// Copyright 2015 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/compiler/bytecode-graph-builder.h"
#include "src/ast/ast.h"
#include "src/ast/scopes.h"
#include "src/compilation-info.h"
#include "src/compiler/bytecode-branch-analysis.h"
#include "src/compiler/compiler-source-position-table.h"
#include "src/compiler/linkage.h"
#include "src/compiler/operator-properties.h"
#include "src/interpreter/bytecodes.h"
#include "src/objects-inl.h"
namespace v8 {
namespace internal {
namespace compiler {
// The abstract execution environment simulates the content of the interpreter
// register file. The environment performs SSA-renaming of all tracked nodes at
// split and merge points in the control flow.
class BytecodeGraphBuilder::Environment : public ZoneObject {
public:
Environment(BytecodeGraphBuilder* builder, int register_count,
int parameter_count, Node* control_dependency, Node* context);
// Specifies whether environment binding methods should attach frame state
// inputs to nodes representing the value being bound. This is done because
// the {OutputFrameStateCombine} is closely related to the binding method.
enum FrameStateAttachmentMode { kAttachFrameState, kDontAttachFrameState };
int parameter_count() const { return parameter_count_; }
int register_count() const { return register_count_; }
Node* LookupAccumulator() const;
Node* LookupRegister(interpreter::Register the_register) const;
void MarkAllRegistersLive();
void BindAccumulator(Node* node,
FrameStateAttachmentMode mode = kDontAttachFrameState);
void BindRegister(interpreter::Register the_register, Node* node,
FrameStateAttachmentMode mode = kDontAttachFrameState);
void BindRegistersToProjections(
interpreter::Register first_reg, Node* node,
FrameStateAttachmentMode mode = kDontAttachFrameState);
void RecordAfterState(Node* node,
FrameStateAttachmentMode mode = kDontAttachFrameState);
// Effect dependency tracked by this environment.
Node* GetEffectDependency() { return effect_dependency_; }
void UpdateEffectDependency(Node* dependency) {
effect_dependency_ = dependency;
}
// Preserve a checkpoint of the environment for the IR graph. Any
// further mutation of the environment will not affect checkpoints.
Node* Checkpoint(BailoutId bytecode_offset, OutputFrameStateCombine combine,
bool owner_has_exception);
// Control dependency tracked by this environment.
Node* GetControlDependency() const { return control_dependency_; }
void UpdateControlDependency(Node* dependency) {
control_dependency_ = dependency;
}
Node* Context() const { return context_; }
void SetContext(Node* new_context) { context_ = new_context; }
Environment* CopyForConditional();
Environment* CopyForLoop();
Environment* CopyForOsrEntry();
void Merge(Environment* other);
void PrepareForOsrEntry();
void PrepareForLoopExit(Node* loop);
private:
Environment(const Environment* copy, LivenessAnalyzerBlock* liveness_block);
void PrepareForLoop();
bool StateValuesRequireUpdate(Node** state_values, int offset, int count);
void UpdateStateValues(Node** state_values, int offset, int count);
int RegisterToValuesIndex(interpreter::Register the_register) const;
bool IsLivenessBlockConsistent() const;
Zone* zone() const { return builder_->local_zone(); }
Graph* graph() const { return builder_->graph(); }
CommonOperatorBuilder* common() const { return builder_->common(); }
BytecodeGraphBuilder* builder() const { return builder_; }
LivenessAnalyzerBlock* liveness_block() const { return liveness_block_; }
const NodeVector* values() const { return &values_; }
NodeVector* values() { return &values_; }
int register_base() const { return register_base_; }
int accumulator_base() const { return accumulator_base_; }
BytecodeGraphBuilder* builder_;
int register_count_;
int parameter_count_;
LivenessAnalyzerBlock* liveness_block_;
Node* context_;
Node* control_dependency_;
Node* effect_dependency_;
NodeVector values_;
Node* parameters_state_values_;
Node* registers_state_values_;
Node* accumulator_state_values_;
int register_base_;
int accumulator_base_;
};
// Issues:
// - Scopes - intimately tied to AST. Need to eval what is needed.
// - Need to resolve closure parameter treatment.
BytecodeGraphBuilder::Environment::Environment(BytecodeGraphBuilder* builder,
int register_count,
int parameter_count,
Node* control_dependency,
Node* context)
: builder_(builder),
register_count_(register_count),
parameter_count_(parameter_count),
liveness_block_(builder->is_liveness_analysis_enabled_
? builder_->liveness_analyzer()->NewBlock()
: nullptr),
context_(context),
control_dependency_(control_dependency),
effect_dependency_(control_dependency),
values_(builder->local_zone()),
parameters_state_values_(nullptr),
registers_state_values_(nullptr),
accumulator_state_values_(nullptr) {
// The layout of values_ is:
//
// [receiver] [parameters] [registers] [accumulator]
//
// parameter[0] is the receiver (this), parameters 1..N are the
// parameters supplied to the method (arg0..argN-1). The accumulator
// is stored separately.
// Parameters including the receiver
for (int i = 0; i < parameter_count; i++) {
const char* debug_name = (i == 0) ? "%this" : nullptr;
const Operator* op = common()->Parameter(i, debug_name);
Node* parameter = builder->graph()->NewNode(op, graph()->start());
values()->push_back(parameter);
}
// Registers
register_base_ = static_cast<int>(values()->size());
Node* undefined_constant = builder->jsgraph()->UndefinedConstant();
values()->insert(values()->end(), register_count, undefined_constant);
// Accumulator
accumulator_base_ = static_cast<int>(values()->size());
values()->push_back(undefined_constant);
}
BytecodeGraphBuilder::Environment::Environment(
const BytecodeGraphBuilder::Environment* other,
LivenessAnalyzerBlock* liveness_block)
: builder_(other->builder_),
register_count_(other->register_count_),
parameter_count_(other->parameter_count_),
liveness_block_(liveness_block),
context_(other->context_),
control_dependency_(other->control_dependency_),
effect_dependency_(other->effect_dependency_),
values_(other->zone()),
parameters_state_values_(nullptr),
registers_state_values_(nullptr),
accumulator_state_values_(nullptr),
register_base_(other->register_base_),
accumulator_base_(other->accumulator_base_) {
values_ = other->values_;
}
int BytecodeGraphBuilder::Environment::RegisterToValuesIndex(
interpreter::Register the_register) const {
if (the_register.is_parameter()) {
return the_register.ToParameterIndex(parameter_count());
} else {
return the_register.index() + register_base();
}
}
bool BytecodeGraphBuilder::Environment::IsLivenessBlockConsistent() const {
return !builder_->IsLivenessAnalysisEnabled() ==
(liveness_block() == nullptr);
}
Node* BytecodeGraphBuilder::Environment::LookupAccumulator() const {
DCHECK(IsLivenessBlockConsistent());
if (liveness_block() != nullptr) {
liveness_block()->LookupAccumulator();
}
return values()->at(accumulator_base_);
}
Node* BytecodeGraphBuilder::Environment::LookupRegister(
interpreter::Register the_register) const {
if (the_register.is_current_context()) {
return Context();
} else if (the_register.is_function_closure()) {
return builder()->GetFunctionClosure();
} else if (the_register.is_new_target()) {
return builder()->GetNewTarget();
} else {
int values_index = RegisterToValuesIndex(the_register);
if (liveness_block() != nullptr && !the_register.is_parameter()) {
DCHECK(IsLivenessBlockConsistent());
liveness_block()->Lookup(the_register.index());
}
return values()->at(values_index);
}
}
void BytecodeGraphBuilder::Environment::MarkAllRegistersLive() {
DCHECK(IsLivenessBlockConsistent());
if (liveness_block() != nullptr) {
for (int i = 0; i < register_count(); ++i) {
liveness_block()->Lookup(i);
}
}
}
void BytecodeGraphBuilder::Environment::BindAccumulator(
Node* node, FrameStateAttachmentMode mode) {
if (mode == FrameStateAttachmentMode::kAttachFrameState) {
builder()->PrepareFrameState(node, OutputFrameStateCombine::PokeAt(0));
}
DCHECK(IsLivenessBlockConsistent());
if (liveness_block() != nullptr) {
liveness_block()->BindAccumulator();
}
values()->at(accumulator_base_) = node;
}
void BytecodeGraphBuilder::Environment::BindRegister(
interpreter::Register the_register, Node* node,
FrameStateAttachmentMode mode) {
int values_index = RegisterToValuesIndex(the_register);
if (mode == FrameStateAttachmentMode::kAttachFrameState) {
builder()->PrepareFrameState(node, OutputFrameStateCombine::PokeAt(
accumulator_base_ - values_index));
}
values()->at(values_index) = node;
if (liveness_block() != nullptr && !the_register.is_parameter()) {
DCHECK(IsLivenessBlockConsistent());
liveness_block()->Bind(the_register.index());
}
}
void BytecodeGraphBuilder::Environment::BindRegistersToProjections(
interpreter::Register first_reg, Node* node,
FrameStateAttachmentMode mode) {
int values_index = RegisterToValuesIndex(first_reg);
if (mode == FrameStateAttachmentMode::kAttachFrameState) {
builder()->PrepareFrameState(node, OutputFrameStateCombine::PokeAt(
accumulator_base_ - values_index));
}
for (int i = 0; i < node->op()->ValueOutputCount(); i++) {
values()->at(values_index + i) =
builder()->NewNode(common()->Projection(i), node);
}
}
void BytecodeGraphBuilder::Environment::RecordAfterState(
Node* node, FrameStateAttachmentMode mode) {
if (mode == FrameStateAttachmentMode::kAttachFrameState) {
builder()->PrepareFrameState(node, OutputFrameStateCombine::Ignore());
}
}
BytecodeGraphBuilder::Environment*
BytecodeGraphBuilder::Environment::CopyForLoop() {
PrepareForLoop();
if (liveness_block() != nullptr) {
// Finish the current block before copying.
liveness_block_ = builder_->liveness_analyzer()->NewBlock(liveness_block());
}
return new (zone()) Environment(this, liveness_block());
}
BytecodeGraphBuilder::Environment*
BytecodeGraphBuilder::Environment::CopyForOsrEntry() {
return new (zone())
Environment(this, builder_->liveness_analyzer()->NewBlock());
}
BytecodeGraphBuilder::Environment*
BytecodeGraphBuilder::Environment::CopyForConditional() {
LivenessAnalyzerBlock* copy_liveness_block = nullptr;
if (liveness_block() != nullptr) {
copy_liveness_block =
builder_->liveness_analyzer()->NewBlock(liveness_block());
liveness_block_ = builder_->liveness_analyzer()->NewBlock(liveness_block());
}
return new (zone()) Environment(this, copy_liveness_block);
}
void BytecodeGraphBuilder::Environment::Merge(
BytecodeGraphBuilder::Environment* other) {
if (builder_->is_liveness_analysis_enabled_) {
if (GetControlDependency()->opcode() != IrOpcode::kLoop) {
liveness_block_ =
builder()->liveness_analyzer()->NewBlock(liveness_block());
}
liveness_block()->AddPredecessor(other->liveness_block());
}
// Create a merge of the control dependencies of both environments and update
// the current environment's control dependency accordingly.
Node* control = builder()->MergeControl(GetControlDependency(),
other->GetControlDependency());
UpdateControlDependency(control);
// Create a merge of the effect dependencies of both environments and update
// the current environment's effect dependency accordingly.
Node* effect = builder()->MergeEffect(GetEffectDependency(),
other->GetEffectDependency(), control);
UpdateEffectDependency(effect);
// Introduce Phi nodes for values that have differing input at merge points,
// potentially extending an existing Phi node if possible.
context_ = builder()->MergeValue(context_, other->context_, control);
for (size_t i = 0; i < values_.size(); i++) {
values_[i] = builder()->MergeValue(values_[i], other->values_[i], control);
}
}
void BytecodeGraphBuilder::Environment::PrepareForLoop() {
// Create a control node for the loop header.
Node* control = builder()->NewLoop();
// Create a Phi for external effects.
Node* effect = builder()->NewEffectPhi(1, GetEffectDependency(), control);
UpdateEffectDependency(effect);
// Assume everything in the loop is updated.
context_ = builder()->NewPhi(1, context_, control);
int size = static_cast<int>(values()->size());
for (int i = 0; i < size; i++) {
values()->at(i) = builder()->NewPhi(1, values()->at(i), control);
}
// Connect to the loop end.
Node* terminate = builder()->graph()->NewNode(
builder()->common()->Terminate(), effect, control);
builder()->exit_controls_.push_back(terminate);
}
void BytecodeGraphBuilder::Environment::PrepareForOsrEntry() {
DCHECK_EQ(IrOpcode::kLoop, GetControlDependency()->opcode());
DCHECK_EQ(1, GetControlDependency()->InputCount());
Node* start = graph()->start();
// Create a control node for the OSR entry point and update the current
// environment's dependencies accordingly.
Node* entry = graph()->NewNode(common()->OsrLoopEntry(), start, start);
UpdateControlDependency(entry);
UpdateEffectDependency(entry);
// Create OSR values for each environment value.
SetContext(graph()->NewNode(
common()->OsrValue(Linkage::kOsrContextSpillSlotIndex), entry));
int size = static_cast<int>(values()->size());
for (int i = 0; i < size; i++) {
int idx = i; // Indexing scheme follows {StandardFrame}, adapt accordingly.
if (i >= register_base()) idx += InterpreterFrameConstants::kExtraSlotCount;
if (i >= accumulator_base()) idx = Linkage::kOsrAccumulatorRegisterIndex;
values()->at(i) = graph()->NewNode(common()->OsrValue(idx), entry);
}
BailoutId loop_id(builder_->bytecode_iterator().current_offset());
Node* frame_state =
Checkpoint(loop_id, OutputFrameStateCombine::Ignore(), false);
Node* checkpoint =
graph()->NewNode(common()->Checkpoint(), frame_state, entry, entry);
UpdateEffectDependency(checkpoint);
// Create the OSR guard nodes.
const Operator* guard_op = common()->OsrGuard(OsrGuardType::kUninitialized);
Node* effect = checkpoint;
for (int i = 0; i < size; i++) {
values()->at(i) = effect =
graph()->NewNode(guard_op, values()->at(i), effect, entry);
}
Node* context = effect = graph()->NewNode(guard_op, Context(), effect, entry);
SetContext(context);
UpdateEffectDependency(effect);
}
bool BytecodeGraphBuilder::Environment::StateValuesRequireUpdate(
Node** state_values, int offset, int count) {
if (*state_values == nullptr) {
return true;
}
DCHECK_EQ((*state_values)->InputCount(), count);
DCHECK_LE(static_cast<size_t>(offset + count), values()->size());
Node** env_values = (count == 0) ? nullptr : &values()->at(offset);
for (int i = 0; i < count; i++) {
if ((*state_values)->InputAt(i) != env_values[i]) {
return true;
}
}
return false;
}
void BytecodeGraphBuilder::Environment::PrepareForLoopExit(Node* loop) {
DCHECK_EQ(loop->opcode(), IrOpcode::kLoop);
Node* control = GetControlDependency();
// Create the loop exit node.
Node* loop_exit = graph()->NewNode(common()->LoopExit(), control, loop);
UpdateControlDependency(loop_exit);
// Rename the effect.
Node* effect_rename = graph()->NewNode(common()->LoopExitEffect(),
GetEffectDependency(), loop_exit);
UpdateEffectDependency(effect_rename);
// TODO(jarin) We should also rename context here. However, uncoditional
// renaming confuses global object and native context specialization.
// We should only rename if the context is assigned in the loop.
// Rename the environmnent values.
for (size_t i = 0; i < values_.size(); i++) {
Node* rename =
graph()->NewNode(common()->LoopExitValue(), values_[i], loop_exit);
values_[i] = rename;
}
}
void BytecodeGraphBuilder::Environment::UpdateStateValues(Node** state_values,
int offset,
int count) {
if (StateValuesRequireUpdate(state_values, offset, count)) {
const Operator* op = common()->StateValues(count);
(*state_values) = graph()->NewNode(op, count, &values()->at(offset));
}
}
Node* BytecodeGraphBuilder::Environment::Checkpoint(
BailoutId bailout_id, OutputFrameStateCombine combine,
bool owner_has_exception) {
UpdateStateValues(¶meters_state_values_, 0, parameter_count());
UpdateStateValues(®isters_state_values_, register_base(),
register_count());
UpdateStateValues(&accumulator_state_values_, accumulator_base(), 1);
const Operator* op = common()->FrameState(
bailout_id, combine, builder()->frame_state_function_info());
Node* result = graph()->NewNode(
op, parameters_state_values_, registers_state_values_,
accumulator_state_values_, Context(), builder()->GetFunctionClosure(),
builder()->graph()->start());
if (liveness_block() != nullptr) {
// If the owning node has an exception, register the checkpoint to the
// predecessor so that the checkpoint is used for both the normal and the
// exceptional paths. Yes, this is a terrible hack and we might want
// to use an explicit frame state for the exceptional path.
if (owner_has_exception) {
liveness_block()->GetPredecessor()->Checkpoint(result);
} else {
liveness_block()->Checkpoint(result);
}
}
return result;
}
BytecodeGraphBuilder::BytecodeGraphBuilder(
Zone* local_zone, CompilationInfo* info, JSGraph* jsgraph,
float invocation_frequency, SourcePositionTable* source_positions,
int inlining_id)
: local_zone_(local_zone),
jsgraph_(jsgraph),
invocation_frequency_(invocation_frequency),
bytecode_array_(handle(info->shared_info()->bytecode_array())),
exception_handler_table_(
handle(HandlerTable::cast(bytecode_array()->handler_table()))),
feedback_vector_(handle(info->closure()->feedback_vector())),
frame_state_function_info_(common()->CreateFrameStateFunctionInfo(
FrameStateType::kInterpretedFunction,
bytecode_array()->parameter_count(),
bytecode_array()->register_count(), info->shared_info())),
osr_ast_id_(info->osr_ast_id()),
merge_environments_(local_zone),
exception_handlers_(local_zone),
current_exception_handler_(0),
input_buffer_size_(0),
input_buffer_(nullptr),
exit_controls_(local_zone),
is_liveness_analysis_enabled_(FLAG_analyze_environment_liveness &&
info->is_deoptimization_enabled()),
state_values_cache_(jsgraph),
liveness_analyzer_(
static_cast<size_t>(bytecode_array()->register_count()), true,
local_zone),
source_positions_(source_positions),
start_position_(info->shared_info()->start_position(), inlining_id) {}
Node* BytecodeGraphBuilder::GetNewTarget() {
if (!new_target_.is_set()) {
int params = bytecode_array()->parameter_count();
int index = Linkage::GetJSCallNewTargetParamIndex(params);
const Operator* op = common()->Parameter(index, "%new.target");
Node* node = NewNode(op, graph()->start());
new_target_.set(node);
}
return new_target_.get();
}
Node* BytecodeGraphBuilder::GetFunctionContext() {
if (!function_context_.is_set()) {
int params = bytecode_array()->parameter_count();
int index = Linkage::GetJSCallContextParamIndex(params);
const Operator* op = common()->Parameter(index, "%context");
Node* node = NewNode(op, graph()->start());
function_context_.set(node);
}
return function_context_.get();
}
Node* BytecodeGraphBuilder::GetFunctionClosure() {
if (!function_closure_.is_set()) {
int index = Linkage::kJSCallClosureParamIndex;
const Operator* op = common()->Parameter(index, "%closure");
Node* node = NewNode(op, graph()->start());
function_closure_.set(node);
}
return function_closure_.get();
}
Node* BytecodeGraphBuilder::BuildLoadNativeContextField(int index) {
const Operator* op =
javascript()->LoadContext(0, Context::NATIVE_CONTEXT_INDEX, true);
Node* native_context = NewNode(op, environment()->Context());
return NewNode(javascript()->LoadContext(0, index, true), native_context);
}
VectorSlotPair BytecodeGraphBuilder::CreateVectorSlotPair(int slot_id) {
FeedbackVectorSlot slot;
if (slot_id >= TypeFeedbackVector::kReservedIndexCount) {
slot = feedback_vector()->ToSlot(slot_id);
}
return VectorSlotPair(feedback_vector(), slot);
}
bool BytecodeGraphBuilder::CreateGraph(bool stack_check) {
SourcePositionTable::Scope pos_scope(source_positions_, start_position_);
// Set up the basic structure of the graph. Outputs for {Start} are the formal
// parameters (including the receiver) plus new target, number of arguments,
// context and closure.
int actual_parameter_count = bytecode_array()->parameter_count() + 4;
graph()->SetStart(graph()->NewNode(common()->Start(actual_parameter_count)));
Environment env(this, bytecode_array()->register_count(),
bytecode_array()->parameter_count(), graph()->start(),
GetFunctionContext());
set_environment(&env);
VisitBytecodes(stack_check);
// Finish the basic structure of the graph.
DCHECK_NE(0u, exit_controls_.size());
int const input_count = static_cast<int>(exit_controls_.size());
Node** const inputs = &exit_controls_.front();
Node* end = graph()->NewNode(common()->End(input_count), input_count, inputs);
graph()->SetEnd(end);
ClearNonLiveSlotsInFrameStates();
return true;
}
void BytecodeGraphBuilder::PrepareEagerCheckpoint() {
if (environment()->GetEffectDependency()->opcode() != IrOpcode::kCheckpoint) {
// Create an explicit checkpoint node for before the operation. This only
// needs to happen if we aren't effect-dominated by a {Checkpoint} already.
Node* node = NewNode(common()->Checkpoint());
DCHECK_EQ(1, OperatorProperties::GetFrameStateInputCount(node->op()));
DCHECK_EQ(IrOpcode::kDead,
NodeProperties::GetFrameStateInput(node)->opcode());
BailoutId bailout_id(bytecode_iterator().current_offset());
Node* frame_state_before = environment()->Checkpoint(
bailout_id, OutputFrameStateCombine::Ignore(), false);
NodeProperties::ReplaceFrameStateInput(node, frame_state_before);
}
}
void BytecodeGraphBuilder::PrepareFrameState(Node* node,
OutputFrameStateCombine combine) {
if (OperatorProperties::HasFrameStateInput(node->op())) {
// Add the frame state for after the operation. The node in question has
// already been created and had a {Dead} frame state input up until now.
DCHECK_EQ(1, OperatorProperties::GetFrameStateInputCount(node->op()));
DCHECK_EQ(IrOpcode::kDead,
NodeProperties::GetFrameStateInput(node)->opcode());
BailoutId bailout_id(bytecode_iterator().current_offset());
bool has_exception = NodeProperties::IsExceptionalCall(node);
Node* frame_state_after =
environment()->Checkpoint(bailout_id, combine, has_exception);
NodeProperties::ReplaceFrameStateInput(node, frame_state_after);
}
}
void BytecodeGraphBuilder::ClearNonLiveSlotsInFrameStates() {
if (!IsLivenessAnalysisEnabled()) {
return;
}
NonLiveFrameStateSlotReplacer replacer(
&state_values_cache_, jsgraph()->OptimizedOutConstant(),
liveness_analyzer()->local_count(), true, local_zone());
liveness_analyzer()->Run(&replacer);
if (FLAG_trace_environment_liveness) {
OFStream os(stdout);
liveness_analyzer()->Print(os);
}
}
void BytecodeGraphBuilder::VisitBytecodes(bool stack_check) {
BytecodeBranchAnalysis analysis(bytecode_array(), local_zone());
BytecodeLoopAnalysis loop_analysis(bytecode_array(), &analysis, local_zone());
analysis.Analyze();
loop_analysis.Analyze();
set_branch_analysis(&analysis);
set_loop_analysis(&loop_analysis);
interpreter::BytecodeArrayIterator iterator(bytecode_array());
set_bytecode_iterator(&iterator);
SourcePositionTableIterator source_position_iterator(
bytecode_array()->source_position_table());
BuildOSRNormalEntryPoint();
for (; !iterator.done(); iterator.Advance()) {
int current_offset = iterator.current_offset();
UpdateCurrentSourcePosition(&source_position_iterator, current_offset);
EnterAndExitExceptionHandlers(current_offset);
SwitchToMergeEnvironment(current_offset);
if (environment() != nullptr) {
BuildLoopHeaderEnvironment(current_offset);
BuildOSRLoopEntryPoint(current_offset);
// Skip the first stack check if stack_check is false
if (!stack_check &&
iterator.current_bytecode() == interpreter::Bytecode::kStackCheck) {
stack_check = true;
continue;
}
switch (iterator.current_bytecode()) {
#define BYTECODE_CASE(name, ...) \
case interpreter::Bytecode::k##name: \
Visit##name(); \
break;
BYTECODE_LIST(BYTECODE_CASE)
#undef BYTECODE_CODE
}
}
}
set_branch_analysis(nullptr);
set_bytecode_iterator(nullptr);
DCHECK(exception_handlers_.empty());
}
void BytecodeGraphBuilder::VisitLdaZero() {
Node* node = jsgraph()->ZeroConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaSmi() {
Node* node = jsgraph()->Constant(bytecode_iterator().GetImmediateOperand(0));
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaConstant() {
Node* node =
jsgraph()->Constant(bytecode_iterator().GetConstantForIndexOperand(0));
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaUndefined() {
Node* node = jsgraph()->UndefinedConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaNull() {
Node* node = jsgraph()->NullConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaTheHole() {
Node* node = jsgraph()->TheHoleConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaTrue() {
Node* node = jsgraph()->TrueConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaFalse() {
Node* node = jsgraph()->FalseConstant();
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdar() {
Node* value =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
environment()->BindAccumulator(value);
}
void BytecodeGraphBuilder::VisitStar() {
Node* value = environment()->LookupAccumulator();
environment()->BindRegister(bytecode_iterator().GetRegisterOperand(0), value);
}
void BytecodeGraphBuilder::VisitMov() {
Node* value =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
environment()->BindRegister(bytecode_iterator().GetRegisterOperand(1), value);
}
Node* BytecodeGraphBuilder::BuildLoadGlobal(uint32_t feedback_slot_index,
TypeofMode typeof_mode) {
VectorSlotPair feedback = CreateVectorSlotPair(feedback_slot_index);
DCHECK_EQ(FeedbackVectorSlotKind::LOAD_GLOBAL_IC,
feedback_vector()->GetKind(feedback.slot()));
Handle<Name> name(feedback_vector()->GetName(feedback.slot()));
const Operator* op = javascript()->LoadGlobal(name, feedback, typeof_mode);
return NewNode(op, GetFunctionClosure());
}
void BytecodeGraphBuilder::VisitLdaGlobal() {
PrepareEagerCheckpoint();
Node* node = BuildLoadGlobal(bytecode_iterator().GetIndexOperand(0),
TypeofMode::NOT_INSIDE_TYPEOF);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitLdaGlobalInsideTypeof() {
PrepareEagerCheckpoint();
Node* node = BuildLoadGlobal(bytecode_iterator().GetIndexOperand(0),
TypeofMode::INSIDE_TYPEOF);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::BuildStoreGlobal(LanguageMode language_mode) {
PrepareEagerCheckpoint();
Handle<Name> name =
Handle<Name>::cast(bytecode_iterator().GetConstantForIndexOperand(0));
VectorSlotPair feedback =
CreateVectorSlotPair(bytecode_iterator().GetIndexOperand(1));
Node* value = environment()->LookupAccumulator();
const Operator* op = javascript()->StoreGlobal(language_mode, name, feedback);
Node* node = NewNode(op, value, GetFunctionClosure());
environment()->RecordAfterState(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitStaGlobalSloppy() {
BuildStoreGlobal(LanguageMode::SLOPPY);
}
void BytecodeGraphBuilder::VisitStaGlobalStrict() {
BuildStoreGlobal(LanguageMode::STRICT);
}
void BytecodeGraphBuilder::VisitLdaContextSlot() {
// TODO(mythria): immutable flag is also set to false. This information is not
// available in bytecode array. update this code when the implementation
// changes.
const Operator* op = javascript()->LoadContext(
bytecode_iterator().GetUnsignedImmediateOperand(2),
bytecode_iterator().GetIndexOperand(1), false);
Node* context =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* node = NewNode(op, context);
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitLdaCurrentContextSlot() {
// TODO(mythria): immutable flag is also set to false. This information is not
// available in bytecode array. update this code when the implementation
// changes.
const Operator* op = javascript()->LoadContext(
0, bytecode_iterator().GetIndexOperand(0), false);
Node* context = environment()->Context();
Node* node = NewNode(op, context);
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitStaContextSlot() {
const Operator* op = javascript()->StoreContext(
bytecode_iterator().GetUnsignedImmediateOperand(2),
bytecode_iterator().GetIndexOperand(1));
Node* context =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* value = environment()->LookupAccumulator();
NewNode(op, context, value);
}
void BytecodeGraphBuilder::VisitStaCurrentContextSlot() {
const Operator* op =
javascript()->StoreContext(0, bytecode_iterator().GetIndexOperand(0));
Node* context = environment()->Context();
Node* value = environment()->LookupAccumulator();
NewNode(op, context, value);
}
void BytecodeGraphBuilder::BuildLdaLookupSlot(TypeofMode typeof_mode) {
PrepareEagerCheckpoint();
Node* name =
jsgraph()->Constant(bytecode_iterator().GetConstantForIndexOperand(0));
const Operator* op =
javascript()->CallRuntime(typeof_mode == TypeofMode::NOT_INSIDE_TYPEOF
? Runtime::kLoadLookupSlot
: Runtime::kLoadLookupSlotInsideTypeof);
Node* value = NewNode(op, name);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitLdaLookupSlot() {
BuildLdaLookupSlot(TypeofMode::NOT_INSIDE_TYPEOF);
}
void BytecodeGraphBuilder::VisitLdaLookupSlotInsideTypeof() {
BuildLdaLookupSlot(TypeofMode::INSIDE_TYPEOF);
}
BytecodeGraphBuilder::Environment* BytecodeGraphBuilder::CheckContextExtensions(
uint32_t depth) {
// Output environment where the context has an extension
Environment* slow_environment = nullptr;
// We only need to check up to the last-but-one depth, because the an eval in
// the same scope as the variable itself has no way of shadowing it.
for (uint32_t d = 0; d < depth; d++) {
Node* extension_slot =
NewNode(javascript()->LoadContext(d, Context::EXTENSION_INDEX, false),
environment()->Context());
Node* check_no_extension =
NewNode(javascript()->StrictEqual(CompareOperationHint::kAny),
extension_slot, jsgraph()->TheHoleConstant());
NewBranch(check_no_extension);
Environment* true_environment = environment()->CopyForConditional();
{
NewIfFalse();
// If there is an extension, merge into the slow path.
if (slow_environment == nullptr) {
slow_environment = environment();
NewMerge();
} else {
slow_environment->Merge(environment());
}
}
{
set_environment(true_environment);
NewIfTrue();
// Do nothing on if there is no extension, eventually falling through to
// the fast path.
}
}
// The depth can be zero, in which case no slow-path checks are built, and the
// slow path environment can be null.
DCHECK(depth == 0 || slow_environment != nullptr);
return slow_environment;
}
void BytecodeGraphBuilder::BuildLdaLookupContextSlot(TypeofMode typeof_mode) {
uint32_t depth = bytecode_iterator().GetUnsignedImmediateOperand(2);
// Check if any context in the depth has an extension.
Environment* slow_environment = CheckContextExtensions(depth);
// Fast path, do a context load.
{
uint32_t slot_index = bytecode_iterator().GetIndexOperand(1);
const Operator* op = javascript()->LoadContext(depth, slot_index, false);
Node* context = environment()->Context();
environment()->BindAccumulator(NewNode(op, context));
}
// Only build the slow path if there were any slow-path checks.
if (slow_environment != nullptr) {
// Add a merge to the fast environment.
NewMerge();
Environment* fast_environment = environment();
// Slow path, do a runtime load lookup.
set_environment(slow_environment);
{
Node* name = jsgraph()->Constant(
bytecode_iterator().GetConstantForIndexOperand(0));
const Operator* op =
javascript()->CallRuntime(typeof_mode == TypeofMode::NOT_INSIDE_TYPEOF
? Runtime::kLoadLookupSlot
: Runtime::kLoadLookupSlotInsideTypeof);
Node* value = NewNode(op, name);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
fast_environment->Merge(environment());
set_environment(fast_environment);
}
}
void BytecodeGraphBuilder::VisitLdaLookupContextSlot() {
BuildLdaLookupContextSlot(TypeofMode::NOT_INSIDE_TYPEOF);
}
void BytecodeGraphBuilder::VisitLdaLookupContextSlotInsideTypeof() {
BuildLdaLookupContextSlot(TypeofMode::INSIDE_TYPEOF);
}
void BytecodeGraphBuilder::BuildLdaLookupGlobalSlot(TypeofMode typeof_mode) {
uint32_t depth = bytecode_iterator().GetUnsignedImmediateOperand(2);
// Check if any context in the depth has an extension.
Environment* slow_environment = CheckContextExtensions(depth);
// Fast path, do a global load.
{
PrepareEagerCheckpoint();
Node* node =
BuildLoadGlobal(bytecode_iterator().GetIndexOperand(1), typeof_mode);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
// Only build the slow path if there were any slow-path checks.
if (slow_environment != nullptr) {
// Add a merge to the fast environment.
NewMerge();
Environment* fast_environment = environment();
// Slow path, do a runtime load lookup.
set_environment(slow_environment);
{
Node* name = jsgraph()->Constant(
bytecode_iterator().GetConstantForIndexOperand(0));
const Operator* op =
javascript()->CallRuntime(typeof_mode == TypeofMode::NOT_INSIDE_TYPEOF
? Runtime::kLoadLookupSlot
: Runtime::kLoadLookupSlotInsideTypeof);
Node* value = NewNode(op, name);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
fast_environment->Merge(environment());
set_environment(fast_environment);
}
}
void BytecodeGraphBuilder::VisitLdaLookupGlobalSlot() {
BuildLdaLookupGlobalSlot(TypeofMode::NOT_INSIDE_TYPEOF);
}
void BytecodeGraphBuilder::VisitLdaLookupGlobalSlotInsideTypeof() {
BuildLdaLookupGlobalSlot(TypeofMode::INSIDE_TYPEOF);
}
void BytecodeGraphBuilder::BuildStaLookupSlot(LanguageMode language_mode) {
PrepareEagerCheckpoint();
Node* value = environment()->LookupAccumulator();
Node* name =
jsgraph()->Constant(bytecode_iterator().GetConstantForIndexOperand(0));
const Operator* op = javascript()->CallRuntime(
is_strict(language_mode) ? Runtime::kStoreLookupSlot_Strict
: Runtime::kStoreLookupSlot_Sloppy);
Node* store = NewNode(op, name, value);
environment()->BindAccumulator(store, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitStaLookupSlotSloppy() {
BuildStaLookupSlot(LanguageMode::SLOPPY);
}
void BytecodeGraphBuilder::VisitStaLookupSlotStrict() {
BuildStaLookupSlot(LanguageMode::STRICT);
}
void BytecodeGraphBuilder::VisitLdaNamedProperty() {
PrepareEagerCheckpoint();
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Handle<Name> name =
Handle<Name>::cast(bytecode_iterator().GetConstantForIndexOperand(1));
VectorSlotPair feedback =
CreateVectorSlotPair(bytecode_iterator().GetIndexOperand(2));
const Operator* op = javascript()->LoadNamed(name, feedback);
Node* node = NewNode(op, object, GetFunctionClosure());
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitLdaKeyedProperty() {
PrepareEagerCheckpoint();
Node* key = environment()->LookupAccumulator();
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
VectorSlotPair feedback =
CreateVectorSlotPair(bytecode_iterator().GetIndexOperand(1));
const Operator* op = javascript()->LoadProperty(feedback);
Node* node = NewNode(op, object, key, GetFunctionClosure());
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::BuildNamedStore(LanguageMode language_mode) {
PrepareEagerCheckpoint();
Node* value = environment()->LookupAccumulator();
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Handle<Name> name =
Handle<Name>::cast(bytecode_iterator().GetConstantForIndexOperand(1));
VectorSlotPair feedback =
CreateVectorSlotPair(bytecode_iterator().GetIndexOperand(2));
const Operator* op = javascript()->StoreNamed(language_mode, name, feedback);
Node* node = NewNode(op, object, value, GetFunctionClosure());
environment()->RecordAfterState(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitStaNamedPropertySloppy() {
BuildNamedStore(LanguageMode::SLOPPY);
}
void BytecodeGraphBuilder::VisitStaNamedPropertyStrict() {
BuildNamedStore(LanguageMode::STRICT);
}
void BytecodeGraphBuilder::BuildKeyedStore(LanguageMode language_mode) {
PrepareEagerCheckpoint();
Node* value = environment()->LookupAccumulator();
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* key =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(1));
VectorSlotPair feedback =
CreateVectorSlotPair(bytecode_iterator().GetIndexOperand(2));
const Operator* op = javascript()->StoreProperty(language_mode, feedback);
Node* node = NewNode(op, object, key, value, GetFunctionClosure());
environment()->RecordAfterState(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitStaKeyedPropertySloppy() {
BuildKeyedStore(LanguageMode::SLOPPY);
}
void BytecodeGraphBuilder::VisitStaKeyedPropertyStrict() {
BuildKeyedStore(LanguageMode::STRICT);
}
void BytecodeGraphBuilder::VisitLdaModuleVariable() {
int32_t cell_index = bytecode_iterator().GetImmediateOperand(0);
uint32_t depth = bytecode_iterator().GetUnsignedImmediateOperand(1);
Node* module =
NewNode(javascript()->LoadContext(depth, Context::EXTENSION_INDEX, false),
environment()->Context());
Node* value = NewNode(javascript()->LoadModule(cell_index), module);
environment()->BindAccumulator(value);
}
void BytecodeGraphBuilder::VisitStaModuleVariable() {
int32_t cell_index = bytecode_iterator().GetImmediateOperand(0);
uint32_t depth = bytecode_iterator().GetUnsignedImmediateOperand(1);
Node* module =
NewNode(javascript()->LoadContext(depth, Context::EXTENSION_INDEX, false),
environment()->Context());
Node* value = environment()->LookupAccumulator();
NewNode(javascript()->StoreModule(cell_index), module, value);
}
void BytecodeGraphBuilder::VisitPushContext() {
Node* new_context = environment()->LookupAccumulator();
environment()->BindRegister(bytecode_iterator().GetRegisterOperand(0),
environment()->Context());
environment()->SetContext(new_context);
}
void BytecodeGraphBuilder::VisitPopContext() {
Node* context =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
environment()->SetContext(context);
}
void BytecodeGraphBuilder::VisitCreateClosure() {
Handle<SharedFunctionInfo> shared_info = Handle<SharedFunctionInfo>::cast(
bytecode_iterator().GetConstantForIndexOperand(0));
PretenureFlag tenured =
interpreter::CreateClosureFlags::PretenuredBit::decode(
bytecode_iterator().GetFlagOperand(1))
? TENURED
: NOT_TENURED;
const Operator* op = javascript()->CreateClosure(shared_info, tenured);
Node* closure = NewNode(op);
environment()->BindAccumulator(closure);
}
void BytecodeGraphBuilder::VisitCreateBlockContext() {
Handle<ScopeInfo> scope_info = Handle<ScopeInfo>::cast(
bytecode_iterator().GetConstantForIndexOperand(0));
const Operator* op = javascript()->CreateBlockContext(scope_info);
Node* context = NewNode(op, environment()->LookupAccumulator());
environment()->BindAccumulator(context);
}
void BytecodeGraphBuilder::VisitCreateFunctionContext() {
uint32_t slots = bytecode_iterator().GetUnsignedImmediateOperand(0);
const Operator* op = javascript()->CreateFunctionContext(slots);
Node* context = NewNode(op, GetFunctionClosure());
environment()->BindAccumulator(context);
}
void BytecodeGraphBuilder::VisitCreateCatchContext() {
interpreter::Register reg = bytecode_iterator().GetRegisterOperand(0);
Node* exception = environment()->LookupRegister(reg);
Handle<String> name =
Handle<String>::cast(bytecode_iterator().GetConstantForIndexOperand(1));
Handle<ScopeInfo> scope_info = Handle<ScopeInfo>::cast(
bytecode_iterator().GetConstantForIndexOperand(2));
Node* closure = environment()->LookupAccumulator();
const Operator* op = javascript()->CreateCatchContext(name, scope_info);
Node* context = NewNode(op, exception, closure);
environment()->BindAccumulator(context);
}
void BytecodeGraphBuilder::VisitCreateWithContext() {
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Handle<ScopeInfo> scope_info = Handle<ScopeInfo>::cast(
bytecode_iterator().GetConstantForIndexOperand(1));
const Operator* op = javascript()->CreateWithContext(scope_info);
Node* context = NewNode(op, object, environment()->LookupAccumulator());
environment()->BindAccumulator(context);
}
void BytecodeGraphBuilder::BuildCreateArguments(CreateArgumentsType type) {
const Operator* op = javascript()->CreateArguments(type);
Node* object = NewNode(op, GetFunctionClosure());
environment()->BindAccumulator(object, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitCreateMappedArguments() {
BuildCreateArguments(CreateArgumentsType::kMappedArguments);
}
void BytecodeGraphBuilder::VisitCreateUnmappedArguments() {
BuildCreateArguments(CreateArgumentsType::kUnmappedArguments);
}
void BytecodeGraphBuilder::VisitCreateRestParameter() {
BuildCreateArguments(CreateArgumentsType::kRestParameter);
}
void BytecodeGraphBuilder::VisitCreateRegExpLiteral() {
Handle<String> constant_pattern =
Handle<String>::cast(bytecode_iterator().GetConstantForIndexOperand(0));
int literal_index = bytecode_iterator().GetIndexOperand(1);
int literal_flags = bytecode_iterator().GetFlagOperand(2);
Node* literal = NewNode(javascript()->CreateLiteralRegExp(
constant_pattern, literal_flags, literal_index),
GetFunctionClosure());
environment()->BindAccumulator(literal, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitCreateArrayLiteral() {
Handle<FixedArray> constant_elements = Handle<FixedArray>::cast(
bytecode_iterator().GetConstantForIndexOperand(0));
int literal_index = bytecode_iterator().GetIndexOperand(1);
int literal_flags = bytecode_iterator().GetFlagOperand(2);
// Disable allocation site mementos. Only unoptimized code will collect
// feedback about allocation site. Once the code is optimized we expect the
// data to converge. So, we disable allocation site mementos in optimized
// code. We can revisit this when we have data to the contrary.
literal_flags |= ArrayLiteral::kDisableMementos;
int number_of_elements = constant_elements->length();
Node* literal = NewNode(
javascript()->CreateLiteralArray(constant_elements, literal_flags,
literal_index, number_of_elements),
GetFunctionClosure());
environment()->BindAccumulator(literal, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitCreateObjectLiteral() {
PrepareEagerCheckpoint();
Handle<FixedArray> constant_properties = Handle<FixedArray>::cast(
bytecode_iterator().GetConstantForIndexOperand(0));
int literal_index = bytecode_iterator().GetIndexOperand(1);
int bytecode_flags = bytecode_iterator().GetFlagOperand(2);
int literal_flags =
interpreter::CreateObjectLiteralFlags::FlagsBits::decode(bytecode_flags);
// TODO(mstarzinger): Thread through number of properties.
int number_of_properties = constant_properties->length() / 2;
Node* literal = NewNode(
javascript()->CreateLiteralObject(constant_properties, literal_flags,
literal_index, number_of_properties),
GetFunctionClosure());
environment()->BindRegister(bytecode_iterator().GetRegisterOperand(3),
literal, Environment::kAttachFrameState);
}
Node* BytecodeGraphBuilder::ProcessCallArguments(const Operator* call_op,
Node* callee,
interpreter::Register receiver,
size_t arity) {
Node** all = local_zone()->NewArray<Node*>(static_cast<int>(arity));
all[0] = callee;
all[1] = environment()->LookupRegister(receiver);
int receiver_index = receiver.index();
for (int i = 2; i < static_cast<int>(arity); ++i) {
all[i] = environment()->LookupRegister(
interpreter::Register(receiver_index + i - 1));
}
Node* value = MakeNode(call_op, static_cast<int>(arity), all, false);
return value;
}
void BytecodeGraphBuilder::BuildCall(TailCallMode tail_call_mode,
ConvertReceiverMode receiver_hint) {
PrepareEagerCheckpoint();
Node* callee =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
interpreter::Register receiver = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
// Slot index of 0 is used indicate no feedback slot is available. Assert
// the assumption that slot index 0 is never a valid feedback slot.
STATIC_ASSERT(TypeFeedbackVector::kReservedIndexCount > 0);
int const slot_id = bytecode_iterator().GetIndexOperand(3);
VectorSlotPair feedback = CreateVectorSlotPair(slot_id);
float const frequency = ComputeCallFrequency(slot_id);
const Operator* call = javascript()->CallFunction(
arg_count + 1, frequency, feedback, receiver_hint, tail_call_mode);
Node* value = ProcessCallArguments(call, callee, receiver, arg_count + 1);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitCall() {
BuildCall(TailCallMode::kDisallow, ConvertReceiverMode::kAny);
}
void BytecodeGraphBuilder::VisitCallProperty() {
BuildCall(TailCallMode::kDisallow, ConvertReceiverMode::kNotNullOrUndefined);
}
void BytecodeGraphBuilder::VisitTailCall() {
TailCallMode tail_call_mode =
bytecode_array_->GetIsolate()->is_tail_call_elimination_enabled()
? TailCallMode::kAllow
: TailCallMode::kDisallow;
BuildCall(tail_call_mode, ConvertReceiverMode::kAny);
}
void BytecodeGraphBuilder::VisitCallJSRuntime() {
PrepareEagerCheckpoint();
Node* callee =
BuildLoadNativeContextField(bytecode_iterator().GetIndexOperand(0));
interpreter::Register receiver = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
// Create node to perform the JS runtime call.
const Operator* call = javascript()->CallFunction(arg_count + 1);
Node* value = ProcessCallArguments(call, callee, receiver, arg_count + 1);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
Node* BytecodeGraphBuilder::ProcessCallRuntimeArguments(
const Operator* call_runtime_op, interpreter::Register first_arg,
size_t arity) {
Node** all = local_zone()->NewArray<Node*>(arity);
int first_arg_index = first_arg.index();
for (int i = 0; i < static_cast<int>(arity); ++i) {
all[i] = environment()->LookupRegister(
interpreter::Register(first_arg_index + i));
}
Node* value = MakeNode(call_runtime_op, static_cast<int>(arity), all, false);
return value;
}
void BytecodeGraphBuilder::VisitCallRuntime() {
PrepareEagerCheckpoint();
Runtime::FunctionId functionId = bytecode_iterator().GetRuntimeIdOperand(0);
interpreter::Register first_arg = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
// Create node to perform the runtime call.
const Operator* call = javascript()->CallRuntime(functionId, arg_count);
Node* value = ProcessCallRuntimeArguments(call, first_arg, arg_count);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitCallRuntimeForPair() {
PrepareEagerCheckpoint();
Runtime::FunctionId functionId = bytecode_iterator().GetRuntimeIdOperand(0);
interpreter::Register first_arg = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
interpreter::Register first_return =
bytecode_iterator().GetRegisterOperand(3);
// Create node to perform the runtime call.
const Operator* call = javascript()->CallRuntime(functionId, arg_count);
Node* return_pair = ProcessCallRuntimeArguments(call, first_arg, arg_count);
environment()->BindRegistersToProjections(first_return, return_pair,
Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitInvokeIntrinsic() {
PrepareEagerCheckpoint();
Runtime::FunctionId functionId = bytecode_iterator().GetIntrinsicIdOperand(0);
interpreter::Register first_arg = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
// Create node to perform the runtime call. Turbofan will take care of the
// lowering.
const Operator* call = javascript()->CallRuntime(functionId, arg_count);
Node* value = ProcessCallRuntimeArguments(call, first_arg, arg_count);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
Node* BytecodeGraphBuilder::ProcessCallNewArguments(
const Operator* call_new_op, Node* callee, Node* new_target,
interpreter::Register first_arg, size_t arity) {
Node** all = local_zone()->NewArray<Node*>(arity);
all[0] = callee;
int first_arg_index = first_arg.index();
for (int i = 1; i < static_cast<int>(arity) - 1; ++i) {
all[i] = environment()->LookupRegister(
interpreter::Register(first_arg_index + i - 1));
}
all[arity - 1] = new_target;
Node* value = MakeNode(call_new_op, static_cast<int>(arity), all, false);
return value;
}
void BytecodeGraphBuilder::VisitNew() {
PrepareEagerCheckpoint();
interpreter::Register callee_reg = bytecode_iterator().GetRegisterOperand(0);
interpreter::Register first_arg = bytecode_iterator().GetRegisterOperand(1);
size_t arg_count = bytecode_iterator().GetRegisterCountOperand(2);
// Slot index of 0 is used indicate no feedback slot is available. Assert
// the assumption that slot index 0 is never a valid feedback slot.
STATIC_ASSERT(TypeFeedbackVector::kReservedIndexCount > 0);
int const slot_id = bytecode_iterator().GetIndexOperand(3);
VectorSlotPair feedback = CreateVectorSlotPair(slot_id);
Node* new_target = environment()->LookupAccumulator();
Node* callee = environment()->LookupRegister(callee_reg);
float const frequency = ComputeCallFrequency(slot_id);
const Operator* call = javascript()->CallConstruct(
static_cast<int>(arg_count) + 2, frequency, feedback);
Node* value = ProcessCallNewArguments(call, callee, new_target, first_arg,
arg_count + 2);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::BuildThrow() {
PrepareEagerCheckpoint();
Node* value = environment()->LookupAccumulator();
Node* call = NewNode(javascript()->CallRuntime(Runtime::kThrow), value);
environment()->BindAccumulator(call, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitThrow() {
BuildLoopExitsForFunctionExit();
BuildThrow();
Node* call = environment()->LookupAccumulator();
Node* control = NewNode(common()->Throw(), call);
MergeControlToLeaveFunction(control);
}
void BytecodeGraphBuilder::VisitReThrow() {
BuildLoopExitsForFunctionExit();
Node* value = environment()->LookupAccumulator();
Node* call = NewNode(javascript()->CallRuntime(Runtime::kReThrow), value);
Node* control = NewNode(common()->Throw(), call);
MergeControlToLeaveFunction(control);
}
void BytecodeGraphBuilder::BuildBinaryOp(const Operator* js_op) {
PrepareEagerCheckpoint();
Node* left =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* right = environment()->LookupAccumulator();
Node* node = NewNode(js_op, left, right);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
// Helper function to create binary operation hint from the recorded type
// feedback.
BinaryOperationHint BytecodeGraphBuilder::GetBinaryOperationHint(
int operand_index) {
FeedbackVectorSlot slot = feedback_vector()->ToSlot(
bytecode_iterator().GetIndexOperand(operand_index));
DCHECK_EQ(FeedbackVectorSlotKind::INTERPRETER_BINARYOP_IC,
feedback_vector()->GetKind(slot));
BinaryOpICNexus nexus(feedback_vector(), slot);
return nexus.GetBinaryOperationFeedback();
}
// Helper function to create compare operation hint from the recorded type
// feedback.
CompareOperationHint BytecodeGraphBuilder::GetCompareOperationHint() {
int slot_index = bytecode_iterator().GetIndexOperand(1);
if (slot_index == 0) {
return CompareOperationHint::kAny;
}
FeedbackVectorSlot slot =
feedback_vector()->ToSlot(bytecode_iterator().GetIndexOperand(1));
DCHECK_EQ(FeedbackVectorSlotKind::INTERPRETER_COMPARE_IC,
feedback_vector()->GetKind(slot));
CompareICNexus nexus(feedback_vector(), slot);
return nexus.GetCompareOperationFeedback();
}
float BytecodeGraphBuilder::ComputeCallFrequency(int slot_id) const {
CallICNexus nexus(feedback_vector(), feedback_vector()->ToSlot(slot_id));
return nexus.ComputeCallFrequency() * invocation_frequency_;
}
void BytecodeGraphBuilder::VisitAdd() {
BuildBinaryOp(
javascript()->Add(GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitSub() {
BuildBinaryOp(javascript()->Subtract(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitMul() {
BuildBinaryOp(javascript()->Multiply(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitDiv() {
BuildBinaryOp(
javascript()->Divide(GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitMod() {
BuildBinaryOp(
javascript()->Modulus(GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitBitwiseOr() {
BuildBinaryOp(javascript()->BitwiseOr(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitBitwiseXor() {
BuildBinaryOp(javascript()->BitwiseXor(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitBitwiseAnd() {
BuildBinaryOp(javascript()->BitwiseAnd(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitShiftLeft() {
BuildBinaryOp(javascript()->ShiftLeft(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitShiftRight() {
BuildBinaryOp(javascript()->ShiftRight(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::VisitShiftRightLogical() {
BuildBinaryOp(javascript()->ShiftRightLogical(
GetBinaryOperationHint(kBinaryOperationHintIndex)));
}
void BytecodeGraphBuilder::BuildBinaryOpWithImmediate(const Operator* js_op) {
PrepareEagerCheckpoint();
Node* left =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(1));
Node* right = jsgraph()->Constant(bytecode_iterator().GetImmediateOperand(0));
Node* node = NewNode(js_op, left, right);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitAddSmi() {
BuildBinaryOpWithImmediate(
javascript()->Add(GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitSubSmi() {
BuildBinaryOpWithImmediate(javascript()->Subtract(
GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitBitwiseOrSmi() {
BuildBinaryOpWithImmediate(javascript()->BitwiseOr(
GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitBitwiseAndSmi() {
BuildBinaryOpWithImmediate(javascript()->BitwiseAnd(
GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitShiftLeftSmi() {
BuildBinaryOpWithImmediate(javascript()->ShiftLeft(
GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitShiftRightSmi() {
BuildBinaryOpWithImmediate(javascript()->ShiftRight(
GetBinaryOperationHint(kBinaryOperationSmiHintIndex)));
}
void BytecodeGraphBuilder::VisitInc() {
PrepareEagerCheckpoint();
// Note: Use subtract -1 here instead of add 1 to ensure we always convert to
// a number, not a string.
const Operator* js_op =
javascript()->Subtract(GetBinaryOperationHint(kCountOperationHintIndex));
Node* node = NewNode(js_op, environment()->LookupAccumulator(),
jsgraph()->Constant(-1));
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitDec() {
PrepareEagerCheckpoint();
const Operator* js_op =
javascript()->Subtract(GetBinaryOperationHint(kCountOperationHintIndex));
Node* node = NewNode(js_op, environment()->LookupAccumulator(),
jsgraph()->OneConstant());
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitLogicalNot() {
Node* value = environment()->LookupAccumulator();
Node* node = NewNode(common()->Select(MachineRepresentation::kTagged), value,
jsgraph()->FalseConstant(), jsgraph()->TrueConstant());
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitToBooleanLogicalNot() {
Node* value = NewNode(javascript()->ToBoolean(ToBooleanHint::kAny),
environment()->LookupAccumulator());
Node* node = NewNode(common()->Select(MachineRepresentation::kTagged), value,
jsgraph()->FalseConstant(), jsgraph()->TrueConstant());
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::VisitTypeOf() {
Node* node =
NewNode(javascript()->TypeOf(), environment()->LookupAccumulator());
environment()->BindAccumulator(node);
}
void BytecodeGraphBuilder::BuildDelete(LanguageMode language_mode) {
PrepareEagerCheckpoint();
Node* key = environment()->LookupAccumulator();
Node* object =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* node =
NewNode(javascript()->DeleteProperty(language_mode), object, key);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitDeletePropertyStrict() {
BuildDelete(LanguageMode::STRICT);
}
void BytecodeGraphBuilder::VisitDeletePropertySloppy() {
BuildDelete(LanguageMode::SLOPPY);
}
void BytecodeGraphBuilder::BuildCompareOp(const Operator* js_op) {
PrepareEagerCheckpoint();
Node* left =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* right = environment()->LookupAccumulator();
Node* node = NewNode(js_op, left, right);
environment()->BindAccumulator(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitTestEqual() {
BuildCompareOp(javascript()->Equal(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestNotEqual() {
BuildCompareOp(javascript()->NotEqual(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestEqualStrict() {
BuildCompareOp(javascript()->StrictEqual(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestLessThan() {
BuildCompareOp(javascript()->LessThan(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestGreaterThan() {
BuildCompareOp(javascript()->GreaterThan(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestLessThanOrEqual() {
BuildCompareOp(javascript()->LessThanOrEqual(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestGreaterThanOrEqual() {
BuildCompareOp(javascript()->GreaterThanOrEqual(GetCompareOperationHint()));
}
void BytecodeGraphBuilder::VisitTestIn() {
BuildCompareOp(javascript()->HasProperty());
}
void BytecodeGraphBuilder::VisitTestInstanceOf() {
BuildCompareOp(javascript()->InstanceOf());
}
void BytecodeGraphBuilder::BuildCastOperator(const Operator* js_op) {
PrepareEagerCheckpoint();
Node* value = NewNode(js_op, environment()->LookupAccumulator());
environment()->BindRegister(bytecode_iterator().GetRegisterOperand(0), value,
Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitToName() {
BuildCastOperator(javascript()->ToName());
}
void BytecodeGraphBuilder::VisitToObject() {
BuildCastOperator(javascript()->ToObject());
}
void BytecodeGraphBuilder::VisitToNumber() {
BuildCastOperator(javascript()->ToNumber());
}
void BytecodeGraphBuilder::VisitJump() { BuildJump(); }
void BytecodeGraphBuilder::VisitJumpConstant() { BuildJump(); }
void BytecodeGraphBuilder::VisitJumpIfTrue() { BuildJumpIfTrue(); }
void BytecodeGraphBuilder::VisitJumpIfTrueConstant() { BuildJumpIfTrue(); }
void BytecodeGraphBuilder::VisitJumpIfFalse() { BuildJumpIfFalse(); }
void BytecodeGraphBuilder::VisitJumpIfFalseConstant() { BuildJumpIfFalse(); }
void BytecodeGraphBuilder::VisitJumpIfToBooleanTrue() {
BuildJumpIfToBooleanTrue();
}
void BytecodeGraphBuilder::VisitJumpIfToBooleanTrueConstant() {
BuildJumpIfToBooleanTrue();
}
void BytecodeGraphBuilder::VisitJumpIfToBooleanFalse() {
BuildJumpIfToBooleanFalse();
}
void BytecodeGraphBuilder::VisitJumpIfToBooleanFalseConstant() {
BuildJumpIfToBooleanFalse();
}
void BytecodeGraphBuilder::VisitJumpIfNotHole() { BuildJumpIfNotHole(); }
void BytecodeGraphBuilder::VisitJumpIfNotHoleConstant() {
BuildJumpIfNotHole();
}
void BytecodeGraphBuilder::VisitJumpIfNull() {
BuildJumpIfEqual(jsgraph()->NullConstant());
}
void BytecodeGraphBuilder::VisitJumpIfNullConstant() {
BuildJumpIfEqual(jsgraph()->NullConstant());
}
void BytecodeGraphBuilder::VisitJumpIfUndefined() {
BuildJumpIfEqual(jsgraph()->UndefinedConstant());
}
void BytecodeGraphBuilder::VisitJumpIfUndefinedConstant() {
BuildJumpIfEqual(jsgraph()->UndefinedConstant());
}
void BytecodeGraphBuilder::VisitJumpLoop() { BuildJump(); }
void BytecodeGraphBuilder::VisitStackCheck() {
PrepareEagerCheckpoint();
Node* node = NewNode(javascript()->StackCheck());
environment()->RecordAfterState(node, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitReturn() {
BuildLoopExitsForFunctionExit();
Node* pop_node = jsgraph()->ZeroConstant();
Node* control =
NewNode(common()->Return(), pop_node, environment()->LookupAccumulator());
MergeControlToLeaveFunction(control);
}
void BytecodeGraphBuilder::VisitDebugger() {
PrepareEagerCheckpoint();
Node* call =
NewNode(javascript()->CallRuntime(Runtime::kHandleDebuggerStatement));
environment()->BindAccumulator(call, Environment::kAttachFrameState);
environment()->MarkAllRegistersLive();
}
// We cannot create a graph from the debugger copy of the bytecode array.
#define DEBUG_BREAK(Name, ...) \
void BytecodeGraphBuilder::Visit##Name() { UNREACHABLE(); }
DEBUG_BREAK_BYTECODE_LIST(DEBUG_BREAK);
#undef DEBUG_BREAK
void BytecodeGraphBuilder::BuildForInPrepare() {
PrepareEagerCheckpoint();
Node* receiver =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* prepare = NewNode(javascript()->ForInPrepare(), receiver);
environment()->BindRegistersToProjections(
bytecode_iterator().GetRegisterOperand(1), prepare,
Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitForInPrepare() { BuildForInPrepare(); }
void BytecodeGraphBuilder::VisitForInContinue() {
PrepareEagerCheckpoint();
Node* index =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* cache_length =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(1));
Node* exit_cond =
NewNode(javascript()->LessThan(CompareOperationHint::kSignedSmall), index,
cache_length);
environment()->BindAccumulator(exit_cond, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::BuildForInNext() {
PrepareEagerCheckpoint();
Node* receiver =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
Node* index =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(1));
int catch_reg_pair_index = bytecode_iterator().GetRegisterOperand(2).index();
Node* cache_type = environment()->LookupRegister(
interpreter::Register(catch_reg_pair_index));
Node* cache_array = environment()->LookupRegister(
interpreter::Register(catch_reg_pair_index + 1));
Node* value = NewNode(javascript()->ForInNext(), receiver, cache_array,
cache_type, index);
environment()->BindAccumulator(value, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitForInNext() { BuildForInNext(); }
void BytecodeGraphBuilder::VisitForInStep() {
PrepareEagerCheckpoint();
Node* index =
environment()->LookupRegister(bytecode_iterator().GetRegisterOperand(0));
index = NewNode(javascript()->Add(BinaryOperationHint::kSignedSmall), index,
jsgraph()->OneConstant());
environment()->BindAccumulator(index, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitSuspendGenerator() {
Node* state = environment()->LookupAccumulator();
Node* generator = environment()->LookupRegister(
bytecode_iterator().GetRegisterOperand(0));
// The offsets used by the bytecode iterator are relative to a different base
// than what is used in the interpreter, hence the addition.
Node* offset =
jsgraph()->Constant(bytecode_iterator().current_offset() +
(BytecodeArray::kHeaderSize - kHeapObjectTag));
int register_count = environment()->register_count();
int value_input_count = 3 + register_count;
Node** value_inputs = local_zone()->NewArray<Node*>(value_input_count);
value_inputs[0] = generator;
value_inputs[1] = state;
value_inputs[2] = offset;
for (int i = 0; i < register_count; ++i) {
value_inputs[3 + i] =
environment()->LookupRegister(interpreter::Register(i));
}
MakeNode(javascript()->GeneratorStore(register_count), value_input_count,
value_inputs, false);
}
void BytecodeGraphBuilder::VisitResumeGenerator() {
PrepareEagerCheckpoint();
Node* generator = environment()->LookupRegister(
bytecode_iterator().GetRegisterOperand(0));
// Bijection between registers and array indices must match that used in
// InterpreterAssembler::ExportRegisterFile.
for (int i = 0; i < environment()->register_count(); ++i) {
Node* value = NewNode(javascript()->GeneratorRestoreRegister(i), generator);
environment()->BindRegister(interpreter::Register(i), value);
}
Node* state =
NewNode(javascript()->GeneratorRestoreContinuation(), generator);
environment()->BindAccumulator(state, Environment::kAttachFrameState);
}
void BytecodeGraphBuilder::VisitWide() {
// Consumed by the BytecodeArrayIterator.
UNREACHABLE();
}
void BytecodeGraphBuilder::VisitExtraWide() {
// Consumed by the BytecodeArrayIterator.
UNREACHABLE();
}
void BytecodeGraphBuilder::VisitIllegal() {
// Not emitted in valid bytecode.
UNREACHABLE();
}
void BytecodeGraphBuilder::VisitNop() {}
void BytecodeGraphBuilder::SwitchToMergeEnvironment(int current_offset) {
if (merge_environments_[current_offset] != nullptr) {
if (environment() != nullptr) {
merge_environments_[current_offset]->Merge(environment());
}
set_environment(merge_environments_[current_offset]);
}
}
void BytecodeGraphBuilder::BuildLoopHeaderEnvironment(int current_offset) {
if (branch_analysis()->backward_branches_target(current_offset)) {
// Add loop header and store a copy so we can connect merged back
// edge inputs to the loop header.
merge_environments_[current_offset] = environment()->CopyForLoop();
}
}
void BytecodeGraphBuilder::MergeIntoSuccessorEnvironment(int target_offset) {
BuildLoopExitsForBranch(target_offset);
if (merge_environments_[target_offset] == nullptr) {
// Append merge nodes to the environment. We may merge here with another
// environment. So add a place holder for merge nodes. We may add redundant
// but will be eliminated in a later pass.
// TODO(mstarzinger): Be smarter about this!
NewMerge();
merge_environments_[target_offset] = environment();
} else {
merge_environments_[target_offset]->Merge(environment());
}
set_environment(nullptr);
}
void BytecodeGraphBuilder::MergeControlToLeaveFunction(Node* exit) {
exit_controls_.push_back(exit);
set_environment(nullptr);
}
void BytecodeGraphBuilder::BuildOSRLoopEntryPoint(int current_offset) {
if (!osr_ast_id_.IsNone() && osr_ast_id_.ToInt() == current_offset) {
// For OSR add a special {OsrLoopEntry} node into the current loop header.
// It will be turned into a usable entry by the OSR deconstruction.
Environment* loop_env = merge_environments_[current_offset];
Environment* osr_env = loop_env->CopyForOsrEntry();
osr_env->PrepareForOsrEntry();
loop_env->Merge(osr_env);
}
}
void BytecodeGraphBuilder::BuildOSRNormalEntryPoint() {
if (!osr_ast_id_.IsNone()) {
// For OSR add an {OsrNormalEntry} as the the top-level environment start.
// It will be replaced with {Dead} by the OSR deconstruction.
NewNode(common()->OsrNormalEntry());
// Note that the requested OSR entry point must be the target of a backward
// branch, otherwise there will not be a proper loop header available.
DCHECK(branch_analysis()->backward_branches_target(osr_ast_id_.ToInt()));
}
}
void BytecodeGraphBuilder::BuildLoopExitsForBranch(int target_offset) {
int origin_offset = bytecode_iterator().current_offset();
// Only build loop exits for forward edges.
if (target_offset > origin_offset) {
BuildLoopExitsUntilLoop(loop_analysis()->GetLoopOffsetFor(target_offset));
}
}
void BytecodeGraphBuilder::BuildLoopExitsUntilLoop(int loop_offset) {
int origin_offset = bytecode_iterator().current_offset();
int current_loop = loop_analysis()->GetLoopOffsetFor(origin_offset);
while (loop_offset < current_loop) {
Node* loop_node = merge_environments_[current_loop]->GetControlDependency();
environment()->PrepareForLoopExit(loop_node);
current_loop = loop_analysis()->GetParentLoopFor(current_loop);
}
}
void BytecodeGraphBuilder::BuildLoopExitsForFunctionExit() {
BuildLoopExitsUntilLoop(-1);
}
void BytecodeGraphBuilder::BuildJump() {
MergeIntoSuccessorEnvironment(bytecode_iterator().GetJumpTargetOffset());
}
void BytecodeGraphBuilder::BuildJumpIf(Node* condition) {
NewBranch(condition);
Environment* if_false_environment = environment()->CopyForConditional();
NewIfTrue();
MergeIntoSuccessorEnvironment(bytecode_iterator().GetJumpTargetOffset());
set_environment(if_false_environment);
NewIfFalse();
}
void BytecodeGraphBuilder::BuildJumpIfNot(Node* condition) {
NewBranch(condition);
Environment* if_true_environment = environment()->CopyForConditional();
NewIfFalse();
MergeIntoSuccessorEnvironment(bytecode_iterator().GetJumpTargetOffset());
set_environment(if_true_environment);
NewIfTrue();
}
void BytecodeGraphBuilder::BuildJumpIfEqual(Node* comperand) {
Node* accumulator = environment()->LookupAccumulator();
Node* condition =
NewNode(javascript()->StrictEqual(CompareOperationHint::kAny),
accumulator, comperand);
BuildJumpIf(condition);
}
void BytecodeGraphBuilder::BuildJumpIfFalse() {
BuildJumpIfNot(environment()->LookupAccumulator());
}
void BytecodeGraphBuilder::BuildJumpIfTrue() {
BuildJumpIf(environment()->LookupAccumulator());
}
void BytecodeGraphBuilder::BuildJumpIfToBooleanTrue() {
Node* accumulator = environment()->LookupAccumulator();
Node* condition =
NewNode(javascript()->ToBoolean(ToBooleanHint::kAny), accumulator);
BuildJumpIf(condition);
}
void BytecodeGraphBuilder::BuildJumpIfToBooleanFalse() {
Node* accumulator = environment()->LookupAccumulator();
Node* condition =
NewNode(javascript()->ToBoolean(ToBooleanHint::kAny), accumulator);
BuildJumpIfNot(condition);
}
void BytecodeGraphBuilder::BuildJumpIfNotHole() {
Node* accumulator = environment()->LookupAccumulator();
Node* condition =
NewNode(javascript()->StrictEqual(CompareOperationHint::kAny),
accumulator, jsgraph()->TheHoleConstant());
BuildJumpIfNot(condition);
}
Node** BytecodeGraphBuilder::EnsureInputBufferSize(int size) {
if (size > input_buffer_size_) {
size = size + kInputBufferSizeIncrement + input_buffer_size_;
input_buffer_ = local_zone()->NewArray<Node*>(size);
input_buffer_size_ = size;
}
return input_buffer_;
}
void BytecodeGraphBuilder::EnterAndExitExceptionHandlers(int current_offset) {
Handle<HandlerTable> table = exception_handler_table();
int num_entries = table->NumberOfRangeEntries();
// Potentially exit exception handlers.
while (!exception_handlers_.empty()) {
int current_end = exception_handlers_.top().end_offset_;
if (current_offset < current_end) break; // Still covered by range.
exception_handlers_.pop();
}
// Potentially enter exception handlers.
while (current_exception_handler_ < num_entries) {
int next_start = table->GetRangeStart(current_exception_handler_);
if (current_offset < next_start) break; // Not yet covered by range.
int next_end = table->GetRangeEnd(current_exception_handler_);
int next_handler = table->GetRangeHandler(current_exception_handler_);
int context_register = table->GetRangeData(current_exception_handler_);
exception_handlers_.push(
{next_start, next_end, next_handler, context_register});
current_exception_handler_++;
}
}
Node* BytecodeGraphBuilder::MakeNode(const Operator* op, int value_input_count,
Node** value_inputs, bool incomplete) {
DCHECK_EQ(op->ValueInputCount(), value_input_count);
bool has_context = OperatorProperties::HasContextInput(op);
bool has_frame_state = OperatorProperties::HasFrameStateInput(op);
bool has_control = op->ControlInputCount() == 1;
bool has_effect = op->EffectInputCount() == 1;
DCHECK_LT(op->ControlInputCount(), 2);
DCHECK_LT(op->EffectInputCount(), 2);
Node* result = nullptr;
if (!has_context && !has_frame_state && !has_control && !has_effect) {
result = graph()->NewNode(op, value_input_count, value_inputs, incomplete);
} else {
bool inside_handler = !exception_handlers_.empty();
int input_count_with_deps = value_input_count;
if (has_context) ++input_count_with_deps;
if (has_frame_state) ++input_count_with_deps;
if (has_control) ++input_count_with_deps;
if (has_effect) ++input_count_with_deps;
Node** buffer = EnsureInputBufferSize(input_count_with_deps);
memcpy(buffer, value_inputs, kPointerSize * value_input_count);
Node** current_input = buffer + value_input_count;
if (has_context) {
*current_input++ = environment()->Context();
}
if (has_frame_state) {
// The frame state will be inserted later. Here we misuse the {Dead} node
// as a sentinel to be later overwritten with the real frame state by the
// calls to {PrepareFrameState} within individual visitor methods.
*current_input++ = jsgraph()->Dead();
}
if (has_effect) {
*current_input++ = environment()->GetEffectDependency();
}
if (has_control) {
*current_input++ = environment()->GetControlDependency();
}
result = graph()->NewNode(op, input_count_with_deps, buffer, incomplete);
// Update the current control dependency for control-producing nodes.
if (NodeProperties::IsControl(result)) {
environment()->UpdateControlDependency(result);
}
// Update the current effect dependency for effect-producing nodes.
if (result->op()->EffectOutputCount() > 0) {
environment()->UpdateEffectDependency(result);
}
// Add implicit exception continuation for throwing nodes.
if (!result->op()->HasProperty(Operator::kNoThrow) && inside_handler) {
int handler_offset = exception_handlers_.top().handler_offset_;
int context_index = exception_handlers_.top().context_register_;
interpreter::Register context_register(context_index);
Environment* success_env = environment()->CopyForConditional();
const Operator* op = common()->IfException();
Node* effect = environment()->GetEffectDependency();
Node* on_exception = graph()->NewNode(op, effect, result);
Node* context = environment()->LookupRegister(context_register);
environment()->UpdateControlDependency(on_exception);
environment()->UpdateEffectDependency(on_exception);
environment()->BindAccumulator(on_exception);
environment()->SetContext(context);
MergeIntoSuccessorEnvironment(handler_offset);
set_environment(success_env);
}
// Add implicit success continuation for throwing nodes.
if (!result->op()->HasProperty(Operator::kNoThrow)) {
const Operator* if_success = common()->IfSuccess();
Node* on_success = graph()->NewNode(if_success, result);
environment()->UpdateControlDependency(on_success);
}
}
return result;
}
Node* BytecodeGraphBuilder::NewPhi(int count, Node* input, Node* control) {
const Operator* phi_op = common()->Phi(MachineRepresentation::kTagged, count);
Node** buffer = EnsureInputBufferSize(count + 1);
MemsetPointer(buffer, input, count);
buffer[count] = control;
return graph()->NewNode(phi_op, count + 1, buffer, true);
}
Node* BytecodeGraphBuilder::NewEffectPhi(int count, Node* input,
Node* control) {
const Operator* phi_op = common()->EffectPhi(count);
Node** buffer = EnsureInputBufferSize(count + 1);
MemsetPointer(buffer, input, count);
buffer[count] = control;
return graph()->NewNode(phi_op, count + 1, buffer, true);
}
Node* BytecodeGraphBuilder::MergeControl(Node* control, Node* other) {
int inputs = control->op()->ControlInputCount() + 1;
if (control->opcode() == IrOpcode::kLoop) {
// Control node for loop exists, add input.
const Operator* op = common()->Loop(inputs);
control->AppendInput(graph_zone(), other);
NodeProperties::ChangeOp(control, op);
} else if (control->opcode() == IrOpcode::kMerge) {
// Control node for merge exists, add input.
const Operator* op = common()->Merge(inputs);
control->AppendInput(graph_zone(), other);
NodeProperties::ChangeOp(control, op);
} else {
// Control node is a singleton, introduce a merge.
const Operator* op = common()->Merge(inputs);
Node* merge_inputs[] = {control, other};
control = graph()->NewNode(op, arraysize(merge_inputs), merge_inputs, true);
}
return control;
}
Node* BytecodeGraphBuilder::MergeEffect(Node* value, Node* other,
Node* control) {
int inputs = control->op()->ControlInputCount();
if (value->opcode() == IrOpcode::kEffectPhi &&
NodeProperties::GetControlInput(value) == control) {
// Phi already exists, add input.
value->InsertInput(graph_zone(), inputs - 1, other);
NodeProperties::ChangeOp(value, common()->EffectPhi(inputs));
} else if (value != other) {
// Phi does not exist yet, introduce one.
value = NewEffectPhi(inputs, value, control);
value->ReplaceInput(inputs - 1, other);
}
return value;
}
Node* BytecodeGraphBuilder::MergeValue(Node* value, Node* other,
Node* control) {
int inputs = control->op()->ControlInputCount();
if (value->opcode() == IrOpcode::kPhi &&
NodeProperties::GetControlInput(value) == control) {
// Phi already exists, add input.
value->InsertInput(graph_zone(), inputs - 1, other);
NodeProperties::ChangeOp(
value, common()->Phi(MachineRepresentation::kTagged, inputs));
} else if (value != other) {
// Phi does not exist yet, introduce one.
value = NewPhi(inputs, value, control);
value->ReplaceInput(inputs - 1, other);
}
return value;
}
void BytecodeGraphBuilder::UpdateCurrentSourcePosition(
SourcePositionTableIterator* it, int offset) {
if (it->done()) return;
if (it->code_offset() == offset) {
source_positions_->SetCurrentPosition(SourcePosition(
it->source_position().ScriptOffset(), start_position_.InliningId()));
it->Advance();
} else {
DCHECK_GT(it->code_offset(), offset);
}
}
} // namespace compiler
} // namespace internal
} // namespace v8