src/property.h - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2012 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #ifndef V8_PROPERTY_H_
 #define V8_PROPERTY_H_

 #include "allocation.h"
 #include "transitions.h"

 namespace v8 {
 namespace internal {


 // Abstraction for elements in instance-descriptor arrays.
 //
 // Each descriptor has a key, property attributes, property type,
 // property index (in the actual instance-descriptor array) and
 // optionally a piece of data.
 //

 class Descriptor BASE_EMBEDDED {
  public:
   MUST_USE_RESULT MaybeObject* KeyToUniqueName() {
     if (!key_->IsUniqueName()) {
       MaybeObject* maybe_result = HEAP->InternalizeString(String::cast(key_));
       if (!maybe_result->To(&key_)) return maybe_result;
     }
     return key_;
   }

   Name* GetKey() { return key_; }
   Object* GetValue() { return value_; }
   PropertyDetails GetDetails() { return details_; }

 #ifdef OBJECT_PRINT
   void Print(FILE* out);
 #endif

   void SetSortedKeyIndex(int index) { details_ = details_.set_pointer(index); }

  private:
   Name* key_;
   Object* value_;
   PropertyDetails details_;

  protected:
   Descriptor() : details_(Smi::FromInt(0)) {}

   void Init(Name* key, Object* value, PropertyDetails details) {
     key_ = key;
     value_ = value;
     details_ = details;
   }

   Descriptor(Name* key, Object* value, PropertyDetails details)
       : key_(key),
         value_(value),
         details_(details) { }

   Descriptor(Name* key,
              Object* value,
              PropertyAttributes attributes,
              PropertyType type,
              Representation representation,
              int field_index = 0)
       : key_(key),
         value_(value),
         details_(attributes, type, representation, field_index) { }

   friend class DescriptorArray;
 };


 class FieldDescriptor: public Descriptor {
  public:
   FieldDescriptor(Name* key,
                   int field_index,
                   PropertyAttributes attributes,
                   Representation representation)
       : Descriptor(key, Smi::FromInt(0), attributes,
                    FIELD, representation, field_index) {}
 };


 class ConstantDescriptor: public Descriptor {
  public:
   ConstantDescriptor(Name* key,
                      Object* value,
                      PropertyAttributes attributes)
       : Descriptor(key, value, attributes, CONSTANT,
                    value->OptimalRepresentation()) {}
 };


 class CallbacksDescriptor:  public Descriptor {
  public:
   CallbacksDescriptor(Name* key,
                       Object* foreign,
                       PropertyAttributes attributes)
       : Descriptor(key, foreign, attributes, CALLBACKS,
                    Representation::Tagged()) {}
 };


 // Holds a property index value distinguishing if it is a field index or an
 // index inside the object header.
 class PropertyIndex {
  public:
   static PropertyIndex NewFieldIndex(int index) {
     return PropertyIndex(index, false);
   }
   static PropertyIndex NewHeaderIndex(int index) {
     return PropertyIndex(index, true);
   }

   bool is_field_index() { return (index_ & kHeaderIndexBit) == 0; }
   bool is_header_index() { return (index_ & kHeaderIndexBit) != 0; }

   int field_index() {
     ASSERT(is_field_index());
     return value();
   }
   int header_index() {
     ASSERT(is_header_index());
     return value();
   }

   bool is_inobject(Handle<JSObject> holder) {
     if (is_header_index()) return true;
     return field_index() < holder->map()->inobject_properties();
   }

   int translate(Handle<JSObject> holder) {
     if (is_header_index()) return header_index();
     int index = field_index() - holder->map()->inobject_properties();
     if (index >= 0) return index;
     return index + holder->map()->instance_size() / kPointerSize;
   }

  private:
   static const int kHeaderIndexBit = 1 << 31;
   static const int kIndexMask = ~kHeaderIndexBit;

   int value() { return index_ & kIndexMask; }

   PropertyIndex(int index, bool is_header_based)
       : index_(index | (is_header_based ? kHeaderIndexBit : 0)) {
     ASSERT(index <= kIndexMask);
   }

   int index_;
 };


 class LookupResult BASE_EMBEDDED {
  public:
   explicit LookupResult(Isolate* isolate)
       : isolate_(isolate),
         next_(isolate->top_lookup_result()),
         lookup_type_(NOT_FOUND),
         holder_(NULL),
         cacheable_(true),
         details_(NONE, NONEXISTENT, Representation::None()) {
     isolate->SetTopLookupResult(this);
   }

   ~LookupResult() {
     ASSERT(isolate()->top_lookup_result() == this);
     isolate()->SetTopLookupResult(next_);
   }

   Isolate* isolate() const { return isolate_; }

   void DescriptorResult(JSObject* holder, PropertyDetails details, int number) {
     lookup_type_ = DESCRIPTOR_TYPE;
     holder_ = holder;
     details_ = details;
     number_ = number;
   }

   bool CanHoldValue(Handle<Object> value) {
     if (IsNormal()) return true;
     ASSERT(!IsTransition());
     return value->FitsRepresentation(details_.representation());
   }

   void TransitionResult(JSObject* holder, int number) {
     lookup_type_ = TRANSITION_TYPE;
     details_ = PropertyDetails(NONE, TRANSITION, Representation::None());
     holder_ = holder;
     number_ = number;
   }

   void DictionaryResult(JSObject* holder, int entry) {
     lookup_type_ = DICTIONARY_TYPE;
     holder_ = holder;
     details_ = holder->property_dictionary()->DetailsAt(entry);
     number_ = entry;
   }

   void HandlerResult(JSProxy* proxy) {
     lookup_type_ = HANDLER_TYPE;
     holder_ = proxy;
     details_ = PropertyDetails(NONE, HANDLER, Representation::Tagged());
     cacheable_ = false;
   }

   void InterceptorResult(JSObject* holder) {
     lookup_type_ = INTERCEPTOR_TYPE;
     holder_ = holder;
     details_ = PropertyDetails(NONE, INTERCEPTOR, Representation::Tagged());
   }

   void NotFound() {
     lookup_type_ = NOT_FOUND;
     details_ = PropertyDetails(NONE, NONEXISTENT, Representation::None());
     holder_ = NULL;
   }

   JSObject* holder() {
     ASSERT(IsFound());
     return JSObject::cast(holder_);
   }

   JSProxy* proxy() {
     ASSERT(IsFound());
     return JSProxy::cast(holder_);
   }

   PropertyType type() {
     ASSERT(IsFound());
     return details_.type();
   }

   Representation representation() {
     ASSERT(IsFound());
     ASSERT(!IsTransition());
     ASSERT(details_.type() != NONEXISTENT);
     return details_.representation();
   }

   PropertyAttributes GetAttributes() {
     ASSERT(!IsTransition());
     ASSERT(IsFound());
     ASSERT(details_.type() != NONEXISTENT);
     return details_.attributes();
   }

   PropertyDetails GetPropertyDetails() {
     ASSERT(!IsTransition());
     return details_;
   }

   bool IsFastPropertyType() {
     ASSERT(IsFound());
     return IsTransition() || type() != NORMAL;
   }

   // Property callbacks does not include transitions to callbacks.
   bool IsPropertyCallbacks() {
     ASSERT(!(details_.type() == CALLBACKS && !IsFound()));
     return details_.type() == CALLBACKS;
   }

   bool IsReadOnly() {
     ASSERT(IsFound());
     ASSERT(!IsTransition());
     ASSERT(details_.type() != NONEXISTENT);
     return details_.IsReadOnly();
   }

   bool IsField() {
     ASSERT(!(details_.type() == FIELD && !IsFound()));
     return details_.type() == FIELD;
   }

   bool IsNormal() {
     ASSERT(!(details_.type() == NORMAL && !IsFound()));
     return details_.type() == NORMAL;
   }

   bool IsConstant() {
     ASSERT(!(details_.type() == CONSTANT && !IsFound()));
     return details_.type() == CONSTANT;
   }

   bool IsConstantFunction() {
     return IsConstant() && GetValue()->IsJSFunction();
   }

   bool IsDontDelete() { return details_.IsDontDelete(); }
   bool IsDontEnum() { return details_.IsDontEnum(); }
   bool IsFound() { return lookup_type_ != NOT_FOUND; }
   bool IsTransition() { return lookup_type_ == TRANSITION_TYPE; }
   bool IsHandler() { return lookup_type_ == HANDLER_TYPE; }
   bool IsInterceptor() { return lookup_type_ == INTERCEPTOR_TYPE; }

   // Is the result is a property excluding transitions and the null descriptor?
   bool IsProperty() {
     return IsFound() && !IsTransition();
   }

   bool IsDataProperty() {
     switch (type()) {
       case FIELD:
       case NORMAL:
       case CONSTANT:
         return true;
       case CALLBACKS: {
         Object* callback = GetCallbackObject();
         return callback->IsAccessorInfo() || callback->IsForeign();
       }
       case HANDLER:
       case INTERCEPTOR:
       case TRANSITION:
       case NONEXISTENT:
         return false;
     }
     UNREACHABLE();
     return false;
   }

   bool IsCacheable() { return cacheable_; }
   void DisallowCaching() { cacheable_ = false; }

   Object* GetLazyValue() {
     switch (type()) {
       case FIELD:
         return holder()->RawFastPropertyAt(GetFieldIndex().field_index());
       case NORMAL: {
         Object* value;
         value = holder()->property_dictionary()->ValueAt(GetDictionaryEntry());
         if (holder()->IsGlobalObject()) {
           value = PropertyCell::cast(value)->value();
         }
         return value;
       }
       case CONSTANT:
         return GetConstant();
       case CALLBACKS:
       case HANDLER:
       case INTERCEPTOR:
       case TRANSITION:
       case NONEXISTENT:
         return isolate()->heap()->the_hole_value();
     }
     UNREACHABLE();
     return NULL;
   }

   Map* GetTransitionTarget(Map* map) {
     ASSERT(IsTransition());
     TransitionArray* transitions = map->transitions();
     return transitions->GetTarget(number_);
   }

   Map* GetTransitionTarget() {
     return GetTransitionTarget(holder()->map());
   }

   PropertyDetails GetTransitionDetails(Map* map) {
     ASSERT(IsTransition());
     TransitionArray* transitions = map->transitions();
     return transitions->GetTargetDetails(number_);
   }

   PropertyDetails GetTransitionDetails() {
     return GetTransitionDetails(holder()->map());
   }

   bool IsTransitionToField(Map* map) {
     return IsTransition() && GetTransitionDetails(map).type() == FIELD;
   }

   bool IsTransitionToConstant(Map* map) {
     return IsTransition() && GetTransitionDetails(map).type() == CONSTANT;
   }

   Map* GetTransitionMap() {
     ASSERT(IsTransition());
     return Map::cast(GetValue());
   }

   Map* GetTransitionMapFromMap(Map* map) {
     ASSERT(IsTransition());
     return map->transitions()->GetTarget(number_);
   }

   int GetTransitionIndex() {
     ASSERT(IsTransition());
     return number_;
   }

   int GetDescriptorIndex() {
     ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
     return number_;
   }

   PropertyIndex GetFieldIndex() {
     ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
     return PropertyIndex::NewFieldIndex(GetFieldIndexFromMap(holder()->map()));
   }

   int GetLocalFieldIndexFromMap(Map* map) {
     return GetFieldIndexFromMap(map) - map->inobject_properties();
   }

   int GetDictionaryEntry() {
     ASSERT(lookup_type_ == DICTIONARY_TYPE);
     return number_;
   }

   JSFunction* GetConstantFunction() {
     ASSERT(type() == CONSTANT);
     return JSFunction::cast(GetValue());
   }

   Object* GetConstantFromMap(Map* map) {
     ASSERT(type() == CONSTANT);
     return GetValueFromMap(map);
   }

   JSFunction* GetConstantFunctionFromMap(Map* map) {
     return JSFunction::cast(GetConstantFromMap(map));
   }

   Object* GetConstant() {
     ASSERT(type() == CONSTANT);
     return GetValue();
   }

   Object* GetCallbackObject() {
     ASSERT(type() == CALLBACKS && !IsTransition());
     return GetValue();
   }

 #ifdef OBJECT_PRINT
   void Print(FILE* out);
 #endif

   Object* GetValue() {
     if (lookup_type_ == DESCRIPTOR_TYPE) {
       return GetValueFromMap(holder()->map());
     }
     // In the dictionary case, the data is held in the value field.
     ASSERT(lookup_type_ == DICTIONARY_TYPE);
     return holder()->GetNormalizedProperty(this);
   }

   Object* GetValueFromMap(Map* map) const {
     ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
     ASSERT(number_ < map->NumberOfOwnDescriptors());
     return map->instance_descriptors()->GetValue(number_);
   }

   int GetFieldIndexFromMap(Map* map) const {
     ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
     ASSERT(number_ < map->NumberOfOwnDescriptors());
     return map->instance_descriptors()->GetFieldIndex(number_);
   }

   void Iterate(ObjectVisitor* visitor);

  private:
   Isolate* isolate_;
   LookupResult* next_;

   // Where did we find the result;
   enum {
     NOT_FOUND,
     DESCRIPTOR_TYPE,
     TRANSITION_TYPE,
     DICTIONARY_TYPE,
     HANDLER_TYPE,
     INTERCEPTOR_TYPE
   } lookup_type_;

   JSReceiver* holder_;
   int number_;
   bool cacheable_;
   PropertyDetails details_;
 };


 } }  // namespace v8::internal

 #endif  // V8_PROPERTY_H_
	// Copyright 2012 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#ifndef V8_PROPERTY_H_
	#define V8_PROPERTY_H_

	#include "allocation.h"
	#include "transitions.h"

	namespace v8 {
	namespace internal {


	// Abstraction for elements in instance-descriptor arrays.
	//
	// Each descriptor has a key, property attributes, property type,
	// property index (in the actual instance-descriptor array) and
	// optionally a piece of data.
	//

	class Descriptor BASE_EMBEDDED {
	public:
	MUST_USE_RESULT MaybeObject* KeyToUniqueName() {
	if (!key_->IsUniqueName()) {
	MaybeObject* maybe_result = HEAP->InternalizeString(String::cast(key_));
	if (!maybe_result->To(&key_)) return maybe_result;
	}
	return key_;
	}

	Name* GetKey() { return key_; }
	Object* GetValue() { return value_; }
	PropertyDetails GetDetails() { return details_; }

	#ifdef OBJECT_PRINT
	void Print(FILE* out);
	#endif

	void SetSortedKeyIndex(int index) { details_ = details_.set_pointer(index); }

	private:
	Name* key_;
	Object* value_;
	PropertyDetails details_;

	protected:
	Descriptor() : details_(Smi::FromInt(0)) {}

	void Init(Name* key, Object* value, PropertyDetails details) {
	key_ = key;
	value_ = value;
	details_ = details;
	}

	Descriptor(Name* key, Object* value, PropertyDetails details)
	: key_(key),
	value_(value),
	details_(details) { }

	Descriptor(Name* key,
	Object* value,
	PropertyAttributes attributes,
	PropertyType type,
	Representation representation,
	int field_index = 0)
	: key_(key),
	value_(value),
	details_(attributes, type, representation, field_index) { }

	friend class DescriptorArray;
	};


	class FieldDescriptor: public Descriptor {
	public:
	FieldDescriptor(Name* key,
	int field_index,
	PropertyAttributes attributes,
	Representation representation)
	: Descriptor(key, Smi::FromInt(0), attributes,
	FIELD, representation, field_index) {}
	};


	class ConstantDescriptor: public Descriptor {
	public:
	ConstantDescriptor(Name* key,
	Object* value,
	PropertyAttributes attributes)
	: Descriptor(key, value, attributes, CONSTANT,
	value->OptimalRepresentation()) {}
	};


	class CallbacksDescriptor: public Descriptor {
	public:
	CallbacksDescriptor(Name* key,
	Object* foreign,
	PropertyAttributes attributes)
	: Descriptor(key, foreign, attributes, CALLBACKS,
	Representation::Tagged()) {}
	};


	// Holds a property index value distinguishing if it is a field index or an
	// index inside the object header.
	class PropertyIndex {
	public:
	static PropertyIndex NewFieldIndex(int index) {
	return PropertyIndex(index, false);
	}
	static PropertyIndex NewHeaderIndex(int index) {
	return PropertyIndex(index, true);
	}

	bool is_field_index() { return (index_ & kHeaderIndexBit) == 0; }
	bool is_header_index() { return (index_ & kHeaderIndexBit) != 0; }

	int field_index() {
	ASSERT(is_field_index());
	return value();
	}
	int header_index() {
	ASSERT(is_header_index());
	return value();
	}

	bool is_inobject(Handle<JSObject> holder) {
	if (is_header_index()) return true;
	return field_index() < holder->map()->inobject_properties();
	}

	int translate(Handle<JSObject> holder) {
	if (is_header_index()) return header_index();
	int index = field_index() - holder->map()->inobject_properties();
	if (index >= 0) return index;
	return index + holder->map()->instance_size() / kPointerSize;
	}

	private:
	static const int kHeaderIndexBit = 1 << 31;
	static const int kIndexMask = ~kHeaderIndexBit;

	int value() { return index_ & kIndexMask; }

	PropertyIndex(int index, bool is_header_based)
	: index_(index \| (is_header_based ? kHeaderIndexBit : 0)) {
	ASSERT(index <= kIndexMask);
	}

	int index_;
	};


	class LookupResult BASE_EMBEDDED {
	public:
	explicit LookupResult(Isolate* isolate)
	: isolate_(isolate),
	next_(isolate->top_lookup_result()),
	lookup_type_(NOT_FOUND),
	holder_(NULL),
	cacheable_(true),
	details_(NONE, NONEXISTENT, Representation::None()) {
	isolate->SetTopLookupResult(this);
	}

	~LookupResult() {
	ASSERT(isolate()->top_lookup_result() == this);
	isolate()->SetTopLookupResult(next_);
	}

	Isolate* isolate() const { return isolate_; }

	void DescriptorResult(JSObject* holder, PropertyDetails details, int number) {
	lookup_type_ = DESCRIPTOR_TYPE;
	holder_ = holder;
	details_ = details;
	number_ = number;
	}

	bool CanHoldValue(Handle<Object> value) {
	if (IsNormal()) return true;
	ASSERT(!IsTransition());
	return value->FitsRepresentation(details_.representation());
	}

	void TransitionResult(JSObject* holder, int number) {
	lookup_type_ = TRANSITION_TYPE;
	details_ = PropertyDetails(NONE, TRANSITION, Representation::None());
	holder_ = holder;
	number_ = number;
	}

	void DictionaryResult(JSObject* holder, int entry) {
	lookup_type_ = DICTIONARY_TYPE;
	holder_ = holder;
	details_ = holder->property_dictionary()->DetailsAt(entry);
	number_ = entry;
	}

	void HandlerResult(JSProxy* proxy) {
	lookup_type_ = HANDLER_TYPE;
	holder_ = proxy;
	details_ = PropertyDetails(NONE, HANDLER, Representation::Tagged());
	cacheable_ = false;
	}

	void InterceptorResult(JSObject* holder) {
	lookup_type_ = INTERCEPTOR_TYPE;
	holder_ = holder;
	details_ = PropertyDetails(NONE, INTERCEPTOR, Representation::Tagged());
	}

	void NotFound() {
	lookup_type_ = NOT_FOUND;
	details_ = PropertyDetails(NONE, NONEXISTENT, Representation::None());
	holder_ = NULL;
	}

	JSObject* holder() {
	ASSERT(IsFound());
	return JSObject::cast(holder_);
	}

	JSProxy* proxy() {
	ASSERT(IsFound());
	return JSProxy::cast(holder_);
	}

	PropertyType type() {
	ASSERT(IsFound());
	return details_.type();
	}

	Representation representation() {
	ASSERT(IsFound());
	ASSERT(!IsTransition());
	ASSERT(details_.type() != NONEXISTENT);
	return details_.representation();
	}

	PropertyAttributes GetAttributes() {
	ASSERT(!IsTransition());
	ASSERT(IsFound());
	ASSERT(details_.type() != NONEXISTENT);
	return details_.attributes();
	}

	PropertyDetails GetPropertyDetails() {
	ASSERT(!IsTransition());
	return details_;
	}

	bool IsFastPropertyType() {
	ASSERT(IsFound());
	return IsTransition() \|\| type() != NORMAL;
	}

	// Property callbacks does not include transitions to callbacks.
	bool IsPropertyCallbacks() {
	ASSERT(!(details_.type() == CALLBACKS && !IsFound()));
	return details_.type() == CALLBACKS;
	}

	bool IsReadOnly() {
	ASSERT(IsFound());
	ASSERT(!IsTransition());
	ASSERT(details_.type() != NONEXISTENT);
	return details_.IsReadOnly();
	}

	bool IsField() {
	ASSERT(!(details_.type() == FIELD && !IsFound()));
	return details_.type() == FIELD;
	}

	bool IsNormal() {
	ASSERT(!(details_.type() == NORMAL && !IsFound()));
	return details_.type() == NORMAL;
	}

	bool IsConstant() {
	ASSERT(!(details_.type() == CONSTANT && !IsFound()));
	return details_.type() == CONSTANT;
	}

	bool IsConstantFunction() {
	return IsConstant() && GetValue()->IsJSFunction();
	}

	bool IsDontDelete() { return details_.IsDontDelete(); }
	bool IsDontEnum() { return details_.IsDontEnum(); }
	bool IsFound() { return lookup_type_ != NOT_FOUND; }
	bool IsTransition() { return lookup_type_ == TRANSITION_TYPE; }
	bool IsHandler() { return lookup_type_ == HANDLER_TYPE; }
	bool IsInterceptor() { return lookup_type_ == INTERCEPTOR_TYPE; }

	// Is the result is a property excluding transitions and the null descriptor?
	bool IsProperty() {
	return IsFound() && !IsTransition();
	}

	bool IsDataProperty() {
	switch (type()) {
	case FIELD:
	case NORMAL:
	case CONSTANT:
	return true;
	case CALLBACKS: {
	Object* callback = GetCallbackObject();
	return callback->IsAccessorInfo() \|\| callback->IsForeign();
	}
	case HANDLER:
	case INTERCEPTOR:
	case TRANSITION:
	case NONEXISTENT:
	return false;
	}
	UNREACHABLE();
	return false;
	}

	bool IsCacheable() { return cacheable_; }
	void DisallowCaching() { cacheable_ = false; }

	Object* GetLazyValue() {
	switch (type()) {
	case FIELD:
	return holder()->RawFastPropertyAt(GetFieldIndex().field_index());
	case NORMAL: {
	Object* value;
	value = holder()->property_dictionary()->ValueAt(GetDictionaryEntry());
	if (holder()->IsGlobalObject()) {
	value = PropertyCell::cast(value)->value();
	}
	return value;
	}
	case CONSTANT:
	return GetConstant();
	case CALLBACKS:
	case HANDLER:
	case INTERCEPTOR:
	case TRANSITION:
	case NONEXISTENT:
	return isolate()->heap()->the_hole_value();
	}
	UNREACHABLE();
	return NULL;
	}

	Map* GetTransitionTarget(Map* map) {
	ASSERT(IsTransition());
	TransitionArray* transitions = map->transitions();
	return transitions->GetTarget(number_);
	}

	Map* GetTransitionTarget() {
	return GetTransitionTarget(holder()->map());
	}

	PropertyDetails GetTransitionDetails(Map* map) {
	ASSERT(IsTransition());
	TransitionArray* transitions = map->transitions();
	return transitions->GetTargetDetails(number_);
	}

	PropertyDetails GetTransitionDetails() {
	return GetTransitionDetails(holder()->map());
	}

	bool IsTransitionToField(Map* map) {
	return IsTransition() && GetTransitionDetails(map).type() == FIELD;
	}

	bool IsTransitionToConstant(Map* map) {
	return IsTransition() && GetTransitionDetails(map).type() == CONSTANT;
	}

	Map* GetTransitionMap() {
	ASSERT(IsTransition());
	return Map::cast(GetValue());
	}

	Map* GetTransitionMapFromMap(Map* map) {
	ASSERT(IsTransition());
	return map->transitions()->GetTarget(number_);
	}

	int GetTransitionIndex() {
	ASSERT(IsTransition());
	return number_;
	}

	int GetDescriptorIndex() {
	ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
	return number_;
	}

	PropertyIndex GetFieldIndex() {
	ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
	return PropertyIndex::NewFieldIndex(GetFieldIndexFromMap(holder()->map()));
	}

	int GetLocalFieldIndexFromMap(Map* map) {
	return GetFieldIndexFromMap(map) - map->inobject_properties();
	}

	int GetDictionaryEntry() {
	ASSERT(lookup_type_ == DICTIONARY_TYPE);
	return number_;
	}

	JSFunction* GetConstantFunction() {
	ASSERT(type() == CONSTANT);
	return JSFunction::cast(GetValue());
	}

	Object* GetConstantFromMap(Map* map) {
	ASSERT(type() == CONSTANT);
	return GetValueFromMap(map);
	}

	JSFunction* GetConstantFunctionFromMap(Map* map) {
	return JSFunction::cast(GetConstantFromMap(map));
	}

	Object* GetConstant() {
	ASSERT(type() == CONSTANT);
	return GetValue();
	}

	Object* GetCallbackObject() {
	ASSERT(type() == CALLBACKS && !IsTransition());
	return GetValue();
	}

	#ifdef OBJECT_PRINT
	void Print(FILE* out);
	#endif

	Object* GetValue() {
	if (lookup_type_ == DESCRIPTOR_TYPE) {
	return GetValueFromMap(holder()->map());
	}
	// In the dictionary case, the data is held in the value field.
	ASSERT(lookup_type_ == DICTIONARY_TYPE);
	return holder()->GetNormalizedProperty(this);
	}

	Object* GetValueFromMap(Map* map) const {
	ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
	ASSERT(number_ < map->NumberOfOwnDescriptors());
	return map->instance_descriptors()->GetValue(number_);
	}

	int GetFieldIndexFromMap(Map* map) const {
	ASSERT(lookup_type_ == DESCRIPTOR_TYPE);
	ASSERT(number_ < map->NumberOfOwnDescriptors());
	return map->instance_descriptors()->GetFieldIndex(number_);
	}

	void Iterate(ObjectVisitor* visitor);

	private:
	Isolate* isolate_;
	LookupResult* next_;

	// Where did we find the result;
	enum {
	NOT_FOUND,
	DESCRIPTOR_TYPE,
	TRANSITION_TYPE,
	DICTIONARY_TYPE,
	HANDLER_TYPE,
	INTERCEPTOR_TYPE
	} lookup_type_;

	JSReceiver* holder_;
	int number_;
	bool cacheable_;
	PropertyDetails details_;
	};


	} } // namespace v8::internal

	#endif // V8_PROPERTY_H_