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// Copyright 2017 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_OBJECTS_MAP_INL_H_
#define V8_OBJECTS_MAP_INL_H_
#include "src/heap/heap-write-barrier-inl.h"
#include "src/objects/api-callbacks-inl.h"
#include "src/objects/cell-inl.h"
#include "src/objects/descriptor-array-inl.h"
#include "src/objects/field-type.h"
#include "src/objects/instance-type-inl.h"
#include "src/objects/js-function-inl.h"
#include "src/objects/layout-descriptor-inl.h"
#include "src/objects/map.h"
#include "src/objects/objects-inl.h"
#include "src/objects/property.h"
#include "src/objects/prototype-info-inl.h"
#include "src/objects/shared-function-info.h"
#include "src/objects/templates-inl.h"
#include "src/objects/transitions-inl.h"
#include "src/objects/transitions.h"
#include "src/wasm/wasm-objects-inl.h"
// Has to be the last include (doesn't have include guards):
#include "src/objects/object-macros.h"
namespace v8 {
namespace internal {
#include "torque-generated/src/objects/map-tq-inl.inc"
OBJECT_CONSTRUCTORS_IMPL(Map, HeapObject)
CAST_ACCESSOR(Map)
RELAXED_ACCESSORS(Map, instance_descriptors, DescriptorArray,
kInstanceDescriptorsOffset)
RELEASE_ACQUIRE_ACCESSORS(Map, instance_descriptors, DescriptorArray,
kInstanceDescriptorsOffset)
// A freshly allocated layout descriptor can be set on an existing map.
// We need to use release-store and acquire-load accessor pairs to ensure
// that the concurrent marking thread observes initializing stores of the
// layout descriptor.
RELEASE_ACQUIRE_ACCESSORS_CHECKED(Map, layout_descriptor, LayoutDescriptor,
kLayoutDescriptorOffset,
FLAG_unbox_double_fields)
SYNCHRONIZED_WEAK_ACCESSORS(Map, raw_transitions,
kTransitionsOrPrototypeInfoOffset)
ACCESSORS_CHECKED2(Map, prototype, HeapObject, kPrototypeOffset, true,
value.IsNull() || value.IsJSReceiver())
ACCESSORS_CHECKED(Map, prototype_info, Object,
kTransitionsOrPrototypeInfoOffset, this->is_prototype_map())
// |bit_field| fields.
// Concurrent access to |has_prototype_slot| and |has_non_instance_prototype|
// is explicitly allowlisted here. The former is never modified after the map
// is setup but it's being read by concurrent marker when pointer compression
// is enabled. The latter bit can be modified on a live objects.
BIT_FIELD_ACCESSORS(Map, relaxed_bit_field, has_non_instance_prototype,
Map::Bits1::HasNonInstancePrototypeBit)
BIT_FIELD_ACCESSORS(Map, bit_field, is_callable, Map::Bits1::IsCallableBit)
BIT_FIELD_ACCESSORS(Map, bit_field, has_named_interceptor,
Map::Bits1::HasNamedInterceptorBit)
BIT_FIELD_ACCESSORS(Map, bit_field, has_indexed_interceptor,
Map::Bits1::HasIndexedInterceptorBit)
BIT_FIELD_ACCESSORS(Map, bit_field, is_undetectable,
Map::Bits1::IsUndetectableBit)
BIT_FIELD_ACCESSORS(Map, bit_field, is_access_check_needed,
Map::Bits1::IsAccessCheckNeededBit)
BIT_FIELD_ACCESSORS(Map, bit_field, is_constructor,
Map::Bits1::IsConstructorBit)
BIT_FIELD_ACCESSORS(Map, relaxed_bit_field, has_prototype_slot,
Map::Bits1::HasPrototypeSlotBit)
// |bit_field2| fields.
BIT_FIELD_ACCESSORS(Map, bit_field2, new_target_is_base,
Map::Bits2::NewTargetIsBaseBit)
BIT_FIELD_ACCESSORS(Map, bit_field2, is_immutable_proto,
Map::Bits2::IsImmutablePrototypeBit)
// |bit_field3| fields.
BIT_FIELD_ACCESSORS(Map, bit_field3, owns_descriptors,
Map::Bits3::OwnsDescriptorsBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, is_deprecated, Map::Bits3::IsDeprecatedBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, is_in_retained_map_list,
Map::Bits3::IsInRetainedMapListBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, is_prototype_map,
Map::Bits3::IsPrototypeMapBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, is_migration_target,
Map::Bits3::IsMigrationTargetBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, is_extensible, Map::Bits3::IsExtensibleBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, may_have_interesting_symbols,
Map::Bits3::MayHaveInterestingSymbolsBit)
BIT_FIELD_ACCESSORS(Map, bit_field3, construction_counter,
Map::Bits3::ConstructionCounterBits)
DEF_GETTER(Map, GetNamedInterceptor, InterceptorInfo) {
DCHECK(has_named_interceptor());
FunctionTemplateInfo info = GetFunctionTemplateInfo(isolate);
return InterceptorInfo::cast(info.GetNamedPropertyHandler(isolate));
}
DEF_GETTER(Map, GetIndexedInterceptor, InterceptorInfo) {
DCHECK(has_indexed_interceptor());
FunctionTemplateInfo info = GetFunctionTemplateInfo(isolate);
return InterceptorInfo::cast(info.GetIndexedPropertyHandler(isolate));
}
bool Map::IsMostGeneralFieldType(Representation representation,
FieldType field_type) {
return !representation.IsHeapObject() || field_type.IsAny();
}
bool Map::CanHaveFastTransitionableElementsKind(InstanceType instance_type) {
return instance_type == JS_ARRAY_TYPE ||
instance_type == JS_PRIMITIVE_WRAPPER_TYPE ||
instance_type == JS_ARGUMENTS_OBJECT_TYPE;
}
bool Map::CanHaveFastTransitionableElementsKind() const {
return CanHaveFastTransitionableElementsKind(instance_type());
}
bool Map::IsDetached(Isolate* isolate) const {
if (is_prototype_map()) return true;
return instance_type() == JS_OBJECT_TYPE && NumberOfOwnDescriptors() > 0 &&
GetBackPointer().IsUndefined(isolate);
}
// static
void Map::GeneralizeIfCanHaveTransitionableFastElementsKind(
Isolate* isolate, InstanceType instance_type,
Representation* representation, Handle<FieldType>* field_type) {
if (CanHaveFastTransitionableElementsKind(instance_type)) {
// We don't support propagation of field generalization through elements
// kind transitions because they are inserted into the transition tree
// before field transitions. In order to avoid complexity of handling
// such a case we ensure that all maps with transitionable elements kinds
// have the most general field representation and type.
*field_type = FieldType::Any(isolate);
*representation = Representation::Tagged();
}
}
Handle<Map> Map::Normalize(Isolate* isolate, Handle<Map> fast_map,
PropertyNormalizationMode mode, const char* reason) {
return Normalize(isolate, fast_map, fast_map->elements_kind(), mode, reason);
}
bool Map::EquivalentToForNormalization(const Map other,
PropertyNormalizationMode mode) const {
return EquivalentToForNormalization(other, elements_kind(), mode);
}
bool Map::IsUnboxedDoubleField(FieldIndex index) const {
IsolateRoot isolate = GetIsolateForPtrCompr(*this);
return IsUnboxedDoubleField(isolate, index);
}
bool Map::IsUnboxedDoubleField(IsolateRoot isolate, FieldIndex index) const {
if (!FLAG_unbox_double_fields) return false;
if (!index.is_inobject()) return false;
return !layout_descriptor(isolate, kAcquireLoad)
.IsTagged(index.property_index());
}
bool Map::TooManyFastProperties(StoreOrigin store_origin) const {
if (UnusedPropertyFields() != 0) return false;
if (is_prototype_map()) return false;
if (store_origin == StoreOrigin::kNamed) {
int limit = std::max({kMaxFastProperties, GetInObjectProperties()});
FieldCounts counts = GetFieldCounts();
// Only count mutable fields so that objects with large numbers of
// constant functions do not go to dictionary mode. That would be bad
// because such objects have often been used as modules.
int external = counts.mutable_count() - GetInObjectProperties();
return external > limit || counts.GetTotal() > kMaxNumberOfDescriptors;
} else {
int limit = std::max({kFastPropertiesSoftLimit, GetInObjectProperties()});
int external = NumberOfFields() - GetInObjectProperties();
return external > limit;
}
}
PropertyDetails Map::GetLastDescriptorDetails(Isolate* isolate) const {
return instance_descriptors(isolate, kRelaxedLoad).GetDetails(LastAdded());
}
InternalIndex Map::LastAdded() const {
int number_of_own_descriptors = NumberOfOwnDescriptors();
DCHECK_GT(number_of_own_descriptors, 0);
return InternalIndex(number_of_own_descriptors - 1);
}
int Map::NumberOfOwnDescriptors() const {
return Bits3::NumberOfOwnDescriptorsBits::decode(bit_field3());
}
void Map::SetNumberOfOwnDescriptors(int number) {
DCHECK_LE(number, instance_descriptors(kRelaxedLoad).number_of_descriptors());
CHECK_LE(static_cast<unsigned>(number),
static_cast<unsigned>(kMaxNumberOfDescriptors));
set_bit_field3(
Bits3::NumberOfOwnDescriptorsBits::update(bit_field3(), number));
}
InternalIndex::Range Map::IterateOwnDescriptors() const {
return InternalIndex::Range(NumberOfOwnDescriptors());
}
int Map::EnumLength() const {
return Bits3::EnumLengthBits::decode(bit_field3());
}
void Map::SetEnumLength(int length) {
if (length != kInvalidEnumCacheSentinel) {
DCHECK_LE(length, NumberOfOwnDescriptors());
CHECK_LE(static_cast<unsigned>(length),
static_cast<unsigned>(kMaxNumberOfDescriptors));
}
set_bit_field3(Bits3::EnumLengthBits::update(bit_field3(), length));
}
FixedArrayBase Map::GetInitialElements() const {
FixedArrayBase result;
if (has_fast_elements() || has_fast_string_wrapper_elements() ||
has_any_nonextensible_elements()) {
result = GetReadOnlyRoots().empty_fixed_array();
} else if (has_typed_array_elements()) {
result = GetReadOnlyRoots().empty_byte_array();
} else if (has_dictionary_elements()) {
result = GetReadOnlyRoots().empty_slow_element_dictionary();
} else {
UNREACHABLE();
}
DCHECK(!ObjectInYoungGeneration(result));
return result;
}
VisitorId Map::visitor_id() const {
return static_cast<VisitorId>(
RELAXED_READ_BYTE_FIELD(*this, kVisitorIdOffset));
}
void Map::set_visitor_id(VisitorId id) {
CHECK_LT(static_cast<unsigned>(id), 256);
RELAXED_WRITE_BYTE_FIELD(*this, kVisitorIdOffset, static_cast<byte>(id));
}
int Map::instance_size_in_words() const {
return RELAXED_READ_BYTE_FIELD(*this, kInstanceSizeInWordsOffset);
}
void Map::set_instance_size_in_words(int value) {
RELAXED_WRITE_BYTE_FIELD(*this, kInstanceSizeInWordsOffset,
static_cast<byte>(value));
}
int Map::instance_size() const {
return instance_size_in_words() << kTaggedSizeLog2;
}
void Map::set_instance_size(int value) {
CHECK(IsAligned(value, kTaggedSize));
value >>= kTaggedSizeLog2;
CHECK_LT(static_cast<unsigned>(value), 256);
set_instance_size_in_words(value);
}
int Map::inobject_properties_start_or_constructor_function_index() const {
return RELAXED_READ_BYTE_FIELD(
*this, kInObjectPropertiesStartOrConstructorFunctionIndexOffset);
}
void Map::set_inobject_properties_start_or_constructor_function_index(
int value) {
CHECK_LT(static_cast<unsigned>(value), 256);
RELAXED_WRITE_BYTE_FIELD(
*this, kInObjectPropertiesStartOrConstructorFunctionIndexOffset,
static_cast<byte>(value));
}
int Map::GetInObjectPropertiesStartInWords() const {
DCHECK(IsJSObjectMap());
return inobject_properties_start_or_constructor_function_index();
}
void Map::SetInObjectPropertiesStartInWords(int value) {
CHECK(IsJSObjectMap());
set_inobject_properties_start_or_constructor_function_index(value);
}
int Map::GetInObjectProperties() const {
DCHECK(IsJSObjectMap());
return instance_size_in_words() - GetInObjectPropertiesStartInWords();
}
int Map::GetConstructorFunctionIndex() const {
DCHECK(IsPrimitiveMap());
return inobject_properties_start_or_constructor_function_index();
}
void Map::SetConstructorFunctionIndex(int value) {
CHECK(IsPrimitiveMap());
set_inobject_properties_start_or_constructor_function_index(value);
}
int Map::GetInObjectPropertyOffset(int index) const {
return (GetInObjectPropertiesStartInWords() + index) * kTaggedSize;
}
Handle<Map> Map::AddMissingTransitionsForTesting(
Isolate* isolate, Handle<Map> split_map,
Handle<DescriptorArray> descriptors,
Handle<LayoutDescriptor> full_layout_descriptor) {
return AddMissingTransitions(isolate, split_map, descriptors,
full_layout_descriptor);
}
InstanceType Map::instance_type() const {
return static_cast<InstanceType>(ReadField<uint16_t>(kInstanceTypeOffset));
}
void Map::set_instance_type(InstanceType value) {
WriteField<uint16_t>(kInstanceTypeOffset, value);
}
int Map::UnusedPropertyFields() const {
int value = used_or_unused_instance_size_in_words();
DCHECK_IMPLIES(!IsJSObjectMap(), value == 0);
int unused;
if (value >= JSObject::kFieldsAdded) {
unused = instance_size_in_words() - value;
} else {
// For out of object properties "used_or_unused_instance_size_in_words"
// byte encodes the slack in the property array.
unused = value;
}
return unused;
}
int Map::UnusedInObjectProperties() const {
// Like Map::UnusedPropertyFields(), but returns 0 for out of object
// properties.
int value = used_or_unused_instance_size_in_words();
DCHECK_IMPLIES(!IsJSObjectMap(), value == 0);
if (value >= JSObject::kFieldsAdded) {
return instance_size_in_words() - value;
}
return 0;
}
int Map::used_or_unused_instance_size_in_words() const {
return RELAXED_READ_BYTE_FIELD(*this, kUsedOrUnusedInstanceSizeInWordsOffset);
}
void Map::set_used_or_unused_instance_size_in_words(int value) {
CHECK_LE(static_cast<unsigned>(value), 255);
RELAXED_WRITE_BYTE_FIELD(*this, kUsedOrUnusedInstanceSizeInWordsOffset,
static_cast<byte>(value));
}
int Map::UsedInstanceSize() const {
int words = used_or_unused_instance_size_in_words();
if (words < JSObject::kFieldsAdded) {
// All in-object properties are used and the words is tracking the slack
// in the property array.
return instance_size();
}
return words * kTaggedSize;
}
void Map::SetInObjectUnusedPropertyFields(int value) {
STATIC_ASSERT(JSObject::kFieldsAdded == JSObject::kHeaderSize / kTaggedSize);
if (!IsJSObjectMap()) {
CHECK_EQ(0, value);
set_used_or_unused_instance_size_in_words(0);
DCHECK_EQ(0, UnusedPropertyFields());
return;
}
CHECK_LE(0, value);
DCHECK_LE(value, GetInObjectProperties());
int used_inobject_properties = GetInObjectProperties() - value;
set_used_or_unused_instance_size_in_words(
GetInObjectPropertyOffset(used_inobject_properties) / kTaggedSize);
DCHECK_EQ(value, UnusedPropertyFields());
}
void Map::SetOutOfObjectUnusedPropertyFields(int value) {
STATIC_ASSERT(JSObject::kFieldsAdded == JSObject::kHeaderSize / kTaggedSize);
CHECK_LT(static_cast<unsigned>(value), JSObject::kFieldsAdded);
// For out of object properties "used_instance_size_in_words" byte encodes
// the slack in the property array.
set_used_or_unused_instance_size_in_words(value);
DCHECK_EQ(value, UnusedPropertyFields());
}
void Map::CopyUnusedPropertyFields(Map map) {
set_used_or_unused_instance_size_in_words(
map.used_or_unused_instance_size_in_words());
DCHECK_EQ(UnusedPropertyFields(), map.UnusedPropertyFields());
}
void Map::CopyUnusedPropertyFieldsAdjustedForInstanceSize(Map map) {
int value = map.used_or_unused_instance_size_in_words();
if (value >= JSPrimitiveWrapper::kFieldsAdded) {
// Unused in-object fields. Adjust the offset from the object’s start
// so it matches the distance to the object’s end.
value += instance_size_in_words() - map.instance_size_in_words();
}
set_used_or_unused_instance_size_in_words(value);
DCHECK_EQ(UnusedPropertyFields(), map.UnusedPropertyFields());
}
void Map::AccountAddedPropertyField() {
// Update used instance size and unused property fields number.
STATIC_ASSERT(JSObject::kFieldsAdded == JSObject::kHeaderSize / kTaggedSize);
#ifdef DEBUG
int new_unused = UnusedPropertyFields() - 1;
if (new_unused < 0) new_unused += JSObject::kFieldsAdded;
#endif
int value = used_or_unused_instance_size_in_words();
if (value >= JSObject::kFieldsAdded) {
if (value == instance_size_in_words()) {
AccountAddedOutOfObjectPropertyField(0);
} else {
// The property is added in-object, so simply increment the counter.
set_used_or_unused_instance_size_in_words(value + 1);
}
} else {
AccountAddedOutOfObjectPropertyField(value);
}
DCHECK_EQ(new_unused, UnusedPropertyFields());
}
void Map::AccountAddedOutOfObjectPropertyField(int unused_in_property_array) {
unused_in_property_array--;
if (unused_in_property_array < 0) {
unused_in_property_array += JSObject::kFieldsAdded;
}
CHECK_LT(static_cast<unsigned>(unused_in_property_array),
JSObject::kFieldsAdded);
set_used_or_unused_instance_size_in_words(unused_in_property_array);
DCHECK_EQ(unused_in_property_array, UnusedPropertyFields());
}
byte Map::bit_field() const { return ReadField<byte>(kBitFieldOffset); }
void Map::set_bit_field(byte value) {
WriteField<byte>(kBitFieldOffset, value);
}
byte Map::relaxed_bit_field() const {
return RELAXED_READ_BYTE_FIELD(*this, kBitFieldOffset);
}
void Map::set_relaxed_bit_field(byte value) {
RELAXED_WRITE_BYTE_FIELD(*this, kBitFieldOffset, value);
}
byte Map::bit_field2() const { return ReadField<byte>(kBitField2Offset); }
void Map::set_bit_field2(byte value) {
WriteField<byte>(kBitField2Offset, value);
}
bool Map::is_abandoned_prototype_map() const {
return is_prototype_map() && !owns_descriptors();
}
bool Map::should_be_fast_prototype_map() const {
if (!prototype_info().IsPrototypeInfo()) return false;
return PrototypeInfo::cast(prototype_info()).should_be_fast_map();
}
void Map::set_elements_kind(ElementsKind elements_kind) {
CHECK_LT(static_cast<int>(elements_kind), kElementsKindCount);
set_bit_field2(
Map::Bits2::ElementsKindBits::update(bit_field2(), elements_kind));
}
ElementsKind Map::elements_kind() const {
return Map::Bits2::ElementsKindBits::decode(bit_field2());
}
bool Map::has_fast_smi_elements() const {
return IsSmiElementsKind(elements_kind());
}
bool Map::has_fast_object_elements() const {
return IsObjectElementsKind(elements_kind());
}
bool Map::has_fast_smi_or_object_elements() const {
return IsSmiOrObjectElementsKind(elements_kind());
}
bool Map::has_fast_double_elements() const {
return IsDoubleElementsKind(elements_kind());
}
bool Map::has_fast_elements() const {
return IsFastElementsKind(elements_kind());
}
bool Map::has_sloppy_arguments_elements() const {
return IsSloppyArgumentsElementsKind(elements_kind());
}
bool Map::has_fast_sloppy_arguments_elements() const {
return elements_kind() == FAST_SLOPPY_ARGUMENTS_ELEMENTS;
}
bool Map::has_fast_string_wrapper_elements() const {
return elements_kind() == FAST_STRING_WRAPPER_ELEMENTS;
}
bool Map::has_typed_array_elements() const {
return IsTypedArrayElementsKind(elements_kind());
}
bool Map::has_dictionary_elements() const {
return IsDictionaryElementsKind(elements_kind());
}
bool Map::has_any_nonextensible_elements() const {
return IsAnyNonextensibleElementsKind(elements_kind());
}
bool Map::has_nonextensible_elements() const {
return IsNonextensibleElementsKind(elements_kind());
}
bool Map::has_sealed_elements() const {
return IsSealedElementsKind(elements_kind());
}
bool Map::has_frozen_elements() const {
return IsFrozenElementsKind(elements_kind());
}
void Map::set_is_dictionary_map(bool value) {
uint32_t new_bit_field3 =
Bits3::IsDictionaryMapBit::update(bit_field3(), value);
new_bit_field3 = Bits3::IsUnstableBit::update(new_bit_field3, value);
set_bit_field3(new_bit_field3);
}
bool Map::is_dictionary_map() const {
return Bits3::IsDictionaryMapBit::decode(bit_field3());
}
void Map::mark_unstable() {
set_bit_field3(Bits3::IsUnstableBit::update(bit_field3(), true));
}
bool Map::is_stable() const {
return !Bits3::IsUnstableBit::decode(bit_field3());
}
bool Map::CanBeDeprecated() const {
for (InternalIndex i : IterateOwnDescriptors()) {
PropertyDetails details = instance_descriptors(kRelaxedLoad).GetDetails(i);
if (details.representation().IsNone()) return true;
if (details.representation().IsSmi()) return true;
if (details.representation().IsDouble() && FLAG_unbox_double_fields)
return true;
if (details.representation().IsHeapObject()) return true;
if (details.kind() == kData && details.location() == kDescriptor) {
return true;
}
}
return false;
}
void Map::NotifyLeafMapLayoutChange(Isolate* isolate) {
if (is_stable()) {
mark_unstable();
dependent_code().DeoptimizeDependentCodeGroup(
DependentCode::kPrototypeCheckGroup);
}
}
bool Map::CanTransition() const {
// Only JSObject and subtypes have map transitions and back pointers.
return InstanceTypeChecker::IsJSObject(instance_type());
}
#define DEF_TESTER(Type, ...) \
bool Map::Is##Type##Map() const { \
return InstanceTypeChecker::Is##Type(instance_type()); \
}
INSTANCE_TYPE_CHECKERS(DEF_TESTER)
#undef DEF_TESTER
bool Map::IsBooleanMap() const {
return *this == GetReadOnlyRoots().boolean_map();
}
bool Map::IsNullOrUndefinedMap() const {
return *this == GetReadOnlyRoots().null_map() ||
*this == GetReadOnlyRoots().undefined_map();
}
bool Map::IsPrimitiveMap() const {
return instance_type() <= LAST_PRIMITIVE_HEAP_OBJECT_TYPE;
}
LayoutDescriptor Map::layout_descriptor_gc_safe() const {
DCHECK(FLAG_unbox_double_fields);
// The loaded value can be dereferenced on background thread to load the
// bitmap. We need acquire load in order to ensure that the bitmap
// initializing stores are also visible to the background thread.
Object layout_desc =
TaggedField<Object, kLayoutDescriptorOffset>::Acquire_Load(*this);
return LayoutDescriptor::cast_gc_safe(layout_desc);
}
bool Map::HasFastPointerLayout() const {
DCHECK(FLAG_unbox_double_fields);
// The loaded value is used for SMI check only and is not dereferenced,
// so relaxed load is safe.
Object layout_desc =
TaggedField<Object, kLayoutDescriptorOffset>::Relaxed_Load(*this);
return LayoutDescriptor::IsFastPointerLayout(layout_desc);
}
void Map::UpdateDescriptors(Isolate* isolate, DescriptorArray descriptors,
LayoutDescriptor layout_desc,
int number_of_own_descriptors) {
SetInstanceDescriptors(isolate, descriptors, number_of_own_descriptors);
if (FLAG_unbox_double_fields) {
if (layout_descriptor(kAcquireLoad).IsSlowLayout()) {
set_layout_descriptor(layout_desc, kReleaseStore);
}
#ifdef VERIFY_HEAP
// TODO(ishell): remove these checks from VERIFY_HEAP mode.
if (FLAG_verify_heap) {
CHECK(layout_descriptor(kAcquireLoad).IsConsistentWithMap(*this));
CHECK_EQ(Map::GetVisitorId(*this), visitor_id());
}
#else
SLOW_DCHECK(layout_descriptor(kAcquireLoad).IsConsistentWithMap(*this));
DCHECK(visitor_id() == Map::GetVisitorId(*this));
#endif
}
}
void Map::InitializeDescriptors(Isolate* isolate, DescriptorArray descriptors,
LayoutDescriptor layout_desc) {
SetInstanceDescriptors(isolate, descriptors,
descriptors.number_of_descriptors());
if (FLAG_unbox_double_fields) {
set_layout_descriptor(layout_desc, kReleaseStore);
#ifdef VERIFY_HEAP
// TODO(ishell): remove these checks from VERIFY_HEAP mode.
if (FLAG_verify_heap) {
CHECK(layout_descriptor(kAcquireLoad).IsConsistentWithMap(*this));
}
#else
SLOW_DCHECK(layout_descriptor(kAcquireLoad).IsConsistentWithMap(*this));
#endif
set_visitor_id(Map::GetVisitorId(*this));
}
}
void Map::set_bit_field3(uint32_t bits) {
RELAXED_WRITE_UINT32_FIELD(*this, kBitField3Offset, bits);
}
uint32_t Map::bit_field3() const {
return RELAXED_READ_UINT32_FIELD(*this, kBitField3Offset);
}
void Map::clear_padding() {
if (FIELD_SIZE(kOptionalPaddingOffset) == 0) return;
DCHECK_EQ(4, FIELD_SIZE(kOptionalPaddingOffset));
memset(reinterpret_cast<void*>(address() + kOptionalPaddingOffset), 0,
FIELD_SIZE(kOptionalPaddingOffset));
}
LayoutDescriptor Map::GetLayoutDescriptor() const {
return FLAG_unbox_double_fields ? layout_descriptor(kAcquireLoad)
: LayoutDescriptor::FastPointerLayout();
}
void Map::AppendDescriptor(Isolate* isolate, Descriptor* desc) {
DescriptorArray descriptors = instance_descriptors(kRelaxedLoad);
int number_of_own_descriptors = NumberOfOwnDescriptors();
DCHECK(descriptors.number_of_descriptors() == number_of_own_descriptors);
{
// The following two operations need to happen before the marking write
// barrier.
descriptors.Append(desc);
SetNumberOfOwnDescriptors(number_of_own_descriptors + 1);
#ifndef V8_DISABLE_WRITE_BARRIERS
WriteBarrier::Marking(descriptors, number_of_own_descriptors + 1);
#endif
}
// Properly mark the map if the {desc} is an "interesting symbol".
if (desc->GetKey()->IsInterestingSymbol()) {
set_may_have_interesting_symbols(true);
}
PropertyDetails details = desc->GetDetails();
if (details.location() == kField) {
DCHECK_GT(UnusedPropertyFields(), 0);
AccountAddedPropertyField();
}
// This function does not support appending double field descriptors and
// it should never try to (otherwise, layout descriptor must be updated too).
#ifdef DEBUG
DCHECK(details.location() != kField || !details.representation().IsDouble());
#endif
}
DEF_GETTER(Map, GetBackPointer, HeapObject) {
Object object = constructor_or_backpointer(isolate);
// This is the equivalent of IsMap() but avoids reading the instance type so
// it can be used concurrently without acquire load.
if (object.IsHeapObject() && HeapObject::cast(object).map(isolate) ==
GetReadOnlyRoots(isolate).meta_map()) {
return Map::cast(object);
}
// Can't use ReadOnlyRoots(isolate) as this isolate could be produced by
// i::GetIsolateForPtrCompr(HeapObject).
return GetReadOnlyRoots(isolate).undefined_value();
}
void Map::SetBackPointer(HeapObject value, WriteBarrierMode mode) {
CHECK_GE(instance_type(), FIRST_JS_RECEIVER_TYPE);
CHECK(value.IsMap());
CHECK(GetBackPointer().IsUndefined());
CHECK_IMPLIES(value.IsMap(), Map::cast(value).GetConstructor() ==
constructor_or_backpointer());
set_constructor_or_backpointer(value, mode);
}
// static
Map Map::ElementsTransitionMap(Isolate* isolate) {
DisallowHeapAllocation no_gc;
return TransitionsAccessor(isolate, *this, &no_gc)
.SearchSpecial(ReadOnlyRoots(isolate).elements_transition_symbol());
}
ACCESSORS(Map, dependent_code, DependentCode, kDependentCodeOffset)
ACCESSORS(Map, prototype_validity_cell, Object, kPrototypeValidityCellOffset)
ACCESSORS_CHECKED2(Map, constructor_or_backpointer, Object,
kConstructorOrBackPointerOrNativeContextOffset,
!IsContextMap(), value.IsNull() || !IsContextMap())
ACCESSORS_CHECKED(Map, native_context, NativeContext,
kConstructorOrBackPointerOrNativeContextOffset,
IsContextMap())
ACCESSORS_CHECKED(Map, wasm_type_info, WasmTypeInfo,
kConstructorOrBackPointerOrNativeContextOffset,
IsWasmStructMap() || IsWasmArrayMap())
bool Map::IsPrototypeValidityCellValid() const {
Object validity_cell = prototype_validity_cell();
Object value = validity_cell.IsSmi() ? Smi::cast(validity_cell)
: Cell::cast(validity_cell).value();
return value == Smi::FromInt(Map::kPrototypeChainValid);
}
DEF_GETTER(Map, GetConstructor, Object) {
Object maybe_constructor = constructor_or_backpointer(isolate);
// Follow any back pointers.
while (maybe_constructor.IsMap(isolate)) {
maybe_constructor =
Map::cast(maybe_constructor).constructor_or_backpointer(isolate);
}
return maybe_constructor;
}
Object Map::TryGetConstructor(Isolate* isolate, int max_steps) {
Object maybe_constructor = constructor_or_backpointer(isolate);
// Follow any back pointers.
while (maybe_constructor.IsMap(isolate)) {
if (max_steps-- == 0) return Smi::FromInt(0);
maybe_constructor =
Map::cast(maybe_constructor).constructor_or_backpointer(isolate);
}
return maybe_constructor;
}
DEF_GETTER(Map, GetFunctionTemplateInfo, FunctionTemplateInfo) {
Object constructor = GetConstructor(isolate);
if (constructor.IsJSFunction(isolate)) {
// TODO(ishell): IsApiFunction(isolate) and get_api_func_data(isolate)
DCHECK(JSFunction::cast(constructor).shared(isolate).IsApiFunction());
return JSFunction::cast(constructor).shared(isolate).get_api_func_data();
}
DCHECK(constructor.IsFunctionTemplateInfo(isolate));
return FunctionTemplateInfo::cast(constructor);
}
void Map::SetConstructor(Object constructor, WriteBarrierMode mode) {
// Never overwrite a back pointer with a constructor.
CHECK(!constructor_or_backpointer().IsMap());
set_constructor_or_backpointer(constructor, mode);
}
Handle<Map> Map::CopyInitialMap(Isolate* isolate, Handle<Map> map) {
return CopyInitialMap(isolate, map, map->instance_size(),
map->GetInObjectProperties(),
map->UnusedPropertyFields());
}
bool Map::IsInobjectSlackTrackingInProgress() const {
return construction_counter() != Map::kNoSlackTracking;
}
void Map::InobjectSlackTrackingStep(Isolate* isolate) {
// Slack tracking should only be performed on an initial map.
DCHECK(GetBackPointer().IsUndefined());
if (!IsInobjectSlackTrackingInProgress()) return;
int counter = construction_counter();
set_construction_counter(counter - 1);
if (counter == kSlackTrackingCounterEnd) {
CompleteInobjectSlackTracking(isolate);
}
}
int Map::SlackForArraySize(int old_size, int size_limit) {
const int max_slack = size_limit - old_size;
CHECK_LE(0, max_slack);
if (old_size < 4) {
DCHECK_LE(1, max_slack);
return 1;
}
return std::min(max_slack, old_size / 4);
}
int Map::InstanceSizeFromSlack(int slack) const {
return instance_size() - slack * kTaggedSize;
}
OBJECT_CONSTRUCTORS_IMPL(NormalizedMapCache, WeakFixedArray)
CAST_ACCESSOR(NormalizedMapCache)
NEVER_READ_ONLY_SPACE_IMPL(NormalizedMapCache)
int NormalizedMapCache::GetIndex(Handle<Map> map) {
return map->Hash() % NormalizedMapCache::kEntries;
}
DEF_GETTER(HeapObject, IsNormalizedMapCache, bool) {
if (!IsWeakFixedArray(isolate)) return false;
if (WeakFixedArray::cast(*this).length() != NormalizedMapCache::kEntries) {
return false;
}
return true;
}
} // namespace internal
} // namespace v8
#include "src/objects/object-macros-undef.h"
#endif // V8_OBJECTS_MAP_INL_H_