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chromium / v8 / v8 / 5376383cd7d53a1be5e039069eeb6a081f964412 / . / src / feedback-vector-inl.h
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// Copyright 2012 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_FEEDBACK_VECTOR_INL_H_
#define V8_FEEDBACK_VECTOR_INL_H_
#include "src/feedback-vector.h"
#include "src/globals.h"
#include "src/heap/factory-inl.h"
#include "src/heap/heap-write-barrier-inl.h"
#include "src/objects/code-inl.h"
#include "src/objects/maybe-object-inl.h"
#include "src/objects/shared-function-info.h"
#include "src/objects/smi.h"
// Has to be the last include (doesn't have include guards):
#include "src/objects/object-macros.h"
namespace v8 {
namespace internal {
OBJECT_CONSTRUCTORS_IMPL(FeedbackVector, HeapObject)
OBJECT_CONSTRUCTORS_IMPL(FeedbackMetadata, HeapObject)
OBJECT_CONSTRUCTORS_IMPL(ClosureFeedbackCellArray, FixedArray)
NEVER_READ_ONLY_SPACE_IMPL(FeedbackVector)
NEVER_READ_ONLY_SPACE_IMPL(ClosureFeedbackCellArray)
CAST_ACCESSOR(FeedbackVector)
CAST_ACCESSOR(FeedbackMetadata)
CAST_ACCESSOR(ClosureFeedbackCellArray)
INT32_ACCESSORS(FeedbackMetadata, slot_count, kSlotCountOffset)
INT32_ACCESSORS(FeedbackMetadata, closure_feedback_cell_count,
kFeedbackCellCountOffset)
int32_t FeedbackMetadata::synchronized_slot_count() const {
return base::Acquire_Load(reinterpret_cast<const base::Atomic32*>(
FIELD_ADDR(*this, kSlotCountOffset)));
}
int32_t FeedbackMetadata::get(int index) const {
DCHECK(index >= 0 && index < length());
int offset = kHeaderSize + index * kInt32Size;
return READ_INT32_FIELD(*this, offset);
}
void FeedbackMetadata::set(int index, int32_t value) {
DCHECK(index >= 0 && index < length());
int offset = kHeaderSize + index * kInt32Size;
WRITE_INT32_FIELD(*this, offset, value);
}
bool FeedbackMetadata::is_empty() const { return slot_count() == 0; }
int FeedbackMetadata::length() const {
return FeedbackMetadata::length(slot_count());
}
int FeedbackMetadata::GetSlotSize(FeedbackSlotKind kind) {
switch (kind) {
case FeedbackSlotKind::kForIn:
case FeedbackSlotKind::kInstanceOf:
case FeedbackSlotKind::kCompareOp:
case FeedbackSlotKind::kBinaryOp:
case FeedbackSlotKind::kLiteral:
case FeedbackSlotKind::kTypeProfile:
return 1;
case FeedbackSlotKind::kCall:
case FeedbackSlotKind::kCloneObject:
case FeedbackSlotKind::kLoadProperty:
case FeedbackSlotKind::kLoadGlobalInsideTypeof:
case FeedbackSlotKind::kLoadGlobalNotInsideTypeof:
case FeedbackSlotKind::kLoadKeyed:
case FeedbackSlotKind::kHasKeyed:
case FeedbackSlotKind::kStoreNamedSloppy:
case FeedbackSlotKind::kStoreNamedStrict:
case FeedbackSlotKind::kStoreOwnNamed:
case FeedbackSlotKind::kStoreGlobalSloppy:
case FeedbackSlotKind::kStoreGlobalStrict:
case FeedbackSlotKind::kStoreKeyedSloppy:
case FeedbackSlotKind::kStoreKeyedStrict:
case FeedbackSlotKind::kStoreInArrayLiteral:
case FeedbackSlotKind::kStoreDataPropertyInLiteral:
return 2;
case FeedbackSlotKind::kInvalid:
case FeedbackSlotKind::kKindsNumber:
UNREACHABLE();
break;
}
return 1;
}
SMI_ACCESSORS(ClosureFeedbackCellArray, interrupt_budget,
FixedArray::OffsetOfElementAt(kInterruptBudgetIndex))
Handle<FeedbackCell> ClosureFeedbackCellArray::GetFeedbackCell(int index) {
return handle(FeedbackCell::cast(get(index + kFeedbackCellStartIndex)),
GetIsolate());
}
ACCESSORS(FeedbackVector, shared_function_info, SharedFunctionInfo,
kSharedFunctionInfoOffset)
WEAK_ACCESSORS(FeedbackVector, optimized_code_weak_or_smi, kOptimizedCodeOffset)
ACCESSORS(FeedbackVector, closure_feedback_cell_array, ClosureFeedbackCellArray,
kClosureFeedbackCellArrayOffset)
INT32_ACCESSORS(FeedbackVector, length, kLengthOffset)
INT32_ACCESSORS(FeedbackVector, invocation_count, kInvocationCountOffset)
INT32_ACCESSORS(FeedbackVector, profiler_ticks, kProfilerTicksOffset)
INT32_ACCESSORS(FeedbackVector, deopt_count, kDeoptCountOffset)
bool FeedbackVector::is_empty() const { return length() == 0; }
FeedbackMetadata FeedbackVector::metadata() const {
return shared_function_info()->feedback_metadata();
}
void FeedbackVector::clear_invocation_count() { set_invocation_count(0); }
void FeedbackVector::increment_deopt_count() {
int count = deopt_count();
if (count < std::numeric_limits<int32_t>::max()) {
set_deopt_count(count + 1);
}
}
Code FeedbackVector::optimized_code() const {
MaybeObject slot = optimized_code_weak_or_smi();
DCHECK(slot->IsSmi() || slot->IsWeakOrCleared());
HeapObject heap_object;
return slot->GetHeapObject(&heap_object) ? Code::cast(heap_object) : Code();
}
OptimizationMarker FeedbackVector::optimization_marker() const {
MaybeObject slot = optimized_code_weak_or_smi();
Smi value;
if (!slot->ToSmi(&value)) return OptimizationMarker::kNone;
return static_cast<OptimizationMarker>(value->value());
}
bool FeedbackVector::has_optimized_code() const {
return !optimized_code().is_null();
}
bool FeedbackVector::has_optimization_marker() const {
return optimization_marker() != OptimizationMarker::kLogFirstExecution &&
optimization_marker() != OptimizationMarker::kNone;
}
// Conversion from an integer index to either a slot or an ic slot.
// static
FeedbackSlot FeedbackVector::ToSlot(int index) {
DCHECK_GE(index, 0);
return FeedbackSlot(index);
}
MaybeObject FeedbackVector::Get(FeedbackSlot slot) const {
return get(GetIndex(slot));
}
MaybeObject FeedbackVector::get(int index) const {
DCHECK_GE(index, 0);
DCHECK_LT(index, this->length());
int offset = kFeedbackSlotsOffset + index * kTaggedSize;
return RELAXED_READ_WEAK_FIELD(*this, offset);
}
Handle<FeedbackCell> FeedbackVector::GetClosureFeedbackCell(int index) const {
DCHECK_GE(index, 0);
ClosureFeedbackCellArray cell_array =
ClosureFeedbackCellArray::cast(closure_feedback_cell_array());
return cell_array->GetFeedbackCell(index);
}
void FeedbackVector::Set(FeedbackSlot slot, MaybeObject value,
WriteBarrierMode mode) {
set(GetIndex(slot), value, mode);
}
void FeedbackVector::set(int index, MaybeObject value, WriteBarrierMode mode) {
DCHECK_GE(index, 0);
DCHECK_LT(index, this->length());
int offset = kFeedbackSlotsOffset + index * kTaggedSize;
RELAXED_WRITE_WEAK_FIELD(*this, offset, value);
CONDITIONAL_WEAK_WRITE_BARRIER(*this, offset, value, mode);
}
void FeedbackVector::Set(FeedbackSlot slot, Object value,
WriteBarrierMode mode) {
set(GetIndex(slot), MaybeObject::FromObject(value), mode);
}
void FeedbackVector::set(int index, Object value, WriteBarrierMode mode) {
set(index, MaybeObject::FromObject(value), mode);
}
inline MaybeObjectSlot FeedbackVector::slots_start() {
return RawMaybeWeakField(kFeedbackSlotsOffset);
}
// Helper function to transform the feedback to BinaryOperationHint.
BinaryOperationHint BinaryOperationHintFromFeedback(int type_feedback) {
switch (type_feedback) {
case BinaryOperationFeedback::kNone:
return BinaryOperationHint::kNone;
case BinaryOperationFeedback::kSignedSmall:
return BinaryOperationHint::kSignedSmall;
case BinaryOperationFeedback::kSignedSmallInputs:
return BinaryOperationHint::kSignedSmallInputs;
case BinaryOperationFeedback::kNumber:
return BinaryOperationHint::kNumber;
case BinaryOperationFeedback::kNumberOrOddball:
return BinaryOperationHint::kNumberOrOddball;
case BinaryOperationFeedback::kConsOneByteString:
return BinaryOperationHint::kConsOneByteString;
case BinaryOperationFeedback::kConsTwoByteString:
return BinaryOperationHint::kConsTwoByteString;
case BinaryOperationFeedback::kConsString:
return BinaryOperationHint::kConsString;
case BinaryOperationFeedback::kString:
return BinaryOperationHint::kString;
case BinaryOperationFeedback::kBigInt:
return BinaryOperationHint::kBigInt;
default:
return BinaryOperationHint::kAny;
}
UNREACHABLE();
}
// Helper function to transform the feedback to CompareOperationHint.
CompareOperationHint CompareOperationHintFromFeedback(int type_feedback) {
switch (type_feedback) {
case CompareOperationFeedback::kNone:
return CompareOperationHint::kNone;
case CompareOperationFeedback::kSignedSmall:
return CompareOperationHint::kSignedSmall;
case CompareOperationFeedback::kNumber:
return CompareOperationHint::kNumber;
case CompareOperationFeedback::kNumberOrOddball:
return CompareOperationHint::kNumberOrOddball;
case CompareOperationFeedback::kInternalizedString:
return CompareOperationHint::kInternalizedString;
case CompareOperationFeedback::kString:
return CompareOperationHint::kString;
case CompareOperationFeedback::kSymbol:
return CompareOperationHint::kSymbol;
case CompareOperationFeedback::kBigInt:
return CompareOperationHint::kBigInt;
case CompareOperationFeedback::kReceiver:
return CompareOperationHint::kReceiver;
case CompareOperationFeedback::kReceiverOrNullOrUndefined:
return CompareOperationHint::kReceiverOrNullOrUndefined;
default:
return CompareOperationHint::kAny;
}
UNREACHABLE();
}
// Helper function to transform the feedback to ForInHint.
ForInHint ForInHintFromFeedback(int type_feedback) {
switch (type_feedback) {
case ForInFeedback::kNone:
return ForInHint::kNone;
case ForInFeedback::kEnumCacheKeys:
return ForInHint::kEnumCacheKeys;
case ForInFeedback::kEnumCacheKeysAndIndices:
return ForInHint::kEnumCacheKeysAndIndices;
default:
return ForInHint::kAny;
}
UNREACHABLE();
}
Handle<Symbol> FeedbackVector::UninitializedSentinel(Isolate* isolate) {
return isolate->factory()->uninitialized_symbol();
}
Handle<Symbol> FeedbackVector::GenericSentinel(Isolate* isolate) {
return isolate->factory()->generic_symbol();
}
Handle<Symbol> FeedbackVector::MegamorphicSentinel(Isolate* isolate) {
return isolate->factory()->megamorphic_symbol();
}
Handle<Symbol> FeedbackVector::PremonomorphicSentinel(Isolate* isolate) {
return isolate->factory()->premonomorphic_symbol();
}
Symbol FeedbackVector::RawUninitializedSentinel(Isolate* isolate) {
return ReadOnlyRoots(isolate).uninitialized_symbol();
}
bool FeedbackMetadataIterator::HasNext() const {
return next_slot_.ToInt() < metadata()->slot_count();
}
FeedbackSlot FeedbackMetadataIterator::Next() {
DCHECK(HasNext());
cur_slot_ = next_slot_;
slot_kind_ = metadata()->GetKind(cur_slot_);
next_slot_ = FeedbackSlot(next_slot_.ToInt() + entry_size());
return cur_slot_;
}
int FeedbackMetadataIterator::entry_size() const {
return FeedbackMetadata::GetSlotSize(kind());
}
MaybeObject FeedbackNexus::GetFeedback() const {
MaybeObject feedback = vector()->Get(slot());
FeedbackVector::AssertNoLegacyTypes(feedback);
return feedback;
}
MaybeObject FeedbackNexus::GetFeedbackExtra() const {
#ifdef DEBUG
FeedbackSlotKind kind = vector()->GetKind(slot());
DCHECK_LT(1, FeedbackMetadata::GetSlotSize(kind));
#endif
int extra_index = vector()->GetIndex(slot()) + 1;
return vector()->get(extra_index);
}
void FeedbackNexus::SetFeedback(Object feedback, WriteBarrierMode mode) {
SetFeedback(MaybeObject::FromObject(feedback));
}
void FeedbackNexus::SetFeedback(MaybeObject feedback, WriteBarrierMode mode) {
FeedbackVector::AssertNoLegacyTypes(feedback);
vector()->Set(slot(), feedback, mode);
}
void FeedbackNexus::SetFeedbackExtra(Object feedback_extra,
WriteBarrierMode mode) {
#ifdef DEBUG
FeedbackSlotKind kind = vector()->GetKind(slot());
DCHECK_LT(1, FeedbackMetadata::GetSlotSize(kind));
FeedbackVector::AssertNoLegacyTypes(MaybeObject::FromObject(feedback_extra));
#endif
int index = vector()->GetIndex(slot()) + 1;
vector()->set(index, MaybeObject::FromObject(feedback_extra), mode);
}
void FeedbackNexus::SetFeedbackExtra(MaybeObject feedback_extra,
WriteBarrierMode mode) {
#ifdef DEBUG
FeedbackVector::AssertNoLegacyTypes(feedback_extra);
#endif
int index = vector()->GetIndex(slot()) + 1;
vector()->set(index, feedback_extra, mode);
}
Isolate* FeedbackNexus::GetIsolate() const { return vector()->GetIsolate(); }
} // namespace internal
} // namespace v8
#include "src/objects/object-macros-undef.h"
#endif // V8_FEEDBACK_VECTOR_INL_H_