feedback slots,
     // e.g. Token::COMMA, but for the operations covered by the BinaryOpIC we
     // should always have them.
     DCHECK(!object->IsCode());
     DCHECK(op < BinaryOpICState::FIRST_TOKEN ||
            op > BinaryOpICState::LAST_TOKEN);
     *left = *right = *result = AstType::None();
     *fixed_right_arg = Nothing<int>();
     *allocation_site = Handle<AllocationSite>::null();
     return;
   }

   // Feedback from Ignition. The feedback slot will be allocated and initialized
   // to AstType::None() even when ignition is not enabled. So it is safe to get
   // feedback from the type feedback vector.
   DCHECK(!slot.IsInvalid());
   BinaryOpICNexus nexus(feedback_vector_, slot);
   *left = *right = *result =
       BinaryOpFeedbackToType(Smi::cast(nexus.GetFeedback())->value());
   *fixed_right_arg = Nothing<int>();
   *allocation_site = Handle<AllocationSite>::null();

   if (!object->IsCode()) return;

   // Merge the feedback from full-codegen if available.
   Handle<Code> code = Handle<Code>::cast(object);
   DCHECK_EQ(Code::BINARY_OP_IC, code->kind());
   BinaryOpICState state(isolate(), code->extra_ic_state());
   DCHECK_EQ(op, state.op());

   *left = AstType::Union(*left, state.GetLeftType(), zone());
   *right = AstType::Union(*right, state.GetRightType(), zone());
   *result = AstType::Union(*result, state.GetResultType(), zone());
   *fixed_right_arg = state.fixed_right_arg();

   AllocationSite* first_allocation_site = code->FindFirstAllocationSite();
   if (first_allocation_site != NULL) {
     *allocation_site = handle(first_allocation_site);
   } else {
     *allocation_site = Handle<AllocationSite>::null();
   }
 }

 AstType* TypeFeedbackOracle::CountType(TypeFeedbackId id,
                                        FeedbackVectorSlot slot) {
   Handle<Object> object = GetInfo(id);
   if (slot.IsInvalid()) {
     DCHECK(!object->IsCode());
     return AstType::None();
   }

   DCHECK(!slot.IsInvalid());
   BinaryOpICNexus nexus(feedback_vector_, slot);
   AstType* type =
       BinaryOpFeedbackToType(Smi::cast(nexus.GetFeedback())->value());

   if (!object->IsCode()) return type;

   Handle<Code> code = Handle<Code>::cast(object);
   DCHECK_EQ(Code::BINARY_OP_IC, code->kind());
   BinaryOpICState state(isolate(), code->extra_ic_state());
   return AstType::Union(type, state.GetLeftType(), zone());
 }


 bool TypeFeedbackOracle::HasOnlyStringMaps(SmallMapList* receiver_types) {
   bool all_strings = receiver_types->length() > 0;
   for (int i = 0; i < receiver_types->length(); i++) {
     all_strings &= receiver_types->at(i)->IsStringMap();
   }
   return all_strings;
 }


 void TypeFeedbackOracle::PropertyReceiverTypes(FeedbackVectorSlot slot,
                                                Handle<Name> name,
                                                SmallMapList* receiver_types) {
   receiver_types->Clear();
   if (!slot.IsInvalid()) {
     LoadICNexus nexus(feedback_vector_, slot);
     CollectReceiverTypes(isolate()->load_stub_cache(), &nexus, name,
                          receiver_types);
   }
 }


 void TypeFeedbackOracle::KeyedPropertyReceiverTypes(
     FeedbackVectorSlot slot, SmallMapList* receiver_types, bool* is_string,
     IcCheckType* key_type) {
   receiver_types->Clear();
   if (slot.IsInvalid()) {
     *is_string = false;
     *key_type = ELEMENT;
   } else {
     KeyedLoadICNexus nexus(feedback_vector_, slot);
     CollectReceiverTypes(&nexus, receiver_types);
     *is_string = HasOnlyStringMaps(receiver_types);
     *key_type = nexus.GetKeyType();
   }
 }


 void TypeFeedbackOracle::AssignmentReceiverTypes(FeedbackVectorSlot slot,
                                                  Handle<Name> name,
                                                  SmallMapList* receiver_types) {
   receiver_types->Clear();
   CollectReceiverTypes(isolate()->store_stub_cache(), slot, name,
                        receiver_types);
 }


 void TypeFeedbackOracle::KeyedAssignmentReceiverTypes(
     FeedbackVectorSlot slot, SmallMapList* receiver_types,
     KeyedAccessStoreMode* store_mode, IcCheckType* key_type) {
   receiver_types->Clear();
   CollectReceiverTypes(slot, receiver_types);
   GetStoreModeAndKeyType(slot, store_mode, key_type);
 }


 void TypeFeedbackOracle::CountReceiverTypes(FeedbackVectorSlot slot,
                                             SmallMapList* receiver_types) {
   receiver_types->Clear();
   if (!slot.IsInvalid()) CollectReceiverTypes(slot, receiver_types);
 }

 void TypeFeedbackOracle::CollectReceiverTypes(StubCache* stub_cache,
                                               FeedbackVectorSlot slot,
                                               Handle<Name> name,
                                               SmallMapList* types) {
   StoreICNexus nexus(feedback_vector_, slot);
   CollectReceiverTypes(stub_cache, &nexus, name, types);
 }

 void TypeFeedbackOracle::CollectReceiverTypes(StubCache* stub_cache,
                                               FeedbackNexus* nexus,
                                               Handle<Name> name,
                                               SmallMapList* types) {
   if (FLAG_collect_megamorphic_maps_from_stub_cache &&
       nexus->ic_state() == MEGAMORPHIC) {
     types->Reserve(4, zone());
     stub_cache->CollectMatchingMaps(types, name, native_context_, zone());
   } else {
     CollectReceiverTypes(nexus, types);
   }
 }


 void TypeFeedbackOracle::CollectReceiverTypes(FeedbackVectorSlot slot,
                                               SmallMapList* types) {
   FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
   if (kind == FeedbackVectorSlotKind::STORE_IC) {
     StoreICNexus nexus(feedback_vector_, slot);
     CollectReceiverTypes(&nexus, types);
   } else {
     DCHECK_EQ(FeedbackVectorSlotKind::KEYED_STORE_IC, kind);
     KeyedStoreICNexus nexus(feedback_vector_, slot);
     CollectReceiverTypes(&nexus, types);
   }
 }

 void TypeFeedbackOracle::CollectReceiverTypes(FeedbackNexus* nexus,
                                               SmallMapList* types) {
   MapHandleList maps;
   if (nexus->ic_state() == MONOMORPHIC) {
     Map* map = nexus->FindFirstMap();
     if (map != NULL) maps.Add(handle(map));
   } else if (nexus->ic_state() == POLYMORPHIC) {
     nexus->FindAllMaps(&maps);
   } else {
     return;
   }
   types->Reserve(maps.length(), zone());
   for (int i = 0; i < maps.length(); i++) {
     Handle<Map> map(maps.at(i));
     if (IsRelevantFeedback(*map, *native_context_)) {
       types->AddMapIfMissing(maps.at(i), zone());
     }
   }
 }


 uint16_t TypeFeedbackOracle::ToBooleanTypes(TypeFeedbackId id) {
   Handle<Object> object = GetInfo(id);
   return object->IsCode() ? Handle<Code>::cast(object)->to_boolean_state() : 0;
 }


 // Things are a bit tricky here: The iterator for the RelocInfos and the infos
 // themselves are not GC-safe, so we first get all infos, then we create the
 // dictionary (possibly triggering GC), and finally we relocate the collected
 // infos before we process them.
 void TypeFeedbackOracle::BuildDictionary(Handle<Code> code) {
   DisallowHeapAllocation no_allocation;
   ZoneList<RelocInfo> infos(16, zone());
   HandleScope scope(isolate());
   GetRelocInfos(code, &infos);
   CreateDictionary(code, &infos);
   ProcessRelocInfos(&infos);
   // Allocate handle in the parent scope.
   dictionary_ = scope.CloseAndEscape(dictionary_);
 }


 void TypeFeedbackOracle::GetRelocInfos(Handle<Code> code,
                                        ZoneList<RelocInfo>* infos) {
   int mask = RelocInfo::ModeMask(RelocInfo::CODE_TARGET_WITH_ID);
   for (RelocIterator it(*code, mask); !it.done(); it.next()) {
     infos->Add(*it.rinfo(), zone());
   }
 }


 void TypeFeedbackOracle::CreateDictionary(Handle<Code> code,
                                           ZoneList<RelocInfo>* infos) {
   AllowHeapAllocation allocation_allowed;
   Code* old_code = *code;
   dictionary_ = UnseededNumberDictionary::New(isolate(), infos->length());
   RelocateRelocInfos(infos, old_code, *code);
 }


 void TypeFeedbackOracle::RelocateRelocInfos(ZoneList<RelocInfo>* infos,
                                             Code* old_code,
                                             Code* new_code) {
   for (int i = 0; i < infos->length(); i++) {
     RelocInfo* info = &(*infos)[i];
     info->set_host(new_code);
     info->set_pc(new_code->instruction_start() +
                  (info->pc() - old_code->instruction_start()));
   }
 }


 void TypeFeedbackOracle::ProcessRelocInfos(ZoneList<RelocInfo>* infos) {
   for (int i = 0; i < infos->length(); i++) {
     RelocInfo reloc_entry = (*infos)[i];
     Address target_address = reloc_entry.target_address();
     TypeFeedbackId ast_id =
         TypeFeedbackId(static_cast<unsigned>((*infos)[i].data()));
     Code* target = Code::GetCodeFromTargetAddress(target_address);
     switch (target->kind()) {
       case Code::LOAD_IC:
       case Code::STORE_IC:
       case Code::KEYED_LOAD_IC:
       case Code::KEYED_STORE_IC:
       case Code::BINARY_OP_IC:
       case Code::COMPARE_IC:
       case Code::TO_BOOLEAN_IC:
         SetInfo(ast_id, target);
         break;

       default:
         break;
     }
   }
 }


 void TypeFeedbackOracle::SetInfo(TypeFeedbackId ast_id, Object* target) {
   DCHECK(dictionary_->FindEntry(IdToKey(ast_id)) ==
          UnseededNumberDictionary::kNotFound);
   // Dictionary has been allocated with sufficient size for all elements.
   DisallowHeapAllocation no_need_to_resize_dictionary;
   HandleScope scope(isolate());
   USE(UnseededNumberDictionary::AtNumberPut(
       dictionary_, IdToKey(ast_id), handle(target, isolate())));
 }


 }  // namespace internal
 }  // namespace v8
	// 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.

	#include "src/type-info.h"

	#include "src/ast/ast.h"
	#include "src/code-stubs.h"
	#include "src/ic/ic.h"
	#include "src/ic/stub-cache.h"
	#include "src/objects-inl.h"

	namespace v8 {
	namespace internal {


	TypeFeedbackOracle::TypeFeedbackOracle(
	Isolate* isolate, Zone* zone, Handle<Code> code,
	Handle<TypeFeedbackVector> feedback_vector, Handle<Context> native_context)
	: native_context_(native_context), isolate_(isolate), zone_(zone) {
	BuildDictionary(code);
	DCHECK(dictionary_->IsUnseededNumberDictionary());
	// We make a copy of the feedback vector because a GC could clear
	// the type feedback info contained therein.
	// TODO(mvstanton): revisit the decision to copy when we weakly
	// traverse the feedback vector at GC time.
	feedback_vector_ = TypeFeedbackVector::Copy(isolate, feedback_vector);
	}


	static uint32_t IdToKey(TypeFeedbackId ast_id) {
	return static_cast<uint32_t>(ast_id.ToInt());
	}


	Handle<Object> TypeFeedbackOracle::GetInfo(TypeFeedbackId ast_id) {
	int entry = dictionary_->FindEntry(IdToKey(ast_id));
	if (entry != UnseededNumberDictionary::kNotFound) {
	Object* value = dictionary_->ValueAt(entry);
	if (value->IsCell()) {
	Cell* cell = Cell::cast(value);
	return Handle<Object>(cell->value(), isolate());
	} else {
	return Handle<Object>(value, isolate());
	}
	}
	return Handle<Object>::cast(isolate()->factory()->undefined_value());
	}


	Handle<Object> TypeFeedbackOracle::GetInfo(FeedbackVectorSlot slot) {
	DCHECK(slot.ToInt() >= 0 && slot.ToInt() < feedback_vector_->length());
	Handle<Object> undefined =
	Handle<Object>::cast(isolate()->factory()->undefined_value());
	Object* obj = feedback_vector_->Get(slot);

	// Slots do not embed direct pointers to maps, functions. Instead
	// a WeakCell is always used.
	if (obj->IsWeakCell()) {
	WeakCell* cell = WeakCell::cast(obj);
	if (cell->cleared()) return undefined;
	obj = cell->value();
	}

	if (obj->IsJSFunction() \|\| obj->IsAllocationSite() \|\| obj->IsSymbol() \|\|
	obj->IsSimd128Value()) {
	return Handle<Object>(obj, isolate());
	}

	return undefined;
	}


	InlineCacheState TypeFeedbackOracle::LoadInlineCacheState(
	FeedbackVectorSlot slot) {
	if (!slot.IsInvalid()) {
	FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
	if (kind == FeedbackVectorSlotKind::LOAD_IC) {
	LoadICNexus nexus(feedback_vector_, slot);
	return nexus.StateFromFeedback();
	} else if (kind == FeedbackVectorSlotKind::KEYED_LOAD_IC) {
	KeyedLoadICNexus nexus(feedback_vector_, slot);
	return nexus.StateFromFeedback();
	}
	}

	// If we can't find an IC, assume we've seen something, but we don't know
	// what. PREMONOMORPHIC roughly encodes this meaning.
	return PREMONOMORPHIC;
	}


	bool TypeFeedbackOracle::StoreIsUninitialized(FeedbackVectorSlot slot) {
	if (!slot.IsInvalid()) {
	FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
	if (kind == FeedbackVectorSlotKind::STORE_IC) {
	StoreICNexus nexus(feedback_vector_, slot);
	return nexus.StateFromFeedback() == UNINITIALIZED;
	} else if (kind == FeedbackVectorSlotKind::KEYED_STORE_IC) {
	KeyedStoreICNexus nexus(feedback_vector_, slot);
	return nexus.StateFromFeedback() == UNINITIALIZED;
	}
	}
	return true;
	}


	bool TypeFeedbackOracle::CallIsUninitialized(FeedbackVectorSlot slot) {
	Handle<Object> value = GetInfo(slot);
	return value->IsUndefined(isolate()) \|\|
	value.is_identical_to(
	TypeFeedbackVector::UninitializedSentinel(isolate()));
	}


	bool TypeFeedbackOracle::CallIsMonomorphic(FeedbackVectorSlot slot) {
	Handle<Object> value = GetInfo(slot);
	return value->IsAllocationSite() \|\| value->IsJSFunction();
	}


	bool TypeFeedbackOracle::CallNewIsMonomorphic(FeedbackVectorSlot slot) {
	Handle<Object> info = GetInfo(slot);
	return info->IsAllocationSite() \|\| info->IsJSFunction();
	}


	byte TypeFeedbackOracle::ForInType(FeedbackVectorSlot feedback_vector_slot) {
	Handle<Object> value = GetInfo(feedback_vector_slot);
	return value.is_identical_to(
	TypeFeedbackVector::UninitializedSentinel(isolate()))
	? ForInStatement::FAST_FOR_IN
	: ForInStatement::SLOW_FOR_IN;
	}


	void TypeFeedbackOracle::GetStoreModeAndKeyType(
	FeedbackVectorSlot slot, KeyedAccessStoreMode* store_mode,
	IcCheckType* key_type) {
	if (!slot.IsInvalid() &&
	feedback_vector_->GetKind(slot) ==
	FeedbackVectorSlotKind::KEYED_STORE_IC) {
	KeyedStoreICNexus nexus(feedback_vector_, slot);
	*store_mode = nexus.GetKeyedAccessStoreMode();
	*key_type = nexus.GetKeyType();
	} else {
	*store_mode = STANDARD_STORE;
	*key_type = ELEMENT;
	}
	}


	Handle<JSFunction> TypeFeedbackOracle::GetCallTarget(FeedbackVectorSlot slot) {
	Handle<Object> info = GetInfo(slot);
	if (info->IsAllocationSite()) {
	return Handle<JSFunction>(isolate()->native_context()->array_function());
	}

	return Handle<JSFunction>::cast(info);
	}


	Handle<JSFunction> TypeFeedbackOracle::GetCallNewTarget(
	FeedbackVectorSlot slot) {
	Handle<Object> info = GetInfo(slot);
	if (info->IsJSFunction()) {
	return Handle<JSFunction>::cast(info);
	}

	DCHECK(info->IsAllocationSite());
	return Handle<JSFunction>(isolate()->native_context()->array_function());
	}


	Handle<AllocationSite> TypeFeedbackOracle::GetCallAllocationSite(
	FeedbackVectorSlot slot) {
	Handle<Object> info = GetInfo(slot);
	if (info->IsAllocationSite()) {
	return Handle<AllocationSite>::cast(info);
	}
	return Handle<AllocationSite>::null();
	}


	Handle<AllocationSite> TypeFeedbackOracle::GetCallNewAllocationSite(
	FeedbackVectorSlot slot) {
	Handle<Object> info = GetInfo(slot);
	if (info->IsAllocationSite()) {
	return Handle<AllocationSite>::cast(info);
	}
	return Handle<AllocationSite>::null();
	}

	namespace {

	AstType* CompareOpHintToType(CompareOperationHint hint) {
	switch (hint) {
	case CompareOperationHint::kNone:
	return AstType::None();
	case CompareOperationHint::kSignedSmall:
	return AstType::SignedSmall();
	case CompareOperationHint::kNumber:
	return AstType::Number();
	case CompareOperationHint::kNumberOrOddball:
	return AstType::NumberOrOddball();
	case CompareOperationHint::kAny:
	return AstType::Any();
	}
	UNREACHABLE();
	return AstType::None();
	}

	AstType* BinaryOpFeedbackToType(int hint) {
	switch (hint) {
	case BinaryOperationFeedback::kNone:
	return AstType::None();
	case BinaryOperationFeedback::kSignedSmall:
	return AstType::SignedSmall();
	case BinaryOperationFeedback::kNumber:
	return AstType::Number();
	case BinaryOperationFeedback::kString:
	return AstType::String();
	// TODO(mythria): Merge Number and NumberOrOddball feedback, after
	// fixing crankshaft to handle Oddballs along with Numbers.
	case BinaryOperationFeedback::kNumberOrOddball:
	case BinaryOperationFeedback::kAny:
	default:
	return AstType::Any();
	}
	UNREACHABLE();
	return AstType::None();
	}

	} // end anonymous namespace

	void TypeFeedbackOracle::CompareType(TypeFeedbackId id, FeedbackVectorSlot slot,
	AstType left_type, AstType right_type,
	AstType** combined_type) {
	Handle<Object> info = GetInfo(id);
	// A check for a valid slot is not sufficient here. InstanceOf collects
	// type feedback in a General slot.
	if (!info->IsCode()) {
	// For some comparisons we don't have type feedback, e.g.
	// LiteralCompareTypeof.
	left_type = right_type = *combined_type = AstType::None();
	return;
	}

	// Feedback from Ignition. The feedback slot will be allocated and initialized
	// to AstType::None() even when ignition is not enabled. So it is safe to get
	// feedback from the type feedback vector.
	DCHECK(!slot.IsInvalid());
	CompareICNexus nexus(feedback_vector_, slot);
	left_type = right_type = *combined_type =
	CompareOpHintToType(nexus.GetCompareOperationFeedback());

	// Merge the feedback from full-codegen if available.
	Handle<Code> code = Handle<Code>::cast(info);
	Handle<Map> map;
	Map* raw_map = code->FindFirstMap();
	if (raw_map != NULL) Map::TryUpdate(handle(raw_map)).ToHandle(&map);

	if (code->is_compare_ic_stub()) {
	CompareICStub stub(code->stub_key(), isolate());
	AstType* left_type_from_ic =
	CompareICState::StateToType(zone(), stub.left());
	left_type = AstType::Union(left_type, left_type_from_ic, zone());
	AstType* right_type_from_ic =
	CompareICState::StateToType(zone(), stub.right());
	right_type = AstType::Union(right_type, right_type_from_ic, zone());
	AstType* combined_type_from_ic =
	CompareICState::StateToType(zone(), stub.state(), map);
	*combined_type =
	AstType::Union(*combined_type, combined_type_from_ic, zone());
	}
	}

	void TypeFeedbackOracle::BinaryType(TypeFeedbackId id, FeedbackVectorSlot slot,
	AstType left, AstType right,
	AstType** result,
	Maybe<int>* fixed_right_arg,
	Handle<AllocationSite>* allocation_site,
	Token::Value op) {
	Handle<Object> object = GetInfo(id);
	if (slot.IsInvalid()) {
	// For some binary ops we don't have ICs or feedback slots,
	// e.g. Token::COMMA, but for the operations covered by the BinaryOpIC we
	// should always have them.
	DCHECK(!object->IsCode());
	DCHECK(op < BinaryOpICState::FIRST_TOKEN \|\|
	op > BinaryOpICState::LAST_TOKEN);
	left = right = *result = AstType::None();
	*fixed_right_arg = Nothing<int>();
	*allocation_site = Handle<AllocationSite>::null();
	return;
	}

	// Feedback from Ignition. The feedback slot will be allocated and initialized
	// to AstType::None() even when ignition is not enabled. So it is safe to get
	// feedback from the type feedback vector.
	DCHECK(!slot.IsInvalid());
	BinaryOpICNexus nexus(feedback_vector_, slot);
	left = right = *result =
	BinaryOpFeedbackToType(Smi::cast(nexus.GetFeedback())->value());
	*fixed_right_arg = Nothing<int>();
	*allocation_site = Handle<AllocationSite>::null();

	if (!object->IsCode()) return;

	// Merge the feedback from full-codegen if available.
	Handle<Code> code = Handle<Code>::cast(object);
	DCHECK_EQ(Code::BINARY_OP_IC, code->kind());
	BinaryOpICState state(isolate(), code->extra_ic_state());
	DCHECK_EQ(op, state.op());

	left = AstType::Union(left, state.GetLeftType(), zone());
	right = AstType::Union(right, state.GetRightType(), zone());
	result = AstType::Union(result, state.GetResultType(), zone());
	*fixed_right_arg = state.fixed_right_arg();

	AllocationSite* first_allocation_site = code->FindFirstAllocationSite();
	if (first_allocation_site != NULL) {
	*allocation_site = handle(first_allocation_site);
	} else {
	*allocation_site = Handle<AllocationSite>::null();
	}
	}

	AstType* TypeFeedbackOracle::CountType(TypeFeedbackId id,
	FeedbackVectorSlot slot) {
	Handle<Object> object = GetInfo(id);
	if (slot.IsInvalid()) {
	DCHECK(!object->IsCode());
	return AstType::None();
	}

	DCHECK(!slot.IsInvalid());
	BinaryOpICNexus nexus(feedback_vector_, slot);
	AstType* type =
	BinaryOpFeedbackToType(Smi::cast(nexus.GetFeedback())->value());

	if (!object->IsCode()) return type;

	Handle<Code> code = Handle<Code>::cast(object);
	DCHECK_EQ(Code::BINARY_OP_IC, code->kind());
	BinaryOpICState state(isolate(), code->extra_ic_state());
	return AstType::Union(type, state.GetLeftType(), zone());
	}


	bool TypeFeedbackOracle::HasOnlyStringMaps(SmallMapList* receiver_types) {
	bool all_strings = receiver_types->length() > 0;
	for (int i = 0; i < receiver_types->length(); i++) {
	all_strings &= receiver_types->at(i)->IsStringMap();
	}
	return all_strings;
	}


	void TypeFeedbackOracle::PropertyReceiverTypes(FeedbackVectorSlot slot,
	Handle<Name> name,
	SmallMapList* receiver_types) {
	receiver_types->Clear();
	if (!slot.IsInvalid()) {
	LoadICNexus nexus(feedback_vector_, slot);
	CollectReceiverTypes(isolate()->load_stub_cache(), &nexus, name,
	receiver_types);
	}
	}


	void TypeFeedbackOracle::KeyedPropertyReceiverTypes(
	FeedbackVectorSlot slot, SmallMapList* receiver_types, bool* is_string,
	IcCheckType* key_type) {
	receiver_types->Clear();
	if (slot.IsInvalid()) {
	*is_string = false;
	*key_type = ELEMENT;
	} else {
	KeyedLoadICNexus nexus(feedback_vector_, slot);
	CollectReceiverTypes(&nexus, receiver_types);
	*is_string = HasOnlyStringMaps(receiver_types);
	*key_type = nexus.GetKeyType();
	}
	}


	void TypeFeedbackOracle::AssignmentReceiverTypes(FeedbackVectorSlot slot,
	Handle<Name> name,
	SmallMapList* receiver_types) {
	receiver_types->Clear();
	CollectReceiverTypes(isolate()->store_stub_cache(), slot, name,
	receiver_types);
	}


	void TypeFeedbackOracle::KeyedAssignmentReceiverTypes(
	FeedbackVectorSlot slot, SmallMapList* receiver_types,
	KeyedAccessStoreMode* store_mode, IcCheckType* key_type) {
	receiver_types->Clear();
	CollectReceiverTypes(slot, receiver_types);
	GetStoreModeAndKeyType(slot, store_mode, key_type);
	}


	void TypeFeedbackOracle::CountReceiverTypes(FeedbackVectorSlot slot,
	SmallMapList* receiver_types) {
	receiver_types->Clear();
	if (!slot.IsInvalid()) CollectReceiverTypes(slot, receiver_types);
	}

	void TypeFeedbackOracle::CollectReceiverTypes(StubCache* stub_cache,
	FeedbackVectorSlot slot,
	Handle<Name> name,
	SmallMapList* types) {
	StoreICNexus nexus(feedback_vector_, slot);
	CollectReceiverTypes(stub_cache, &nexus, name, types);
	}

	void TypeFeedbackOracle::CollectReceiverTypes(StubCache* stub_cache,
	FeedbackNexus* nexus,
	Handle<Name> name,
	SmallMapList* types) {
	if (FLAG_collect_megamorphic_maps_from_stub_cache &&
	nexus->ic_state() == MEGAMORPHIC) {
	types->Reserve(4, zone());
	stub_cache->CollectMatchingMaps(types, name, native_context_, zone());
	} else {
	CollectReceiverTypes(nexus, types);
	}
	}


	void TypeFeedbackOracle::CollectReceiverTypes(FeedbackVectorSlot slot,
	SmallMapList* types) {
	FeedbackVectorSlotKind kind = feedback_vector_->GetKind(slot);
	if (kind == FeedbackVectorSlotKind::STORE_IC) {
	StoreICNexus nexus(feedback_vector_, slot);
	CollectReceiverTypes(&nexus, types);
	} else {
	DCHECK_EQ(FeedbackVectorSlotKind::KEYED_STORE_IC, kind);
	KeyedStoreICNexus nexus(feedback_vector_, slot);
	CollectReceiverTypes(&nexus, types);
	}
	}

	void TypeFeedbackOracle::CollectReceiverTypes(FeedbackNexus* nexus,
	SmallMapList* types) {
	MapHandleList maps;
	if (nexus->ic_state() == MONOMORPHIC) {
	Map* map = nexus->FindFirstMap();
	if (map != NULL) maps.Add(handle(map));
	} else if (nexus->ic_state() == POLYMORPHIC) {
	nexus->FindAllMaps(&maps);
	} else {
	return;
	}
	types->Reserve(maps.length(), zone());
	for (int i = 0; i < maps.length(); i++) {
	Handle<Map> map(maps.at(i));
	if (IsRelevantFeedback(map, native_context_)) {
	types->AddMapIfMissing(maps.at(i), zone());
	}
	}
	}


	uint16_t TypeFeedbackOracle::ToBooleanTypes(TypeFeedbackId id) {
	Handle<Object> object = GetInfo(id);
	return object->IsCode() ? Handle<Code>::cast(object)->to_boolean_state() : 0;
	}


	// Things are a bit tricky here: The iterator for the RelocInfos and the infos
	// themselves are not GC-safe, so we first get all infos, then we create the
	// dictionary (possibly triggering GC), and finally we relocate the collected
	// infos before we process them.
	void TypeFeedbackOracle::BuildDictionary(Handle<Code> code) {
	DisallowHeapAllocation no_allocation;
	ZoneList<RelocInfo> infos(16, zone());
	HandleScope scope(isolate());
	GetRelocInfos(code, &infos);
	CreateDictionary(code, &infos);
	ProcessRelocInfos(&infos);
	// Allocate handle in the parent scope.
	dictionary_ = scope.CloseAndEscape(dictionary_);
	}


	void TypeFeedbackOracle::GetRelocInfos(Handle<Code> code,
	ZoneList<RelocInfo>* infos) {
	int mask = RelocInfo::ModeMask(RelocInfo::CODE_TARGET_WITH_ID);
	for (RelocIterator it(*code, mask); !it.done(); it.next()) {
	infos->Add(*it.rinfo(), zone());
	}
	}


	void TypeFeedbackOracle::CreateDictionary(Handle<Code> code,
	ZoneList<RelocInfo>* infos) {
	AllowHeapAllocation allocation_allowed;
	Code* old_code = *code;
	dictionary_ = UnseededNumberDictionary::New(isolate(), infos->length());
	RelocateRelocInfos(infos, old_code, *code);
	}


	void TypeFeedbackOracle::RelocateRelocInfos(ZoneList<RelocInfo>* infos,
	Code* old_code,
	Code* new_code) {
	for (int i = 0; i < infos->length(); i++) {
	RelocInfo* info = &(*infos)[i];
	info->set_host(new_code);
	info->set_pc(new_code->instruction_start() +
	(info->pc() - old_code->instruction_start()));
	}
	}


	void TypeFeedbackOracle::ProcessRelocInfos(ZoneList<RelocInfo>* infos) {
	for (int i = 0; i < infos->length(); i++) {
	RelocInfo reloc_entry = (*infos)[i];
	Address target_address = reloc_entry.target_address();
	TypeFeedbackId ast_id =
	TypeFeedbackId(static_cast<unsigned>((*infos)[i].data()));
	Code* target = Code::GetCodeFromTargetAddress(target_address);
	switch (target->kind()) {
	case Code::LOAD_IC:
	case Code::STORE_IC:
	case Code::KEYED_LOAD_IC:
	case Code::KEYED_STORE_IC:
	case Code::BINARY_OP_IC:
	case Code::COMPARE_IC:
	case Code::TO_BOOLEAN_IC:
	SetInfo(ast_id, target);
	break;

	default:
	break;
	}
	}
	}


	void TypeFeedbackOracle::SetInfo(TypeFeedbackId ast_id, Object* target) {
	DCHECK(dictionary_->FindEntry(IdToKey(ast_id)) ==
	UnseededNumberDictionary::kNotFound);
	// Dictionary has been allocated with sufficient size for all elements.
	DisallowHeapAllocation no_need_to_resize_dictionary;
	HandleScope scope(isolate());
	USE(UnseededNumberDictionary::AtNumberPut(
	dictionary_, IdToKey(ast_id), handle(target, isolate())));
	}


	} // namespace internal
	} // namespace v8