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cobalt / cobalt / 0e7d696c3ce6a2ef566d0fabc20213b6a651f942 / . / src / third_party / v8 / src / interpreter / bytecode-generator.cc
blob: 0e1c45c1c3c505e35cec45416a7a22ac487781e2 [file] [log] [blame]
// 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/interpreter/bytecode-generator.h"
#include "src/api/api-inl.h"
#include "src/ast/ast-source-ranges.h"
#include "src/ast/scopes.h"
#include "src/builtins/builtins-constructor.h"
#include "src/codegen/compiler.h"
#include "src/codegen/unoptimized-compilation-info.h"
#include "src/interpreter/bytecode-flags.h"
#include "src/interpreter/bytecode-jump-table.h"
#include "src/interpreter/bytecode-label.h"
#include "src/interpreter/bytecode-register-allocator.h"
#include "src/interpreter/bytecode-register.h"
#include "src/interpreter/control-flow-builders.h"
#include "src/logging/local-logger.h"
#include "src/logging/log.h"
#include "src/objects/debug-objects.h"
#include "src/objects/literal-objects-inl.h"
#include "src/objects/objects-inl.h"
#include "src/objects/smi.h"
#include "src/objects/template-objects-inl.h"
#include "src/parsing/parse-info.h"
#include "src/parsing/token.h"
#include "src/utils/ostreams.h"
namespace v8 {
namespace internal {
namespace interpreter {
// Scoped class tracking context objects created by the visitor. Represents
// mutations of the context chain within the function body, allowing pushing and
// popping of the current {context_register} during visitation.
class BytecodeGenerator::ContextScope {
public:
ContextScope(BytecodeGenerator* generator, Scope* scope)
: generator_(generator),
scope_(scope),
outer_(generator_->execution_context()),
register_(Register::current_context()),
depth_(0) {
DCHECK(scope->NeedsContext() || outer_ == nullptr);
if (outer_) {
depth_ = outer_->depth_ + 1;
// Push the outer context into a new context register.
Register outer_context_reg =
generator_->register_allocator()->NewRegister();
outer_->set_register(outer_context_reg);
generator_->builder()->PushContext(outer_context_reg);
}
generator_->set_execution_context(this);
}
~ContextScope() {
if (outer_) {
DCHECK_EQ(register_.index(), Register::current_context().index());
generator_->builder()->PopContext(outer_->reg());
outer_->set_register(register_);
}
generator_->set_execution_context(outer_);
}
// Returns the depth of the given |scope| for the current execution context.
int ContextChainDepth(Scope* scope) {
return scope_->ContextChainLength(scope);
}
// Returns the execution context at |depth| in the current context chain if it
// is a function local execution context, otherwise returns nullptr.
ContextScope* Previous(int depth) {
if (depth > depth_) {
return nullptr;
}
ContextScope* previous = this;
for (int i = depth; i > 0; --i) {
previous = previous->outer_;
}
return previous;
}
Register reg() const { return register_; }
private:
const BytecodeArrayBuilder* builder() const { return generator_->builder(); }
void set_register(Register reg) { register_ = reg; }
BytecodeGenerator* generator_;
Scope* scope_;
ContextScope* outer_;
Register register_;
int depth_;
};
// Scoped class for tracking control statements entered by the
// visitor. The pattern derives AstGraphBuilder::ControlScope.
class BytecodeGenerator::ControlScope {
public:
explicit ControlScope(BytecodeGenerator* generator)
: generator_(generator),
outer_(generator->execution_control()),
context_(generator->execution_context()) {
generator_->set_execution_control(this);
}
virtual ~ControlScope() { generator_->set_execution_control(outer()); }
ControlScope(const ControlScope&) = delete;
ControlScope& operator=(const ControlScope&) = delete;
void Break(Statement* stmt) {
PerformCommand(CMD_BREAK, stmt, kNoSourcePosition);
}
void Continue(Statement* stmt) {
PerformCommand(CMD_CONTINUE, stmt, kNoSourcePosition);
}
void ReturnAccumulator(int source_position = kNoSourcePosition) {
PerformCommand(CMD_RETURN, nullptr, source_position);
}
void AsyncReturnAccumulator(int source_position = kNoSourcePosition) {
PerformCommand(CMD_ASYNC_RETURN, nullptr, source_position);
}
class DeferredCommands;
protected:
enum Command {
CMD_BREAK,
CMD_CONTINUE,
CMD_RETURN,
CMD_ASYNC_RETURN,
CMD_RETHROW
};
static constexpr bool CommandUsesAccumulator(Command command) {
return command != CMD_BREAK && command != CMD_CONTINUE;
}
void PerformCommand(Command command, Statement* statement,
int source_position);
virtual bool Execute(Command command, Statement* statement,
int source_position) = 0;
// Helper to pop the context chain to a depth expected by this control scope.
// Note that it is the responsibility of each individual {Execute} method to
// trigger this when commands are handled and control-flow continues locally.
void PopContextToExpectedDepth();
BytecodeGenerator* generator() const { return generator_; }
ControlScope* outer() const { return outer_; }
ContextScope* context() const { return context_; }
private:
BytecodeGenerator* generator_;
ControlScope* outer_;
ContextScope* context_;
};
// Helper class for a try-finally control scope. It can record intercepted
// control-flow commands that cause entry into a finally-block, and re-apply
// them after again leaving that block. Special tokens are used to identify
// paths going through the finally-block to dispatch after leaving the block.
class BytecodeGenerator::ControlScope::DeferredCommands final {
public:
// Fixed value tokens for paths we know we need.
// Fallthrough is set to -1 to make it the fallthrough case of the jump table,
// where the remaining cases start at 0.
static const int kFallthroughToken = -1;
// TODO(leszeks): Rethrow being 0 makes it use up a valuable LdaZero, which
// means that other commands (such as break or return) have to use LdaSmi.
// This can very slightly bloat bytecode, so perhaps token values should all
// be shifted down by 1.
static const int kRethrowToken = 0;
DeferredCommands(BytecodeGenerator* generator, Register token_register,
Register result_register)
: generator_(generator),
deferred_(generator->zone()),
token_register_(token_register),
result_register_(result_register),
return_token_(-1),
async_return_token_(-1) {
// There's always a rethrow path.
// TODO(leszeks): We could decouple deferred_ index and token to allow us
// to still push this lazily.
STATIC_ASSERT(kRethrowToken == 0);
deferred_.push_back({CMD_RETHROW, nullptr, kRethrowToken});
}
// One recorded control-flow command.
struct Entry {
Command command; // The command type being applied on this path.
Statement* statement; // The target statement for the command or {nullptr}.
int token; // A token identifying this particular path.
};
// Records a control-flow command while entering the finally-block. This also
// generates a new dispatch token that identifies one particular path. This
// expects the result to be in the accumulator.
void RecordCommand(Command command, Statement* statement) {
int token = GetTokenForCommand(command, statement);
DCHECK_LT(token, deferred_.size());
DCHECK_EQ(deferred_[token].command, command);
DCHECK_EQ(deferred_[token].statement, statement);
DCHECK_EQ(deferred_[token].token, token);
if (CommandUsesAccumulator(command)) {
builder()->StoreAccumulatorInRegister(result_register_);
}
builder()->LoadLiteral(Smi::FromInt(token));
builder()->StoreAccumulatorInRegister(token_register_);
if (!CommandUsesAccumulator(command)) {
// If we're not saving the accumulator in the result register, shove a
// harmless value there instead so that it is still considered "killed" in
// the liveness analysis. Normally we would LdaUndefined first, but the
// Smi token value is just as good, and by reusing it we save a bytecode.
builder()->StoreAccumulatorInRegister(result_register_);
}
}
// Records the dispatch token to be used to identify the re-throw path when
// the finally-block has been entered through the exception handler. This
// expects the exception to be in the accumulator.
void RecordHandlerReThrowPath() {
// The accumulator contains the exception object.
RecordCommand(CMD_RETHROW, nullptr);
}
// Records the dispatch token to be used to identify the implicit fall-through
// path at the end of a try-block into the corresponding finally-block.
void RecordFallThroughPath() {
builder()->LoadLiteral(Smi::FromInt(kFallthroughToken));
builder()->StoreAccumulatorInRegister(token_register_);
// Since we're not saving the accumulator in the result register, shove a
// harmless value there instead so that it is still considered "killed" in
// the liveness analysis. Normally we would LdaUndefined first, but the Smi
// token value is just as good, and by reusing it we save a bytecode.
builder()->StoreAccumulatorInRegister(result_register_);
}
// Applies all recorded control-flow commands after the finally-block again.
// This generates a dynamic dispatch on the token from the entry point.
void ApplyDeferredCommands() {
if (deferred_.size() == 0) return;
BytecodeLabel fall_through;
if (deferred_.size() == 1) {
// For a single entry, just jump to the fallthrough if we don't match the
// entry token.
const Entry& entry = deferred_[0];
builder()
->LoadLiteral(Smi::FromInt(entry.token))
.CompareReference(token_register_)
.JumpIfFalse(ToBooleanMode::kAlreadyBoolean, &fall_through);
if (CommandUsesAccumulator(entry.command)) {
builder()->LoadAccumulatorWithRegister(result_register_);
}
execution_control()->PerformCommand(entry.command, entry.statement,
kNoSourcePosition);
} else {
// For multiple entries, build a jump table and switch on the token,
// jumping to the fallthrough if none of them match.
BytecodeJumpTable* jump_table =
builder()->AllocateJumpTable(static_cast<int>(deferred_.size()), 0);
builder()
->LoadAccumulatorWithRegister(token_register_)
.SwitchOnSmiNoFeedback(jump_table)
.Jump(&fall_through);
for (const Entry& entry : deferred_) {
builder()->Bind(jump_table, entry.token);
if (CommandUsesAccumulator(entry.command)) {
builder()->LoadAccumulatorWithRegister(result_register_);
}
execution_control()->PerformCommand(entry.command, entry.statement,
kNoSourcePosition);
}
}
builder()->Bind(&fall_through);
}
BytecodeArrayBuilder* builder() { return generator_->builder(); }
ControlScope* execution_control() { return generator_->execution_control(); }
private:
int GetTokenForCommand(Command command, Statement* statement) {
switch (command) {
case CMD_RETURN:
return GetReturnToken();
case CMD_ASYNC_RETURN:
return GetAsyncReturnToken();
case CMD_RETHROW:
return kRethrowToken;
default:
// TODO(leszeks): We could also search for entries with the same
// command and statement.
return GetNewTokenForCommand(command, statement);
}
}
int GetReturnToken() {
if (return_token_ == -1) {
return_token_ = GetNewTokenForCommand(CMD_RETURN, nullptr);
}
return return_token_;
}
int GetAsyncReturnToken() {
if (async_return_token_ == -1) {
async_return_token_ = GetNewTokenForCommand(CMD_ASYNC_RETURN, nullptr);
}
return async_return_token_;
}
int GetNewTokenForCommand(Command command, Statement* statement) {
int token = static_cast<int>(deferred_.size());
deferred_.push_back({command, statement, token});
return token;
}
BytecodeGenerator* generator_;
ZoneVector<Entry> deferred_;
Register token_register_;
Register result_register_;
// Tokens for commands that don't need a statement.
int return_token_;
int async_return_token_;
};
// Scoped class for dealing with control flow reaching the function level.
class BytecodeGenerator::ControlScopeForTopLevel final
: public BytecodeGenerator::ControlScope {
public:
explicit ControlScopeForTopLevel(BytecodeGenerator* generator)
: ControlScope(generator) {}
protected:
bool Execute(Command command, Statement* statement,
int source_position) override {
switch (command) {
case CMD_BREAK: // We should never see break/continue in top-level.
case CMD_CONTINUE:
UNREACHABLE();
case CMD_RETURN:
// No need to pop contexts, execution leaves the method body.
generator()->BuildReturn(source_position);
return true;
case CMD_ASYNC_RETURN:
// No need to pop contexts, execution leaves the method body.
generator()->BuildAsyncReturn(source_position);
return true;
case CMD_RETHROW:
// No need to pop contexts, execution leaves the method body.
generator()->BuildReThrow();
return true;
}
return false;
}
};
// Scoped class for enabling break inside blocks and switch blocks.
class BytecodeGenerator::ControlScopeForBreakable final
: public BytecodeGenerator::ControlScope {
public:
ControlScopeForBreakable(BytecodeGenerator* generator,
BreakableStatement* statement,
BreakableControlFlowBuilder* control_builder)
: ControlScope(generator),
statement_(statement),
control_builder_(control_builder) {}
protected:
bool Execute(Command command, Statement* statement,
int source_position) override {
if (statement != statement_) return false;
switch (command) {
case CMD_BREAK:
PopContextToExpectedDepth();
control_builder_->Break();
return true;
case CMD_CONTINUE:
case CMD_RETURN:
case CMD_ASYNC_RETURN:
case CMD_RETHROW:
break;
}
return false;
}
private:
Statement* statement_;
BreakableControlFlowBuilder* control_builder_;
};
// Scoped class for enabling 'break' and 'continue' in iteration
// constructs, e.g. do...while, while..., for...
class BytecodeGenerator::ControlScopeForIteration final
: public BytecodeGenerator::ControlScope {
public:
ControlScopeForIteration(BytecodeGenerator* generator,
IterationStatement* statement,
LoopBuilder* loop_builder)
: ControlScope(generator),
statement_(statement),
loop_builder_(loop_builder) {}
protected:
bool Execute(Command command, Statement* statement,
int source_position) override {
if (statement != statement_) return false;
switch (command) {
case CMD_BREAK:
PopContextToExpectedDepth();
loop_builder_->Break();
return true;
case CMD_CONTINUE:
PopContextToExpectedDepth();
loop_builder_->Continue();
return true;
case CMD_RETURN:
case CMD_ASYNC_RETURN:
case CMD_RETHROW:
break;
}
return false;
}
private:
Statement* statement_;
LoopBuilder* loop_builder_;
};
// Scoped class for enabling 'throw' in try-catch constructs.
class BytecodeGenerator::ControlScopeForTryCatch final
: public BytecodeGenerator::ControlScope {
public:
ControlScopeForTryCatch(BytecodeGenerator* generator,
TryCatchBuilder* try_catch_builder)
: ControlScope(generator) {}
protected:
bool Execute(Command command, Statement* statement,
int source_position) override {
switch (command) {
case CMD_BREAK:
case CMD_CONTINUE:
case CMD_RETURN:
case CMD_ASYNC_RETURN:
break;
case CMD_RETHROW:
// No need to pop contexts, execution re-enters the method body via the
// stack unwinding mechanism which itself restores contexts correctly.
generator()->BuildReThrow();
return true;
}
return false;
}
};
// Scoped class for enabling control flow through try-finally constructs.
class BytecodeGenerator::ControlScopeForTryFinally final
: public BytecodeGenerator::ControlScope {
public:
ControlScopeForTryFinally(BytecodeGenerator* generator,
TryFinallyBuilder* try_finally_builder,
DeferredCommands* commands)
: ControlScope(generator),
try_finally_builder_(try_finally_builder),
commands_(commands) {}
protected:
bool Execute(Command command, Statement* statement,
int source_position) override {
switch (command) {
case CMD_BREAK:
case CMD_CONTINUE:
case CMD_RETURN:
case CMD_ASYNC_RETURN:
case CMD_RETHROW:
PopContextToExpectedDepth();
// We don't record source_position here since we don't generate return
// bytecode right here and will generate it later as part of finally
// block. Each return bytecode generated in finally block will get own
// return source position from corresponded return statement or we'll
// use end of function if no return statement is presented.
commands_->RecordCommand(command, statement);
try_finally_builder_->LeaveTry();
return true;
}
return false;
}
private:
TryFinallyBuilder* try_finally_builder_;
DeferredCommands* commands_;
};
// Allocate and fetch the coverage indices tracking NaryLogical Expressions.
class BytecodeGenerator::NaryCodeCoverageSlots {
public:
NaryCodeCoverageSlots(BytecodeGenerator* generator, NaryOperation* expr)
: generator_(generator) {
if (generator_->block_coverage_builder_ == nullptr) return;
for (size_t i = 0; i < expr->subsequent_length(); i++) {
coverage_slots_.push_back(
generator_->AllocateNaryBlockCoverageSlotIfEnabled(expr, i));
}
}
int GetSlotFor(size_t subsequent_expr_index) const {
if (generator_->block_coverage_builder_ == nullptr) {
return BlockCoverageBuilder::kNoCoverageArraySlot;
}
DCHECK(coverage_slots_.size() > subsequent_expr_index);
return coverage_slots_[subsequent_expr_index];
}
private:
BytecodeGenerator* generator_;
std::vector<int> coverage_slots_;
};
void BytecodeGenerator::ControlScope::PerformCommand(Command command,
Statement* statement,
int source_position) {
ControlScope* current = this;
do {
if (current->Execute(command, statement, source_position)) {
return;
}
current = current->outer();
} while (current != nullptr);
UNREACHABLE();
}
void BytecodeGenerator::ControlScope::PopContextToExpectedDepth() {
// Pop context to the expected depth. Note that this can in fact pop multiple
// contexts at once because the {PopContext} bytecode takes a saved register.
if (generator()->execution_context() != context()) {
generator()->builder()->PopContext(context()->reg());
}
}
class BytecodeGenerator::RegisterAllocationScope final {
public:
explicit RegisterAllocationScope(BytecodeGenerator* generator)
: generator_(generator),
outer_next_register_index_(
generator->register_allocator()->next_register_index()) {}
~RegisterAllocationScope() {
generator_->register_allocator()->ReleaseRegisters(
outer_next_register_index_);
}
RegisterAllocationScope(const RegisterAllocationScope&) = delete;
RegisterAllocationScope& operator=(const RegisterAllocationScope&) = delete;
BytecodeGenerator* generator() const { return generator_; }
private:
BytecodeGenerator* generator_;
int outer_next_register_index_;
};
class BytecodeGenerator::AccumulatorPreservingScope final {
public:
explicit AccumulatorPreservingScope(BytecodeGenerator* generator,
AccumulatorPreservingMode mode)
: generator_(generator) {
if (mode == AccumulatorPreservingMode::kPreserve) {
saved_accumulator_register_ =
generator_->register_allocator()->NewRegister();
generator_->builder()->StoreAccumulatorInRegister(
saved_accumulator_register_);
}
}
~AccumulatorPreservingScope() {
if (saved_accumulator_register_.is_valid()) {
generator_->builder()->LoadAccumulatorWithRegister(
saved_accumulator_register_);
}
}
AccumulatorPreservingScope(const AccumulatorPreservingScope&) = delete;
AccumulatorPreservingScope& operator=(const AccumulatorPreservingScope&) =
delete;
private:
BytecodeGenerator* generator_;
Register saved_accumulator_register_;
};
// Scoped base class for determining how the result of an expression will be
// used.
class BytecodeGenerator::ExpressionResultScope {
public:
ExpressionResultScope(BytecodeGenerator* generator, Expression::Context kind)
: outer_(generator->execution_result()),
allocator_(generator),
kind_(kind),
type_hint_(TypeHint::kAny) {
generator->set_execution_result(this);
}
~ExpressionResultScope() {
allocator_.generator()->set_execution_result(outer_);
}
ExpressionResultScope(const ExpressionResultScope&) = delete;
ExpressionResultScope& operator=(const ExpressionResultScope&) = delete;
bool IsEffect() const { return kind_ == Expression::kEffect; }
bool IsValue() const { return kind_ == Expression::kValue; }
bool IsTest() const { return kind_ == Expression::kTest; }
TestResultScope* AsTest() {
DCHECK(IsTest());
return reinterpret_cast<TestResultScope*>(this);
}
// Specify expression always returns a Boolean result value.
void SetResultIsBoolean() {
DCHECK_EQ(type_hint_, TypeHint::kAny);
type_hint_ = TypeHint::kBoolean;
}
void SetResultIsString() {
DCHECK_EQ(type_hint_, TypeHint::kAny);
type_hint_ = TypeHint::kString;
}
TypeHint type_hint() const { return type_hint_; }
private:
ExpressionResultScope* outer_;
RegisterAllocationScope allocator_;
Expression::Context kind_;
TypeHint type_hint_;
};
// Scoped class used when the result of the current expression is not
// expected to produce a result.
class BytecodeGenerator::EffectResultScope final
: public ExpressionResultScope {
public:
explicit EffectResultScope(BytecodeGenerator* generator)
: ExpressionResultScope(generator, Expression::kEffect) {}
};
// Scoped class used when the result of the current expression to be
// evaluated should go into the interpreter's accumulator.
class BytecodeGenerator::ValueResultScope final : public ExpressionResultScope {
public:
explicit ValueResultScope(BytecodeGenerator* generator)
: ExpressionResultScope(generator, Expression::kValue) {}
};
// Scoped class used when the result of the current expression to be
// evaluated is only tested with jumps to two branches.
class BytecodeGenerator::TestResultScope final : public ExpressionResultScope {
public:
TestResultScope(BytecodeGenerator* generator, BytecodeLabels* then_labels,
BytecodeLabels* else_labels, TestFallthrough fallthrough)
: ExpressionResultScope(generator, Expression::kTest),
result_consumed_by_test_(false),
fallthrough_(fallthrough),
then_labels_(then_labels),
else_labels_(else_labels) {}
TestResultScope(const TestResultScope&) = delete;
TestResultScope& operator=(const TestResultScope&) = delete;
// Used when code special cases for TestResultScope and consumes any
// possible value by testing and jumping to a then/else label.
void SetResultConsumedByTest() { result_consumed_by_test_ = true; }
bool result_consumed_by_test() { return result_consumed_by_test_; }
// Inverts the control flow of the operation, swapping the then and else
// labels and the fallthrough.
void InvertControlFlow() {
std::swap(then_labels_, else_labels_);
fallthrough_ = inverted_fallthrough();
}
BytecodeLabel* NewThenLabel() { return then_labels_->New(); }
BytecodeLabel* NewElseLabel() { return else_labels_->New(); }
BytecodeLabels* then_labels() const { return then_labels_; }
BytecodeLabels* else_labels() const { return else_labels_; }
void set_then_labels(BytecodeLabels* then_labels) {
then_labels_ = then_labels;
}
void set_else_labels(BytecodeLabels* else_labels) {
else_labels_ = else_labels;
}
TestFallthrough fallthrough() const { return fallthrough_; }
TestFallthrough inverted_fallthrough() const {
switch (fallthrough_) {
case TestFallthrough::kThen:
return TestFallthrough::kElse;
case TestFallthrough::kElse:
return TestFallthrough::kThen;
default:
return TestFallthrough::kNone;
}
}
void set_fallthrough(TestFallthrough fallthrough) {
fallthrough_ = fallthrough;
}
private:
bool result_consumed_by_test_;
TestFallthrough fallthrough_;
BytecodeLabels* then_labels_;
BytecodeLabels* else_labels_;
};
// Used to build a list of toplevel declaration data.
class BytecodeGenerator::TopLevelDeclarationsBuilder final : public ZoneObject {
public:
template <typename LocalIsolate>
Handle<FixedArray> AllocateDeclarations(UnoptimizedCompilationInfo* info,
BytecodeGenerator* generator,
Handle<Script> script,
LocalIsolate* isolate) {
DCHECK(has_constant_pool_entry_);
Handle<FixedArray> data =
isolate->factory()->NewFixedArray(entry_slots_, AllocationType::kOld);
int array_index = 0;
if (info->scope()->is_module_scope()) {
for (Declaration* decl : *info->scope()->declarations()) {
Variable* var = decl->var();
if (!var->is_used()) continue;
if (var->location() != VariableLocation::MODULE) continue;
#ifdef DEBUG
int start = array_index;
#endif
if (decl->IsFunctionDeclaration()) {
FunctionLiteral* f = static_cast<FunctionDeclaration*>(decl)->fun();
Handle<SharedFunctionInfo> sfi(
Compiler::GetSharedFunctionInfo(f, script, isolate));
// Return a null handle if any initial values can't be created. Caller
// will set stack overflow.
if (sfi.is_null()) return Handle<FixedArray>();
data->set(array_index++, *sfi);
int literal_index = generator->GetCachedCreateClosureSlot(f);
data->set(array_index++, Smi::FromInt(literal_index));
DCHECK(var->IsExport());
data->set(array_index++, Smi::FromInt(var->index()));
DCHECK_EQ(start + kModuleFunctionDeclarationSize, array_index);
} else if (var->IsExport() && var->binding_needs_init()) {
data->set(array_index++, Smi::FromInt(var->index()));
DCHECK_EQ(start + kModuleVariableDeclarationSize, array_index);
}
}
} else {
for (Declaration* decl : *info->scope()->declarations()) {
Variable* var = decl->var();
if (!var->is_used()) continue;
if (var->location() != VariableLocation::UNALLOCATED) continue;
#ifdef DEBUG
int start = array_index;
#endif
if (decl->IsVariableDeclaration()) {
data->set(array_index++, *var->raw_name()->string());
DCHECK_EQ(start + kGlobalVariableDeclarationSize, array_index);
} else {
FunctionLiteral* f = static_cast<FunctionDeclaration*>(decl)->fun();
Handle<SharedFunctionInfo> sfi(
Compiler::GetSharedFunctionInfo(f, script, isolate));
// Return a null handle if any initial values can't be created. Caller
// will set stack overflow.
if (sfi.is_null()) return Handle<FixedArray>();
data->set(array_index++, *sfi);
int literal_index = generator->GetCachedCreateClosureSlot(f);
data->set(array_index++, Smi::FromInt(literal_index));
DCHECK_EQ(start + kGlobalFunctionDeclarationSize, array_index);
}
}
}
DCHECK_EQ(array_index, data->length());
return data;
}
size_t constant_pool_entry() {
DCHECK(has_constant_pool_entry_);
return constant_pool_entry_;
}
void set_constant_pool_entry(size_t constant_pool_entry) {
DCHECK(has_top_level_declaration());
DCHECK(!has_constant_pool_entry_);
constant_pool_entry_ = constant_pool_entry;
has_constant_pool_entry_ = true;
}
void record_global_variable_declaration() {
entry_slots_ += kGlobalVariableDeclarationSize;
}
void record_global_function_declaration() {
entry_slots_ += kGlobalFunctionDeclarationSize;
}
void record_module_variable_declaration() {
entry_slots_ += kModuleVariableDeclarationSize;
}
void record_module_function_declaration() {
entry_slots_ += kModuleFunctionDeclarationSize;
}
bool has_top_level_declaration() { return entry_slots_ > 0; }
bool processed() { return processed_; }
void mark_processed() { processed_ = true; }
private:
const int kGlobalVariableDeclarationSize = 1;
const int kGlobalFunctionDeclarationSize = 2;
const int kModuleVariableDeclarationSize = 1;
const int kModuleFunctionDeclarationSize = 3;
size_t constant_pool_entry_ = 0;
int entry_slots_ = 0;
bool has_constant_pool_entry_ = false;
bool processed_ = false;
};
class BytecodeGenerator::CurrentScope final {
public:
CurrentScope(BytecodeGenerator* generator, Scope* scope)
: generator_(generator), outer_scope_(generator->current_scope()) {
if (scope != nullptr) {
DCHECK_EQ(outer_scope_, scope->outer_scope());
generator_->set_current_scope(scope);
}
}
~CurrentScope() {
if (outer_scope_ != generator_->current_scope()) {
generator_->set_current_scope(outer_scope_);
}
}
private:
BytecodeGenerator* generator_;
Scope* outer_scope_;
};
class BytecodeGenerator::FeedbackSlotCache : public ZoneObject {
public:
enum class SlotKind {
kStoreGlobalSloppy,
kStoreGlobalStrict,
kStoreNamedStrict,
kStoreNamedSloppy,
kLoadProperty,
kLoadSuperProperty,
kLoadGlobalNotInsideTypeof,
kLoadGlobalInsideTypeof,
kClosureFeedbackCell
};
explicit FeedbackSlotCache(Zone* zone) : map_(zone) {}
void Put(SlotKind slot_kind, Variable* variable, int slot_index) {
PutImpl(slot_kind, 0, variable, slot_index);
}
void Put(SlotKind slot_kind, AstNode* node, int slot_index) {
PutImpl(slot_kind, 0, node, slot_index);
}
void Put(SlotKind slot_kind, int variable_index, const AstRawString* name,
int slot_index) {
PutImpl(slot_kind, variable_index, name, slot_index);
}
void Put(SlotKind slot_kind, const AstRawString* name, int slot_index) {
PutImpl(slot_kind, 0, name, slot_index);
}
int Get(SlotKind slot_kind, Variable* variable) const {
return GetImpl(slot_kind, 0, variable);
}
int Get(SlotKind slot_kind, AstNode* node) const {
return GetImpl(slot_kind, 0, node);
}
int Get(SlotKind slot_kind, int variable_index,
const AstRawString* name) const {
return GetImpl(slot_kind, variable_index, name);
}
int Get(SlotKind slot_kind, const AstRawString* name) const {
return GetImpl(slot_kind, 0, name);
}
private:
using Key = std::tuple<SlotKind, int, const void*>;
void PutImpl(SlotKind slot_kind, int index, const void* node,
int slot_index) {
Key key = std::make_tuple(slot_kind, index, node);
auto entry = std::make_pair(key, slot_index);
map_.insert(entry);
}
int GetImpl(SlotKind slot_kind, int index, const void* node) const {
Key key = std::make_tuple(slot_kind, index, node);
auto iter = map_.find(key);
if (iter != map_.end()) {
return iter->second;
}
return -1;
}
ZoneMap<Key, int> map_;
};
class BytecodeGenerator::IteratorRecord final {
public:
IteratorRecord(Register object_register, Register next_register,
IteratorType type = IteratorType::kNormal)
: type_(type), object_(object_register), next_(next_register) {
DCHECK(object_.is_valid() && next_.is_valid());
}
inline IteratorType type() const { return type_; }
inline Register object() const { return object_; }
inline Register next() const { return next_; }
private:
IteratorType type_;
Register object_;
Register next_;
};
class BytecodeGenerator::OptionalChainNullLabelScope final {
public:
explicit OptionalChainNullLabelScope(BytecodeGenerator* bytecode_generator)
: bytecode_generator_(bytecode_generator),
labels_(bytecode_generator->zone()) {
prev_ = bytecode_generator_->optional_chaining_null_labels_;
bytecode_generator_->optional_chaining_null_labels_ = &labels_;
}
~OptionalChainNullLabelScope() {
bytecode_generator_->optional_chaining_null_labels_ = prev_;
}
BytecodeLabels* labels() { return &labels_; }
private:
BytecodeGenerator* bytecode_generator_;
BytecodeLabels labels_;
BytecodeLabels* prev_;
};
// LoopScope delimits the scope of {loop}, from its header to its final jump.
// It should be constructed iff a (conceptual) back edge should be produced. In
// the case of creating a LoopBuilder but never emitting the loop, it is valid
// to skip the creation of LoopScope.
class BytecodeGenerator::LoopScope final {
public:
explicit LoopScope(BytecodeGenerator* bytecode_generator, LoopBuilder* loop)
: bytecode_generator_(bytecode_generator),
parent_loop_scope_(bytecode_generator_->current_loop_scope()),
loop_builder_(loop) {
loop_builder_->LoopHeader();
bytecode_generator_->set_current_loop_scope(this);
bytecode_generator_->loop_depth_++;
}
~LoopScope() {
bytecode_generator_->loop_depth_--;
bytecode_generator_->set_current_loop_scope(parent_loop_scope_);
DCHECK_GE(bytecode_generator_->loop_depth_, 0);
loop_builder_->JumpToHeader(
bytecode_generator_->loop_depth_,
parent_loop_scope_ ? parent_loop_scope_->loop_builder_ : nullptr);
}
private:
BytecodeGenerator* const bytecode_generator_;
LoopScope* const parent_loop_scope_;
LoopBuilder* const loop_builder_;
};
namespace {
template <typename PropertyT>
struct Accessors : public ZoneObject {
Accessors() : getter(nullptr), setter(nullptr) {}
PropertyT* getter;
PropertyT* setter;
};
// A map from property names to getter/setter pairs allocated in the zone that
// also provides a way of accessing the pairs in the order they were first
// added so that the generated bytecode is always the same.
template <typename PropertyT>
class AccessorTable
: public base::TemplateHashMap<Literal, Accessors<PropertyT>,
bool (*)(void*, void*),
ZoneAllocationPolicy> {
public:
explicit AccessorTable(Zone* zone)
: base::TemplateHashMap<Literal, Accessors<PropertyT>,
bool (*)(void*, void*), ZoneAllocationPolicy>(
Literal::Match, ZoneAllocationPolicy(zone)),
zone_(zone) {}
Accessors<PropertyT>* LookupOrInsert(Literal* key) {
auto it = this->find(key, true);
if (it->second == nullptr) {
it->second = zone_->New<Accessors<PropertyT>>();
ordered_accessors_.push_back({key, it->second});
}
return it->second;
}
const std::vector<std::pair<Literal*, Accessors<PropertyT>*>>&
ordered_accessors() {
return ordered_accessors_;
}
private:
std::vector<std::pair<Literal*, Accessors<PropertyT>*>> ordered_accessors_;
Zone* zone_;
};
} // namespace
#ifdef DEBUG
static bool IsInEagerLiterals(
FunctionLiteral* literal,
const std::vector<FunctionLiteral*>& eager_literals) {
for (FunctionLiteral* eager_literal : eager_literals) {
if (literal == eager_literal) return true;
}
return false;
}
#endif // DEBUG
BytecodeGenerator::BytecodeGenerator(
Zone* compile_zone, UnoptimizedCompilationInfo* info,
const AstStringConstants* ast_string_constants,
std::vector<FunctionLiteral*>* eager_inner_literals)
: zone_(compile_zone),
builder_(zone(), info->num_parameters_including_this(),
info->scope()->num_stack_slots(), info->feedback_vector_spec(),
info->SourcePositionRecordingMode()),
info_(info),
ast_string_constants_(ast_string_constants),
closure_scope_(info->scope()),
current_scope_(info->scope()),
eager_inner_literals_(eager_inner_literals),
feedback_slot_cache_(zone()->New<FeedbackSlotCache>(zone())),
top_level_builder_(zone()->New<TopLevelDeclarationsBuilder>()),
block_coverage_builder_(nullptr),
function_literals_(0, zone()),
native_function_literals_(0, zone()),
object_literals_(0, zone()),
array_literals_(0, zone()),
class_literals_(0, zone()),
template_objects_(0, zone()),
execution_control_(nullptr),
execution_context_(nullptr),
execution_result_(nullptr),
incoming_new_target_or_generator_(),
optional_chaining_null_labels_(nullptr),
dummy_feedback_slot_(feedback_spec(), FeedbackSlotKind::kCompareOp),
generator_jump_table_(nullptr),
suspend_count_(0),
loop_depth_(0),
current_loop_scope_(nullptr),
catch_prediction_(HandlerTable::UNCAUGHT) {
DCHECK_EQ(closure_scope(), closure_scope()->GetClosureScope());
if (info->has_source_range_map()) {
block_coverage_builder_ = zone()->New<BlockCoverageBuilder>(
zone(), builder(), info->source_range_map());
}
}
namespace {
template <typename Isolate>
struct NullContextScopeHelper;
template <>
struct NullContextScopeHelper<Isolate> {
using Type = NullContextScope;
};
template <>
struct NullContextScopeHelper<LocalIsolate> {
class DummyNullContextScope {
public:
explicit DummyNullContextScope(LocalIsolate*) {}
};
using Type = DummyNullContextScope;
};
template <typename Isolate>
using NullContextScopeFor = typename NullContextScopeHelper<Isolate>::Type;
} // namespace
template <typename LocalIsolate>
Handle<BytecodeArray> BytecodeGenerator::FinalizeBytecode(
LocalIsolate* isolate, Handle<Script> script) {
DCHECK_EQ(ThreadId::Current(), isolate->thread_id());
#ifdef DEBUG
// Unoptimized compilation should be context-independent. Verify that we don't
// access the native context by nulling it out during finalization.
NullContextScopeFor<LocalIsolate> null_context_scope(isolate);
#endif
AllocateDeferredConstants(isolate, script);
if (block_coverage_builder_) {
Handle<CoverageInfo> coverage_info =
isolate->factory()->NewCoverageInfo(block_coverage_builder_->slots());
info()->set_coverage_info(coverage_info);
if (FLAG_trace_block_coverage) {
StdoutStream os;
coverage_info->CoverageInfoPrint(os, info()->literal()->GetDebugName());
}
}
if (HasStackOverflow()) return Handle<BytecodeArray>();
Handle<BytecodeArray> bytecode_array = builder()->ToBytecodeArray(isolate);
if (incoming_new_target_or_generator_.is_valid()) {
bytecode_array->set_incoming_new_target_or_generator_register(
incoming_new_target_or_generator_);
}
return bytecode_array;
}
template Handle<BytecodeArray> BytecodeGenerator::FinalizeBytecode(
Isolate* isolate, Handle<Script> script);
template Handle<BytecodeArray> BytecodeGenerator::FinalizeBytecode(
LocalIsolate* isolate, Handle<Script> script);
template <typename LocalIsolate>
Handle<ByteArray> BytecodeGenerator::FinalizeSourcePositionTable(
LocalIsolate* isolate) {
DCHECK_EQ(ThreadId::Current(), isolate->thread_id());
#ifdef DEBUG
// Unoptimized compilation should be context-independent. Verify that we don't
// access the native context by nulling it out during finalization.
NullContextScopeFor<LocalIsolate> null_context_scope(isolate);
#endif
Handle<ByteArray> source_position_table =
builder()->ToSourcePositionTable(isolate);
LOG_CODE_EVENT(isolate,
CodeLinePosInfoRecordEvent(
info_->bytecode_array()->GetFirstBytecodeAddress(),
*source_position_table));
return source_position_table;
}
template Handle<ByteArray> BytecodeGenerator::FinalizeSourcePositionTable(
Isolate* isolate);
template Handle<ByteArray> BytecodeGenerator::FinalizeSourcePositionTable(
LocalIsolate* isolate);
#ifdef DEBUG
int BytecodeGenerator::CheckBytecodeMatches(BytecodeArray bytecode) {
return builder()->CheckBytecodeMatches(bytecode);
}
#endif
template <typename LocalIsolate>
void BytecodeGenerator::AllocateDeferredConstants(LocalIsolate* isolate,
Handle<Script> script) {
if (top_level_builder()->has_top_level_declaration()) {
// Build global declaration pair array.
Handle<FixedArray> declarations = top_level_builder()->AllocateDeclarations(
info(), this, script, isolate);
if (declarations.is_null()) return SetStackOverflow();
builder()->SetDeferredConstantPoolEntry(
top_level_builder()->constant_pool_entry(), declarations);
}
// Find or build shared function infos.
for (std::pair<FunctionLiteral*, size_t> literal : function_literals_) {
FunctionLiteral* expr = literal.first;
Handle<SharedFunctionInfo> shared_info =
Compiler::GetSharedFunctionInfo(expr, script, isolate);
if (shared_info.is_null()) return SetStackOverflow();
builder()->SetDeferredConstantPoolEntry(literal.second, shared_info);
}
// Find or build shared function infos for the native function templates.
for (std::pair<NativeFunctionLiteral*, size_t> literal :
native_function_literals_) {
// This should only happen for main-thread compilations.
DCHECK((std::is_same<Isolate, v8::internal::Isolate>::value));
NativeFunctionLiteral* expr = literal.first;
v8::Isolate* v8_isolate = reinterpret_cast<v8::Isolate*>(isolate);
// Compute the function template for the native function.
v8::Local<v8::FunctionTemplate> info =
expr->extension()->GetNativeFunctionTemplate(
v8_isolate, Utils::ToLocal(expr->name()));
DCHECK(!info.IsEmpty());
Handle<SharedFunctionInfo> shared_info =
FunctionTemplateInfo::GetOrCreateSharedFunctionInfo(
isolate, Utils::OpenHandle(*info), expr->name());
DCHECK(!shared_info.is_null());
builder()->SetDeferredConstantPoolEntry(literal.second, shared_info);
}
// Build object literal constant properties
for (std::pair<ObjectLiteral*, size_t> literal : object_literals_) {
ObjectLiteral* object_literal = literal.first;
if (object_literal->properties_count() > 0) {
// If constant properties is an empty fixed array, we've already added it
// to the constant pool when visiting the object literal.
Handle<ObjectBoilerplateDescription> constant_properties =
object_literal->GetOrBuildBoilerplateDescription(isolate);
builder()->SetDeferredConstantPoolEntry(literal.second,
constant_properties);
}
}
// Build array literal constant elements
for (std::pair<ArrayLiteral*, size_t> literal : array_literals_) {
ArrayLiteral* array_literal = literal.first;
Handle<ArrayBoilerplateDescription> constant_elements =
array_literal->GetOrBuildBoilerplateDescription(isolate);
builder()->SetDeferredConstantPoolEntry(literal.second, constant_elements);
}
// Build class literal boilerplates.
for (std::pair<ClassLiteral*, size_t> literal : class_literals_) {
ClassLiteral* class_literal = literal.first;
Handle<ClassBoilerplate> class_boilerplate =
ClassBoilerplate::BuildClassBoilerplate(isolate, class_literal);
builder()->SetDeferredConstantPoolEntry(literal.second, class_boilerplate);
}
// Build template literals.
for (std::pair<GetTemplateObject*, size_t> literal : template_objects_) {
GetTemplateObject* get_template_object = literal.first;
Handle<TemplateObjectDescription> description =
get_template_object->GetOrBuildDescription(isolate);
builder()->SetDeferredConstantPoolEntry(literal.second, description);
}
}
template void BytecodeGenerator::AllocateDeferredConstants(
Isolate* isolate, Handle<Script> script);
template void BytecodeGenerator::AllocateDeferredConstants(
LocalIsolate* isolate, Handle<Script> script);
namespace {
bool NeedsContextInitialization(DeclarationScope* scope) {
return scope->NeedsContext() && !scope->is_script_scope() &&
!scope->is_module_scope();
}
} // namespace
void BytecodeGenerator::GenerateBytecode(uintptr_t stack_limit) {
DisallowHeapAllocation no_allocation;
DisallowHandleAllocation no_handles;
DisallowHandleDereference no_deref;
InitializeAstVisitor(stack_limit);
// Initialize the incoming context.
ContextScope incoming_context(this, closure_scope());
// Initialize control scope.
ControlScopeForTopLevel control(this);
RegisterAllocationScope register_scope(this);
AllocateTopLevelRegisters();
builder()->EmitFunctionStartSourcePosition(
info()->literal()->start_position());
if (info()->literal()->CanSuspend()) {
BuildGeneratorPrologue();
}
if (NeedsContextInitialization(closure_scope())) {
// Push a new inner context scope for the function.
BuildNewLocalActivationContext();
ContextScope local_function_context(this, closure_scope());
BuildLocalActivationContextInitialization();
GenerateBytecodeBody();
} else {
GenerateBytecodeBody();
}
// Check that we are not falling off the end.
DCHECK(builder()->RemainderOfBlockIsDead());
}
void BytecodeGenerator::GenerateBytecodeBody() {
// Build the arguments object if it is used.
VisitArgumentsObject(closure_scope()->arguments());
// Build rest arguments array if it is used.
Variable* rest_parameter = closure_scope()->rest_parameter();
VisitRestArgumentsArray(rest_parameter);
// Build assignment to the function name or {.this_function}
// variables if used.
VisitThisFunctionVariable(closure_scope()->function_var());
VisitThisFunctionVariable(closure_scope()->this_function_var());
// Build assignment to {new.target} variable if it is used.
VisitNewTargetVariable(closure_scope()->new_target_var());
// Create a generator object if necessary and initialize the
// {.generator_object} variable.
FunctionLiteral* literal = info()->literal();
if (IsResumableFunction(literal->kind())) {
BuildGeneratorObjectVariableInitialization();
}
// Emit tracing call if requested to do so.
if (FLAG_trace) builder()->CallRuntime(Runtime::kTraceEnter);
// Emit type profile call.
if (info()->flags().collect_type_profile()) {
feedback_spec()->AddTypeProfileSlot();
int num_parameters = closure_scope()->num_parameters();
for (int i = 0; i < num_parameters; i++) {
Register parameter(builder()->Parameter(i));
builder()->LoadAccumulatorWithRegister(parameter).CollectTypeProfile(
closure_scope()->parameter(i)->initializer_position());
}
}
// Increment the function-scope block coverage counter.
BuildIncrementBlockCoverageCounterIfEnabled(literal, SourceRangeKind::kBody);
// Visit declarations within the function scope.
if (closure_scope()->is_script_scope()) {
VisitGlobalDeclarations(closure_scope()->declarations());
} else if (closure_scope()->is_module_scope()) {
VisitModuleDeclarations(closure_scope()->declarations());
} else {
VisitDeclarations(closure_scope()->declarations());
}
// Emit initializing assignments for module namespace imports (if any).
VisitModuleNamespaceImports();
// The derived constructor case is handled in VisitCallSuper.
if (IsBaseConstructor(function_kind())) {
if (literal->class_scope_has_private_brand()) {
BuildPrivateBrandInitialization(builder()->Receiver());
}
if (literal->requires_instance_members_initializer()) {
BuildInstanceMemberInitialization(Register::function_closure(),
builder()->Receiver());
}
}
// Visit statements in the function body.
VisitStatements(literal->body());
// Emit an implicit return instruction in case control flow can fall off the
// end of the function without an explicit return being present on all paths.
if (!builder()->RemainderOfBlockIsDead()) {
builder()->LoadUndefined();
BuildReturn();
}
}
void BytecodeGenerator::AllocateTopLevelRegisters() {
if (IsResumableFunction(info()->literal()->kind())) {
// Either directly use generator_object_var or allocate a new register for
// the incoming generator object.
Variable* generator_object_var = closure_scope()->generator_object_var();
if (generator_object_var->location() == VariableLocation::LOCAL) {
incoming_new_target_or_generator_ =
GetRegisterForLocalVariable(generator_object_var);
} else {
incoming_new_target_or_generator_ = register_allocator()->NewRegister();
}
} else if (closure_scope()->new_target_var()) {
// Either directly use new_target_var or allocate a new register for
// the incoming new target object.
Variable* new_target_var = closure_scope()->new_target_var();
if (new_target_var->location() == VariableLocation::LOCAL) {
incoming_new_target_or_generator_ =
GetRegisterForLocalVariable(new_target_var);
} else {
incoming_new_target_or_generator_ = register_allocator()->NewRegister();
}
}
}
void BytecodeGenerator::BuildGeneratorPrologue() {
DCHECK_GT(info()->literal()->suspend_count(), 0);
DCHECK(generator_object().is_valid());
generator_jump_table_ =
builder()->AllocateJumpTable(info()->literal()->suspend_count(), 0);
// If the generator is not undefined, this is a resume, so perform state
// dispatch.
builder()->SwitchOnGeneratorState(generator_object(), generator_jump_table_);
// Otherwise, fall-through to the ordinary function prologue, after which we
// will run into the generator object creation and other extra code inserted
// by the parser.
}
void BytecodeGenerator::VisitBlock(Block* stmt) {
// Visit declarations and statements.
CurrentScope current_scope(this, stmt->scope());
if (stmt->scope() != nullptr && stmt->scope()->NeedsContext()) {
BuildNewLocalBlockContext(stmt->scope());
ContextScope scope(this, stmt->scope());
VisitBlockDeclarationsAndStatements(stmt);
} else {
VisitBlockDeclarationsAndStatements(stmt);
}
}
void BytecodeGenerator::VisitBlockDeclarationsAndStatements(Block* stmt) {
BlockBuilder block_builder(builder(), block_coverage_builder_, stmt);
ControlScopeForBreakable execution_control(this, stmt, &block_builder);
if (stmt->scope() != nullptr) {
VisitDeclarations(stmt->scope()->declarations());
}
VisitStatements(stmt->statements());
}
void BytecodeGenerator::VisitVariableDeclaration(VariableDeclaration* decl) {
Variable* variable = decl->var();
// Unused variables don't need to be visited.
if (!variable->is_used()) return;
switch (variable->location()) {
case VariableLocation::UNALLOCATED:
case VariableLocation::MODULE:
UNREACHABLE();
case VariableLocation::LOCAL:
if (variable->binding_needs_init()) {
Register destination(builder()->Local(variable->index()));
builder()->LoadTheHole().StoreAccumulatorInRegister(destination);
}
break;
case VariableLocation::PARAMETER:
if (variable->binding_needs_init()) {
Register destination(builder()->Parameter(variable->index()));
builder()->LoadTheHole().StoreAccumulatorInRegister(destination);
}
break;
case VariableLocation::REPL_GLOBAL:
// REPL let's are stored in script contexts. They get initialized
// with the hole the same way as normal context allocated variables.
case VariableLocation::CONTEXT:
if (variable->binding_needs_init()) {
DCHECK_EQ(0, execution_context()->ContextChainDepth(variable->scope()));
builder()->LoadTheHole().StoreContextSlot(execution_context()->reg(),
variable->index(), 0);
}
break;
case VariableLocation::LOOKUP: {
DCHECK_EQ(VariableMode::kDynamic, variable->mode());
DCHECK(!variable->binding_needs_init());
Register name = register_allocator()->NewRegister();
builder()
->LoadLiteral(variable->raw_name())
.StoreAccumulatorInRegister(name)
.CallRuntime(Runtime::kDeclareEvalVar, name);
break;
}
}
}
void BytecodeGenerator::VisitFunctionDeclaration(FunctionDeclaration* decl) {
Variable* variable = decl->var();
DCHECK(variable->mode() == VariableMode::kLet ||
variable->mode() == VariableMode::kVar ||
variable->mode() == VariableMode::kDynamic);
// Unused variables don't need to be visited.
if (!variable->is_used()) return;
switch (variable->location()) {
case VariableLocation::UNALLOCATED:
case VariableLocation::MODULE:
UNREACHABLE();
case VariableLocation::PARAMETER:
case VariableLocation::LOCAL: {
VisitFunctionLiteral(decl->fun());
BuildVariableAssignment(variable, Token::INIT, HoleCheckMode::kElided);
break;
}
case VariableLocation::REPL_GLOBAL:
case VariableLocation::CONTEXT: {
DCHECK_EQ(0, execution_context()->ContextChainDepth(variable->scope()));
VisitFunctionLiteral(decl->fun());
builder()->StoreContextSlot(execution_context()->reg(), variable->index(),
0);
break;
}
case VariableLocation::LOOKUP: {
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadLiteral(variable->raw_name())
.StoreAccumulatorInRegister(args[0]);
VisitFunctionLiteral(decl->fun());
builder()->StoreAccumulatorInRegister(args[1]).CallRuntime(
Runtime::kDeclareEvalFunction, args);
break;
}
}
DCHECK_IMPLIES(
eager_inner_literals_ != nullptr && decl->fun()->ShouldEagerCompile(),
IsInEagerLiterals(decl->fun(), *eager_inner_literals_));
}
void BytecodeGenerator::VisitModuleNamespaceImports() {
if (!closure_scope()->is_module_scope()) return;
RegisterAllocationScope register_scope(this);
Register module_request = register_allocator()->NewRegister();
SourceTextModuleDescriptor* descriptor =
closure_scope()->AsModuleScope()->module();
for (auto entry : descriptor->namespace_imports()) {
builder()
->LoadLiteral(Smi::FromInt(entry->module_request))
.StoreAccumulatorInRegister(module_request)
.CallRuntime(Runtime::kGetModuleNamespace, module_request);
Variable* var = closure_scope()->LookupInModule(entry->local_name);
BuildVariableAssignment(var, Token::INIT, HoleCheckMode::kElided);
}
}
void BytecodeGenerator::BuildDeclareCall(Runtime::FunctionId id) {
if (!top_level_builder()->has_top_level_declaration()) return;
DCHECK(!top_level_builder()->processed());
top_level_builder()->set_constant_pool_entry(
builder()->AllocateDeferredConstantPoolEntry());
// Emit code to declare globals.
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadConstantPoolEntry(top_level_builder()->constant_pool_entry())
.StoreAccumulatorInRegister(args[0])
.MoveRegister(Register::function_closure(), args[1])
.CallRuntime(id, args);
top_level_builder()->mark_processed();
}
void BytecodeGenerator::VisitModuleDeclarations(Declaration::List* decls) {
RegisterAllocationScope register_scope(this);
for (Declaration* decl : *decls) {
Variable* var = decl->var();
if (!var->is_used()) continue;
if (var->location() == VariableLocation::MODULE) {
if (decl->IsFunctionDeclaration()) {
DCHECK(var->IsExport());
FunctionDeclaration* f = static_cast<FunctionDeclaration*>(decl);
AddToEagerLiteralsIfEager(f->fun());
top_level_builder()->record_module_function_declaration();
} else if (var->IsExport() && var->binding_needs_init()) {
DCHECK(decl->IsVariableDeclaration());
top_level_builder()->record_module_variable_declaration();
}
} else {
RegisterAllocationScope register_scope(this);
Visit(decl);
}
}
BuildDeclareCall(Runtime::kDeclareModuleExports);
}
void BytecodeGenerator::VisitGlobalDeclarations(Declaration::List* decls) {
RegisterAllocationScope register_scope(this);
for (Declaration* decl : *decls) {
Variable* var = decl->var();
DCHECK(var->is_used());
if (var->location() == VariableLocation::UNALLOCATED) {
// var or function.
if (decl->IsFunctionDeclaration()) {
top_level_builder()->record_global_function_declaration();
FunctionDeclaration* f = static_cast<FunctionDeclaration*>(decl);
AddToEagerLiteralsIfEager(f->fun());
} else {
top_level_builder()->record_global_variable_declaration();
}
} else {
// let or const. Handled in NewScriptContext.
DCHECK(decl->IsVariableDeclaration());
DCHECK(IsLexicalVariableMode(var->mode()));
}
}
BuildDeclareCall(Runtime::kDeclareGlobals);
}
void BytecodeGenerator::VisitDeclarations(Declaration::List* declarations) {
for (Declaration* decl : *declarations) {
RegisterAllocationScope register_scope(this);
Visit(decl);
}
}
void BytecodeGenerator::VisitStatements(
const ZonePtrList<Statement>* statements) {
for (int i = 0; i < statements->length(); i++) {
// Allocate an outer register allocations scope for the statement.
RegisterAllocationScope allocation_scope(this);
Statement* stmt = statements->at(i);
Visit(stmt);
if (builder()->RemainderOfBlockIsDead()) break;
}
}
void BytecodeGenerator::VisitExpressionStatement(ExpressionStatement* stmt) {
builder()->SetStatementPosition(stmt);
VisitForEffect(stmt->expression());
}
void BytecodeGenerator::VisitEmptyStatement(EmptyStatement* stmt) {}
void BytecodeGenerator::VisitIfStatement(IfStatement* stmt) {
ConditionalControlFlowBuilder conditional_builder(
builder(), block_coverage_builder_, stmt);
builder()->SetStatementPosition(stmt);
if (stmt->condition()->ToBooleanIsTrue()) {
// Generate then block unconditionally as always true.
conditional_builder.Then();
Visit(stmt->then_statement());
} else if (stmt->condition()->ToBooleanIsFalse()) {
// Generate else block unconditionally if it exists.
if (stmt->HasElseStatement()) {
conditional_builder.Else();
Visit(stmt->else_statement());
}
} else {
// TODO(oth): If then statement is BreakStatement or
// ContinueStatement we can reduce number of generated
// jump/jump_ifs here. See BasicLoops test.
VisitForTest(stmt->condition(), conditional_builder.then_labels(),
conditional_builder.else_labels(), TestFallthrough::kThen);
conditional_builder.Then();
Visit(stmt->then_statement());
if (stmt->HasElseStatement()) {
conditional_builder.JumpToEnd();
conditional_builder.Else();
Visit(stmt->else_statement());
}
}
}
void BytecodeGenerator::VisitSloppyBlockFunctionStatement(
SloppyBlockFunctionStatement* stmt) {
Visit(stmt->statement());
}
void BytecodeGenerator::VisitContinueStatement(ContinueStatement* stmt) {
AllocateBlockCoverageSlotIfEnabled(stmt, SourceRangeKind::kContinuation);
builder()->SetStatementPosition(stmt);
execution_control()->Continue(stmt->target());
}
void BytecodeGenerator::VisitBreakStatement(BreakStatement* stmt) {
AllocateBlockCoverageSlotIfEnabled(stmt, SourceRangeKind::kContinuation);
builder()->SetStatementPosition(stmt);
execution_control()->Break(stmt->target());
}
void BytecodeGenerator::VisitReturnStatement(ReturnStatement* stmt) {
AllocateBlockCoverageSlotIfEnabled(stmt, SourceRangeKind::kContinuation);
builder()->SetStatementPosition(stmt);
VisitForAccumulatorValue(stmt->expression());
if (stmt->is_async_return()) {
execution_control()->AsyncReturnAccumulator(stmt->end_position());
} else {
execution_control()->ReturnAccumulator(stmt->end_position());
}
}
void BytecodeGenerator::VisitWithStatement(WithStatement* stmt) {
builder()->SetStatementPosition(stmt);
VisitForAccumulatorValue(stmt->expression());
BuildNewLocalWithContext(stmt->scope());
VisitInScope(stmt->statement(), stmt->scope());
}
void BytecodeGenerator::VisitSwitchStatement(SwitchStatement* stmt) {
// We need this scope because we visit for register values. We have to
// maintain a execution result scope where registers can be allocated.
ZonePtrList<CaseClause>* clauses = stmt->cases();
SwitchBuilder switch_builder(builder(), block_coverage_builder_, stmt,
clauses->length());
ControlScopeForBreakable scope(this, stmt, &switch_builder);
int default_index = -1;
builder()->SetStatementPosition(stmt);
// Keep the switch value in a register until a case matches.
Register tag = VisitForRegisterValue(stmt->tag());
FeedbackSlot slot = clauses->length() > 0
? feedback_spec()->AddCompareICSlot()
: FeedbackSlot::Invalid();
// Iterate over all cases and create nodes for label comparison.
for (int i = 0; i < clauses->length(); i++) {
CaseClause* clause = clauses->at(i);
// The default is not a test, remember index.
if (clause->is_default()) {
default_index = i;
continue;
}
// Perform label comparison as if via '===' with tag.
VisitForAccumulatorValue(clause->label());
builder()->CompareOperation(Token::Value::EQ_STRICT, tag,
feedback_index(slot));
switch_builder.Case(ToBooleanMode::kAlreadyBoolean, i);
}
if (default_index >= 0) {
// Emit default jump if there is a default case.
switch_builder.DefaultAt(default_index);
} else {
// Otherwise if we have reached here none of the cases matched, so jump to
// the end.
switch_builder.Break();
}
// Iterate over all cases and create the case bodies.
for (int i = 0; i < clauses->length(); i++) {
CaseClause* clause = clauses->at(i);
switch_builder.SetCaseTarget(i, clause);
VisitStatements(clause->statements());
}
}
template <typename TryBodyFunc, typename CatchBodyFunc>
void BytecodeGenerator::BuildTryCatch(
TryBodyFunc try_body_func, CatchBodyFunc catch_body_func,
HandlerTable::CatchPrediction catch_prediction,
TryCatchStatement* stmt_for_coverage) {
TryCatchBuilder try_control_builder(
builder(),
stmt_for_coverage == nullptr ? nullptr : block_coverage_builder_,
stmt_for_coverage, catch_prediction);
// Preserve the context in a dedicated register, so that it can be restored
// when the handler is entered by the stack-unwinding machinery.
// TODO(ignition): Be smarter about register allocation.
Register context = register_allocator()->NewRegister();
builder()->MoveRegister(Register::current_context(), context);
// Evaluate the try-block inside a control scope. This simulates a handler
// that is intercepting 'throw' control commands.
try_control_builder.BeginTry(context);
{
ControlScopeForTryCatch scope(this, &try_control_builder);
try_body_func();
}
try_control_builder.EndTry();
catch_body_func(context);
try_control_builder.EndCatch();
}
template <typename TryBodyFunc, typename FinallyBodyFunc>
void BytecodeGenerator::BuildTryFinally(
TryBodyFunc try_body_func, FinallyBodyFunc finally_body_func,
HandlerTable::CatchPrediction catch_prediction,
TryFinallyStatement* stmt_for_coverage) {
// We can't know whether the finally block will override ("catch") an
// exception thrown in the try block, so we just adopt the outer prediction.
TryFinallyBuilder try_control_builder(
builder(),
stmt_for_coverage == nullptr ? nullptr : block_coverage_builder_,
stmt_for_coverage, catch_prediction);
// We keep a record of all paths that enter the finally-block to be able to
// dispatch to the correct continuation point after the statements in the
// finally-block have been evaluated.
//
// The try-finally construct can enter the finally-block in three ways:
// 1. By exiting the try-block normally, falling through at the end.
// 2. By exiting the try-block with a function-local control flow transfer
// (i.e. through break/continue/return statements).
// 3. By exiting the try-block with a thrown exception.
//
// The result register semantics depend on how the block was entered:
// - ReturnStatement: It represents the return value being returned.
// - ThrowStatement: It represents the exception being thrown.
// - BreakStatement/ContinueStatement: Undefined and not used.
// - Falling through into finally-block: Undefined and not used.
Register token = register_allocator()->NewRegister();
Register result = register_allocator()->NewRegister();
ControlScope::DeferredCommands commands(this, token, result);
// Preserve the context in a dedicated register, so that it can be restored
// when the handler is entered by the stack-unwinding machinery.
// TODO(ignition): Be smarter about register allocation.
Register context = register_allocator()->NewRegister();
builder()->MoveRegister(Register::current_context(), context);
// Evaluate the try-block inside a control scope. This simulates a handler
// that is intercepting all control commands.
try_control_builder.BeginTry(context);
{
ControlScopeForTryFinally scope(this, &try_control_builder, &commands);
try_body_func();
}
try_control_builder.EndTry();
// Record fall-through and exception cases.
commands.RecordFallThroughPath();
try_control_builder.LeaveTry();
try_control_builder.BeginHandler();
commands.RecordHandlerReThrowPath();
// Pending message object is saved on entry.
try_control_builder.BeginFinally();
Register message = context; // Reuse register.
// Clear message object as we enter the finally block.
builder()->LoadTheHole().SetPendingMessage().StoreAccumulatorInRegister(
message);
// Evaluate the finally-block.
finally_body_func(token);
try_control_builder.EndFinally();
// Pending message object is restored on exit.
builder()->LoadAccumulatorWithRegister(message).SetPendingMessage();
// Dynamic dispatch after the finally-block.
commands.ApplyDeferredCommands();
}
void BytecodeGenerator::VisitIterationBody(IterationStatement* stmt,
LoopBuilder* loop_builder) {
loop_builder->LoopBody();
ControlScopeForIteration execution_control(this, stmt, loop_builder);
Visit(stmt->body());
loop_builder->BindContinueTarget();
}
void BytecodeGenerator::VisitDoWhileStatement(DoWhileStatement* stmt) {
LoopBuilder loop_builder(builder(), block_coverage_builder_, stmt);
if (stmt->cond()->ToBooleanIsFalse()) {
// Since we know that the condition is false, we don't create a loop.
// Therefore, we don't create a LoopScope (and thus we don't create a header
// and a JumpToHeader). However, we still need to iterate once through the
// body.
VisitIterationBody(stmt, &loop_builder);
} else if (stmt->cond()->ToBooleanIsTrue()) {
LoopScope loop_scope(this, &loop_builder);
VisitIterationBody(stmt, &loop_builder);
} else {
LoopScope loop_scope(this, &loop_builder);
VisitIterationBody(stmt, &loop_builder);
builder()->SetExpressionAsStatementPosition(stmt->cond());
BytecodeLabels loop_backbranch(zone());
VisitForTest(stmt->cond(), &loop_backbranch, loop_builder.break_labels(),
TestFallthrough::kThen);
loop_backbranch.Bind(builder());
}
}
void BytecodeGenerator::VisitWhileStatement(WhileStatement* stmt) {
LoopBuilder loop_builder(builder(), block_coverage_builder_, stmt);
if (stmt->cond()->ToBooleanIsFalse()) {
// If the condition is false there is no need to generate the loop.
return;
}
LoopScope loop_scope(this, &loop_builder);
if (!stmt->cond()->ToBooleanIsTrue()) {
builder()->SetExpressionAsStatementPosition(stmt->cond());
BytecodeLabels loop_body(zone());
VisitForTest(stmt->cond(), &loop_body, loop_builder.break_labels(),
TestFallthrough::kThen);
loop_body.Bind(builder());
}
VisitIterationBody(stmt, &loop_builder);
}
void BytecodeGenerator::VisitForStatement(ForStatement* stmt) {
if (stmt->init() != nullptr) {
Visit(stmt->init());
}
LoopBuilder loop_builder(builder(), block_coverage_builder_, stmt);
if (stmt->cond() && stmt->cond()->ToBooleanIsFalse()) {
// If the condition is known to be false there is no need to generate
// body, next or condition blocks. Init block should be generated.
return;
}
LoopScope loop_scope(this, &loop_builder);
if (stmt->cond() && !stmt->cond()->ToBooleanIsTrue()) {
builder()->SetExpressionAsStatementPosition(stmt->cond());
BytecodeLabels loop_body(zone());
VisitForTest(stmt->cond(), &loop_body, loop_builder.break_labels(),
TestFallthrough::kThen);
loop_body.Bind(builder());
}
VisitIterationBody(stmt, &loop_builder);
if (stmt->next() != nullptr) {
builder()->SetStatementPosition(stmt->next());
Visit(stmt->next());
}
}
void BytecodeGenerator::VisitForInStatement(ForInStatement* stmt) {
if (stmt->subject()->IsNullLiteral() ||
stmt->subject()->IsUndefinedLiteral()) {
// ForIn generates lots of code, skip if it wouldn't produce any effects.
return;
}
BytecodeLabel subject_undefined_label;
FeedbackSlot slot = feedback_spec()->AddForInSlot();
// Prepare the state for executing ForIn.
builder()->SetExpressionAsStatementPosition(stmt->subject());
VisitForAccumulatorValue(stmt->subject());
builder()->JumpIfUndefinedOrNull(&subject_undefined_label);
Register receiver = register_allocator()->NewRegister();
builder()->ToObject(receiver);
// Used as kRegTriple and kRegPair in ForInPrepare and ForInNext.
RegisterList triple = register_allocator()->NewRegisterList(3);
Register cache_length = triple[2];
builder()->ForInEnumerate(receiver);
builder()->ForInPrepare(triple, feedback_index(slot));
// Set up loop counter
Register index = register_allocator()->NewRegister();
builder()->LoadLiteral(Smi::zero());
builder()->StoreAccumulatorInRegister(index);
// The loop
{
LoopBuilder loop_builder(builder(), block_coverage_builder_, stmt);
LoopScope loop_scope(this, &loop_builder);
builder()->SetExpressionAsStatementPosition(stmt->each());
builder()->ForInContinue(index, cache_length);
loop_builder.BreakIfFalse(ToBooleanMode::kAlreadyBoolean);
builder()->ForInNext(receiver, index, triple.Truncate(2),
feedback_index(slot));
loop_builder.ContinueIfUndefined();
// Assign accumulator value to the 'each' target.
{
EffectResultScope scope(this);
// Make sure to preserve the accumulator across the PrepareAssignmentLhs
// call.
AssignmentLhsData lhs_data = PrepareAssignmentLhs(
stmt->each(), AccumulatorPreservingMode::kPreserve);
builder()->SetExpressionPosition(stmt->each());
BuildAssignment(lhs_data, Token::ASSIGN, LookupHoistingMode::kNormal);
}
VisitIterationBody(stmt, &loop_builder);
builder()->ForInStep(index);
builder()->StoreAccumulatorInRegister(index);
}
builder()->Bind(&subject_undefined_label);
}
// Desugar a for-of statement into an application of the iteration protocol.
//
// for (EACH of SUBJECT) BODY
//
// becomes
//
// iterator = %GetIterator(SUBJECT)
// try {
//
// loop {
// // Make sure we are considered 'done' if .next(), .done or .value fail.
// done = true
// value = iterator.next()
// if (value.done) break;
// value = value.value
// done = false
//
// EACH = value
// BODY
// }
// done = true
//
// } catch(e) {
// iteration_continuation = RETHROW
// } finally {
// %FinalizeIteration(iterator, done, iteration_continuation)
// }
void BytecodeGenerator::VisitForOfStatement(ForOfStatement* stmt) {
EffectResultScope effect_scope(this);
builder()->SetExpressionAsStatementPosition(stmt->subject());
VisitForAccumulatorValue(stmt->subject());
// Store the iterator in a dedicated register so that it can be closed on
// exit, and the 'done' value in a dedicated register so that it can be
// changed and accessed independently of the iteration result.
IteratorRecord iterator = BuildGetIteratorRecord(stmt->type());
Register done = register_allocator()->NewRegister();
builder()->LoadFalse();
builder()->StoreAccumulatorInRegister(done);
BuildTryFinally(
// Try block.
[&]() {
Register next_result = register_allocator()->NewRegister();
LoopBuilder loop_builder(builder(), block_coverage_builder_, stmt);
LoopScope loop_scope(this, &loop_builder);
builder()->LoadTrue().StoreAccumulatorInRegister(done);
// Call the iterator's .next() method. Break from the loop if the `done`
// property is truthy, otherwise load the value from the iterator result
// and append the argument.
builder()->SetExpressionAsStatementPosition(stmt->each());
BuildIteratorNext(iterator, next_result);
builder()->LoadNamedProperty(
next_result, ast_string_constants()->done_string(),
feedback_index(feedback_spec()->AddLoadICSlot()));
loop_builder.BreakIfTrue(ToBooleanMode::kConvertToBoolean);
builder()
// value = value.value
->LoadNamedProperty(
next_result, ast_string_constants()->value_string(),
feedback_index(feedback_spec()->AddLoadICSlot()));
// done = false, before the assignment to each happens, so that done is
// false if the assignment throws.
builder()
->StoreAccumulatorInRegister(next_result)
.LoadFalse()
.StoreAccumulatorInRegister(done);
// Assign to the 'each' target.
AssignmentLhsData lhs_data = PrepareAssignmentLhs(stmt->each());
builder()->LoadAccumulatorWithRegister(next_result);
BuildAssignment(lhs_data, Token::ASSIGN, LookupHoistingMode::kNormal);
VisitIterationBody(stmt, &loop_builder);
},
// Finally block.
[&](Register iteration_continuation_token) {
// Finish the iteration in the finally block.
BuildFinalizeIteration(iterator, done, iteration_continuation_token);
},
HandlerTable::UNCAUGHT);
}
void BytecodeGenerator::VisitTryCatchStatement(TryCatchStatement* stmt) {
// Update catch prediction tracking. The updated catch_prediction value lasts
// until the end of the try_block in the AST node, and does not apply to the
// catch_block.
HandlerTable::CatchPrediction outer_catch_prediction = catch_prediction();
set_catch_prediction(stmt->GetCatchPrediction(outer_catch_prediction));
BuildTryCatch(
// Try body.
[&]() {
Visit(stmt->try_block());
set_catch_prediction(outer_catch_prediction);
},
// Catch body.
[&](Register context) {
if (stmt->scope()) {
// Create a catch scope that binds the exception.
BuildNewLocalCatchContext(stmt->scope());
builder()->StoreAccumulatorInRegister(context);
}
// If requested, clear message object as we enter the catch block.
if (stmt->ShouldClearPendingException(outer_catch_prediction)) {
builder()->LoadTheHole().SetPendingMessage();
}
// Load the catch context into the accumulator.
builder()->LoadAccumulatorWithRegister(context);
// Evaluate the catch-block.
if (stmt->scope()) {
VisitInScope(stmt->catch_block(), stmt->scope());
} else {
VisitBlock(stmt->catch_block());
}
},
catch_prediction(), stmt);
}
void BytecodeGenerator::VisitTryFinallyStatement(TryFinallyStatement* stmt) {
BuildTryFinally(
// Try block.
[&]() { Visit(stmt->try_block()); },
// Finally block.
[&](Register body_continuation_token) { Visit(stmt->finally_block()); },
catch_prediction(), stmt);
}
void BytecodeGenerator::VisitDebuggerStatement(DebuggerStatement* stmt) {
builder()->SetStatementPosition(stmt);
builder()->Debugger();
}
void BytecodeGenerator::VisitFunctionLiteral(FunctionLiteral* expr) {
DCHECK(expr->scope()->outer_scope() == current_scope());
uint8_t flags = CreateClosureFlags::Encode(
expr->pretenure(), closure_scope()->is_function_scope(),
info()->flags().might_always_opt());
size_t entry = builder()->AllocateDeferredConstantPoolEntry();
builder()->CreateClosure(entry, GetCachedCreateClosureSlot(expr), flags);
function_literals_.push_back(std::make_pair(expr, entry));
AddToEagerLiteralsIfEager(expr);
}
void BytecodeGenerator::AddToEagerLiteralsIfEager(FunctionLiteral* literal) {
if (eager_inner_literals_ && literal->ShouldEagerCompile()) {
DCHECK(!IsInEagerLiterals(literal, *eager_inner_literals_));
eager_inner_literals_->push_back(literal);
}
}
bool BytecodeGenerator::ShouldOptimizeAsOneShot() const {
if (!FLAG_enable_one_shot_optimization) return false;
if (loop_depth_ > 0) return false;
return info()->literal()->is_toplevel() ||
info()->literal()->is_oneshot_iife();
}
void BytecodeGenerator::BuildClassLiteral(ClassLiteral* expr, Register name) {
size_t class_boilerplate_entry =
builder()->AllocateDeferredConstantPoolEntry();
class_literals_.push_back(std::make_pair(expr, class_boilerplate_entry));
VisitDeclarations(expr->scope()->declarations());
Register class_constructor = register_allocator()->NewRegister();
// Create the class brand symbol and store it on the context during class
// evaluation. This will be stored in the instance later in the constructor.
// We do this early so that invalid access to private methods or accessors
// in computed property keys throw.
if (expr->scope()->brand() != nullptr) {
Register brand = register_allocator()->NewRegister();
const AstRawString* class_name =
expr->scope()->class_variable() != nullptr
? expr->scope()->class_variable()->raw_name()
: ast_string_constants()->empty_string();
builder()
->LoadLiteral(class_name)
.StoreAccumulatorInRegister(brand)
.CallRuntime(Runtime::kCreatePrivateBrandSymbol, brand);
BuildVariableAssignment(expr->scope()->brand(), Token::INIT,
HoleCheckMode::kElided);
}
AccessorTable<ClassLiteral::Property> private_accessors(zone());
for (int i = 0; i < expr->private_members()->length(); i++) {
ClassLiteral::Property* property = expr->private_members()->at(i);
DCHECK(property->is_private());
switch (property->kind()) {
case ClassLiteral::Property::FIELD: {
// Initialize the private field variables early.
// Create the private name symbols for fields during class
// evaluation and store them on the context. These will be
// used as keys later during instance or static initialization.
RegisterAllocationScope private_name_register_scope(this);
Register private_name = register_allocator()->NewRegister();
VisitForRegisterValue(property->key(), private_name);
builder()
->LoadLiteral(property->key()->AsLiteral()->AsRawPropertyName())
.StoreAccumulatorInRegister(private_name)
.CallRuntime(Runtime::kCreatePrivateNameSymbol, private_name);
DCHECK_NOT_NULL(property->private_name_var());
BuildVariableAssignment(property->private_name_var(), Token::INIT,
HoleCheckMode::kElided);
break;
}
case ClassLiteral::Property::METHOD: {
// We can initialize the private methods and accessors later so that the
// home objects can be assigned right after the creation of the
// closures, and those are guarded by the brand checks.
break;
}
// Collect private accessors into a table to merge the creation of
// those closures later.
case ClassLiteral::Property::GETTER: {
Literal* key = property->key()->AsLiteral();
DCHECK_NULL(private_accessors.LookupOrInsert(key)->getter);
private_accessors.LookupOrInsert(key)->getter = property;
break;
}
case ClassLiteral::Property::SETTER: {
Literal* key = property->key()->AsLiteral();
DCHECK_NULL(private_accessors.LookupOrInsert(key)->setter);
private_accessors.LookupOrInsert(key)->setter = property;
break;
}
default:
UNREACHABLE();
}
}
{
RegisterAllocationScope register_scope(this);
RegisterList args = register_allocator()->NewGrowableRegisterList();
Register class_boilerplate = register_allocator()->GrowRegisterList(&args);
Register class_constructor_in_args =
register_allocator()->GrowRegisterList(&args);
Register super_class = register_allocator()->GrowRegisterList(&args);
DCHECK_EQ(ClassBoilerplate::kFirstDynamicArgumentIndex,
args.register_count());
VisitForAccumulatorValueOrTheHole(expr->extends());
builder()->StoreAccumulatorInRegister(super_class);
VisitFunctionLiteral(expr->constructor());
builder()
->StoreAccumulatorInRegister(class_constructor)
.MoveRegister(class_constructor, class_constructor_in_args)
.LoadConstantPoolEntry(class_boilerplate_entry)
.StoreAccumulatorInRegister(class_boilerplate);
// Create computed names and method values nodes to store into the literal.
for (int i = 0; i < expr->public_members()->length(); i++) {
ClassLiteral::Property* property = expr->public_members()->at(i);
if (property->is_computed_name()) {
Register key = register_allocator()->GrowRegisterList(&args);
builder()->SetExpressionAsStatementPosition(property->key());
BuildLoadPropertyKey(property, key);
if (property->is_static()) {
// The static prototype property is read only. We handle the non
// computed property name case in the parser. Since this is the only
// case where we need to check for an own read only property we
// special case this so we do not need to do this for every property.
FeedbackSlot slot = GetDummyCompareICSlot();
BytecodeLabel done;
builder()
->LoadLiteral(ast_string_constants()->prototype_string())
.CompareOperation(Token::Value::EQ_STRICT, key,
feedback_index(slot))
.JumpIfFalse(ToBooleanMode::kAlreadyBoolean, &done)
.CallRuntime(Runtime::kThrowStaticPrototypeError)
.Bind(&done);
}
if (property->kind() == ClassLiteral::Property::FIELD) {
DCHECK(!property->is_private());
// Initialize field's name variable with the computed name.
DCHECK_NOT_NULL(property->computed_name_var());
builder()->LoadAccumulatorWithRegister(key);
BuildVariableAssignment(property->computed_name_var(), Token::INIT,
HoleCheckMode::kElided);
}
}
DCHECK(!property->is_private());
if (property->kind() == ClassLiteral::Property::FIELD) {
// We don't compute field's value here, but instead do it in the
// initializer function.
continue;
}
Register value = register_allocator()->GrowRegisterList(&args);
VisitForRegisterValue(property->value(), value);
}
builder()->CallRuntime(Runtime::kDefineClass, args);
}
Register prototype = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(prototype);
// Assign to class variable.
Variable* class_variable = expr->scope()->class_variable();
if (class_variable != nullptr && class_variable->is_used()) {
DCHECK(class_variable->IsStackLocal() || class_variable->IsContextSlot());
builder()->LoadAccumulatorWithRegister(class_constructor);
BuildVariableAssignment(class_variable, Token::INIT,
HoleCheckMode::kElided);
}
// Create the closures of private methods, and store the home object for
// any private methods that need them.
if (expr->has_private_methods()) {
for (int i = 0; i < expr->private_members()->length(); i++) {
ClassLiteral::Property* property = expr->private_members()->at(i);
if (property->kind() != ClassLiteral::Property::METHOD) {
continue;
}
RegisterAllocationScope register_scope(this);
VisitForAccumulatorValue(property->value());
BuildVariableAssignment(property->private_name_var(), Token::INIT,
HoleCheckMode::kElided);
Register home_object = property->private_name_var()->is_static()
? class_constructor
: prototype;
if (property->NeedsHomeObjectOnClassPrototype()) {
Register func = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(func);
VisitSetHomeObject(func, home_object, property);
}
}
}
// Define private accessors, using only a single call to the runtime for
// each pair of corresponding getters and setters, in the order the first
// component is declared. Store the home objects if necessary.
for (auto accessors : private_accessors.ordered_accessors()) {
RegisterAllocationScope inner_register_scope(this);
RegisterList accessors_reg = register_allocator()->NewRegisterList(2);
ClassLiteral::Property* getter = accessors.second->getter;
ClassLiteral::Property* setter = accessors.second->setter;
bool is_static =
getter != nullptr ? getter->is_static() : setter->is_static();
Register home_object = is_static ? class_constructor : prototype;
VisitLiteralAccessor(home_object, getter, accessors_reg[0]);
VisitLiteralAccessor(home_object, setter, accessors_reg[1]);
builder()->CallRuntime(Runtime::kCreatePrivateAccessors, accessors_reg);
Variable* var = getter != nullptr ? getter->private_name_var()
: setter->private_name_var();
DCHECK_NOT_NULL(var);
BuildVariableAssignment(var, Token::INIT, HoleCheckMode::kElided);
}
if (expr->instance_members_initializer_function() != nullptr) {
Register initializer =
VisitForRegisterValue(expr->instance_members_initializer_function());
if (FunctionLiteral::NeedsHomeObject(
expr->instance_members_initializer_function())) {
FeedbackSlot slot = feedback_spec()->AddStoreICSlot(language_mode());
builder()->LoadAccumulatorWithRegister(prototype).StoreHomeObjectProperty(
initializer, feedback_index(slot), language_mode());
}
FeedbackSlot slot = feedback_spec()->AddStoreICSlot(language_mode());
builder()
->LoadAccumulatorWithRegister(initializer)
.StoreClassFieldsInitializer(class_constructor, feedback_index(slot))
.LoadAccumulatorWithRegister(class_constructor);
}
if (expr->static_fields_initializer() != nullptr) {
// TODO(gsathya): This can be optimized away to be a part of the
// class boilerplate in the future. The name argument can be
// passed to the DefineClass runtime function and have it set
// there.
if (name.is_valid()) {
Register key = register_allocator()->NewRegister();
builder()
->LoadLiteral(ast_string_constants()->name_string())
.StoreAccumulatorInRegister(key);
DataPropertyInLiteralFlags data_property_flags =
DataPropertyInLiteralFlag::kNoFlags;
FeedbackSlot slot =
feedback_spec()->AddStoreDataPropertyInLiteralICSlot();
builder()->LoadAccumulatorWithRegister(name).StoreDataPropertyInLiteral(
class_constructor, key, data_property_flags, feedback_index(slot));
}
RegisterList args = register_allocator()->NewRegisterList(1);
Register initializer =
VisitForRegisterValue(expr->static_fields_initializer());
if (FunctionLiteral::NeedsHomeObject(expr->static_fields_initializer())) {
FeedbackSlot slot = feedback_spec()->AddStoreICSlot(language_mode());
builder()
->LoadAccumulatorWithRegister(class_constructor)
.StoreHomeObjectProperty(initializer, feedback_index(slot),
language_mode());
}
builder()
->MoveRegister(class_constructor, args[0])
.CallProperty(initializer, args,
feedback_index(feedback_spec()->AddCallICSlot()));
}
builder()->LoadAccumulatorWithRegister(class_constructor);
}
void BytecodeGenerator::VisitClassLiteral(ClassLiteral* expr) {
VisitClassLiteral(expr, Register::invalid_value());
}
void BytecodeGenerator::VisitClassLiteral(ClassLiteral* expr, Register name) {
CurrentScope current_scope(this, expr->scope());
DCHECK_NOT_NULL(expr->scope());
if (expr->scope()->NeedsContext()) {
BuildNewLocalBlockContext(expr->scope());
ContextScope scope(this, expr->scope());
BuildClassLiteral(expr, name);
} else {
BuildClassLiteral(expr, name);
}
}
void BytecodeGenerator::VisitInitializeClassMembersStatement(
InitializeClassMembersStatement* stmt) {
RegisterList args = register_allocator()->NewRegisterList(3);
Register constructor = args[0], key = args[1], value = args[2];
builder()->MoveRegister(builder()->Receiver(), constructor);
for (int i = 0; i < stmt->fields()->length(); i++) {
ClassLiteral::Property* property = stmt->fields()->at(i);
// Private methods are not initialized in the
// InitializeClassMembersStatement.
DCHECK_IMPLIES(property->is_private(),
property->kind() == ClassLiteral::Property::FIELD);
if (property->is_computed_name()) {
DCHECK_EQ(property->kind(), ClassLiteral::Property::FIELD);
DCHECK(!property->is_private());
Variable* var = property->computed_name_var();
DCHECK_NOT_NULL(var);
// The computed name is already evaluated and stored in a
// variable at class definition time.
BuildVariableLoad(var, HoleCheckMode::kElided);
builder()->StoreAccumulatorInRegister(key);
} else if (property->is_private()) {
Variable* private_name_var = property->private_name_var();
DCHECK_NOT_NULL(private_name_var);
BuildVariableLoad(private_name_var, HoleCheckMode::kElided);
builder()->StoreAccumulatorInRegister(key);
} else {
BuildLoadPropertyKey(property, key);
}
builder()->SetExpressionAsStatementPosition(property->value());
VisitForRegisterValue(property->value(), value);
VisitSetHomeObject(value, constructor, property);
Runtime::FunctionId function_id =
property->kind() == ClassLiteral::Property::FIELD &&
!property->is_private()
? Runtime::kCreateDataProperty
: Runtime::kAddPrivateField;
builder()->CallRuntime(function_id, args);
}
}
void BytecodeGenerator::BuildInvalidPropertyAccess(MessageTemplate tmpl,
Property* property) {
RegisterAllocationScope register_scope(this);
const AstRawString* name = property->key()->AsVariableProxy()->raw_name();
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadLiteral(Smi::FromEnum(tmpl))
.StoreAccumulatorInRegister(args[0])
.LoadLiteral(name)
.StoreAccumulatorInRegister(args[1])
.CallRuntime(Runtime::kNewTypeError, args)
.Throw();
}
void BytecodeGenerator::BuildPrivateBrandInitialization(Register receiver) {
RegisterList brand_args = register_allocator()->NewRegisterList(3);
Variable* brand = info()->scope()->outer_scope()->AsClassScope()->brand();
int depth = execution_context()->ContextChainDepth(brand->scope());
ContextScope* class_context = execution_context()->Previous(depth);
BuildVariableLoad(brand, HoleCheckMode::kElided);
builder()
->StoreAccumulatorInRegister(brand_args[1])
.MoveRegister(receiver, brand_args[0])
.MoveRegister(class_context->reg(), brand_args[2])
.CallRuntime(Runtime::kAddPrivateBrand, brand_args);
}
void BytecodeGenerator::BuildInstanceMemberInitialization(Register constructor,
Register instance) {
RegisterList args = register_allocator()->NewRegisterList(1);
Register initializer = register_allocator()->NewRegister();
FeedbackSlot slot = feedback_spec()->AddLoadICSlot();
BytecodeLabel done;
builder()
->LoadClassFieldsInitializer(constructor, feedback_index(slot))
// TODO(gsathya): This jump can be elided for the base
// constructor and derived constructor. This is only required
// when called from an arrow function.
.JumpIfUndefined(&done)
.StoreAccumulatorInRegister(initializer)
.MoveRegister(instance, args[0])
.CallProperty(initializer, args,
feedback_index(feedback_spec()->AddCallICSlot()))
.Bind(&done);
}
void BytecodeGenerator::VisitNativeFunctionLiteral(
NativeFunctionLiteral* expr) {
size_t entry = builder()->AllocateDeferredConstantPoolEntry();
int index = feedback_spec()->AddCreateClosureSlot();
uint8_t flags = CreateClosureFlags::Encode(false, false, false);
builder()->CreateClosure(entry, index, flags);
native_function_literals_.push_back(std::make_pair(expr, entry));
}
void BytecodeGenerator::VisitConditional(Conditional* expr) {
ConditionalControlFlowBuilder conditional_builder(
builder(), block_coverage_builder_, expr);
if (expr->condition()->ToBooleanIsTrue()) {
// Generate then block unconditionally as always true.
conditional_builder.Then();
VisitForAccumulatorValue(expr->then_expression());
} else if (expr->condition()->ToBooleanIsFalse()) {
// Generate else block unconditionally if it exists.
conditional_builder.Else();
VisitForAccumulatorValue(expr->else_expression());
} else {
VisitForTest(expr->condition(), conditional_builder.then_labels(),
conditional_builder.else_labels(), TestFallthrough::kThen);
conditional_builder.Then();
VisitForAccumulatorValue(expr->then_expression());
conditional_builder.JumpToEnd();
conditional_builder.Else();
VisitForAccumulatorValue(expr->else_expression());
}
}
void BytecodeGenerator::VisitLiteral(Literal* expr) {
if (execution_result()->IsEffect()) return;
switch (expr->type()) {
case Literal::kSmi:
builder()->LoadLiteral(expr->AsSmiLiteral());
break;
case Literal::kHeapNumber:
builder()->LoadLiteral(expr->AsNumber());
break;
case Literal::kUndefined:
builder()->LoadUndefined();
break;
case Literal::kBoolean:
builder()->LoadBoolean(expr->ToBooleanIsTrue());
execution_result()->SetResultIsBoolean();
break;
case Literal::kNull:
builder()->LoadNull();
break;
case Literal::kTheHole:
builder()->LoadTheHole();
break;
case Literal::kString:
builder()->LoadLiteral(expr->AsRawString());
execution_result()->SetResultIsString();
break;
case Literal::kSymbol:
builder()->LoadLiteral(expr->AsSymbol());
break;
case Literal::kBigInt:
builder()->LoadLiteral(expr->AsBigInt());
break;
}
}
void BytecodeGenerator::VisitRegExpLiteral(RegExpLiteral* expr) {
// Materialize a regular expression literal.
builder()->CreateRegExpLiteral(
expr->raw_pattern(), feedback_index(feedback_spec()->AddLiteralSlot()),
expr->flags());
}
void BytecodeGenerator::BuildCreateObjectLiteral(Register literal,
uint8_t flags, size_t entry) {
if (ShouldOptimizeAsOneShot()) {
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadConstantPoolEntry(entry)
.StoreAccumulatorInRegister(args[0])
.LoadLiteral(Smi::FromInt(flags))
.StoreAccumulatorInRegister(args[1])
.CallRuntime(Runtime::kCreateObjectLiteralWithoutAllocationSite, args)
.StoreAccumulatorInRegister(literal);
} else {
// TODO(cbruni): Directly generate runtime call for literals we cannot
// optimize once the CreateShallowObjectLiteral stub is in sync with the TF
// optimizations.
int literal_index = feedback_index(feedback_spec()->AddLiteralSlot());
builder()
->CreateObjectLiteral(entry, literal_index, flags)
.StoreAccumulatorInRegister(literal);
}
}
void BytecodeGenerator::VisitObjectLiteral(ObjectLiteral* expr) {
expr->InitDepthAndFlags();
// Fast path for the empty object literal which doesn't need an
// AllocationSite.
if (expr->IsEmptyObjectLiteral()) {
DCHECK(expr->IsFastCloningSupported());
builder()->CreateEmptyObjectLiteral();
return;
}
// Deep-copy the literal boilerplate.
uint8_t flags = CreateObjectLiteralFlags::Encode(
expr->ComputeFlags(), expr->IsFastCloningSupported());
Register literal = register_allocator()->NewRegister();
// Create literal object.
int property_index = 0;
bool clone_object_spread =
expr->properties()->first()->kind() == ObjectLiteral::Property::SPREAD;
if (clone_object_spread) {
// Avoid the slow path for spreads in the following common cases:
// 1) `let obj = { ...source }`
// 2) `let obj = { ...source, override: 1 }`
// 3) `let obj = { ...source, ...overrides }`
RegisterAllocationScope register_scope(this);
Expression* property = expr->properties()->first()->value();
Register from_value = VisitForRegisterValue(property);
int clone_index = feedback_index(feedback_spec()->AddCloneObjectSlot());
builder()->CloneObject(from_value, flags, clone_index);
builder()->StoreAccumulatorInRegister(literal);
property_index++;
} else {
size_t entry;
// If constant properties is an empty fixed array, use a cached empty fixed
// array to ensure it's only added to the constant pool once.
if (expr->properties_count() == 0) {
entry = builder()->EmptyObjectBoilerplateDescriptionConstantPoolEntry();
} else {
entry = builder()->AllocateDeferredConstantPoolEntry();
object_literals_.push_back(std::make_pair(expr, entry));
}
BuildCreateObjectLiteral(literal, flags, entry);
}
// Store computed values into the literal.
AccessorTable<ObjectLiteral::Property> accessor_table(zone());
for (; property_index < expr->properties()->length(); property_index++) {
ObjectLiteral::Property* property = expr->properties()->at(property_index);
if (property->is_computed_name()) break;
if (!clone_object_spread && property->IsCompileTimeValue()) continue;
RegisterAllocationScope inner_register_scope(this);
Literal* key = property->key()->AsLiteral();
switch (property->kind()) {
case ObjectLiteral::Property::SPREAD:
UNREACHABLE();
case ObjectLiteral::Property::CONSTANT:
case ObjectLiteral::Property::MATERIALIZED_LITERAL:
DCHECK(clone_object_spread || !property->value()->IsCompileTimeValue());
V8_FALLTHROUGH;
case ObjectLiteral::Property::COMPUTED: {
// It is safe to use [[Put]] here because the boilerplate already
// contains computed properties with an uninitialized value.
if (key->IsStringLiteral()) {
DCHECK(key->IsPropertyName());
if (property->emit_store()) {
builder()->SetExpressionPosition(property->value());
VisitForAccumulatorValue(property->value());
FeedbackSlot slot = feedback_spec()->AddStoreOwnICSlot();
if (FunctionLiteral::NeedsHomeObject(property->value())) {
RegisterAllocationScope register_scope(this);
Register value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
builder()->StoreNamedOwnProperty(
literal, key->AsRawPropertyName(), feedback_index(slot));
VisitSetHomeObject(value, literal, property);
} else {
builder()->StoreNamedOwnProperty(
literal, key->AsRawPropertyName(), feedback_index(slot));
}
} else {
builder()->SetExpressionPosition(property->value());
VisitForEffect(property->value());
}
} else {
RegisterList args = register_allocator()->NewRegisterList(3);
builder()->MoveRegister(literal, args[0]);
builder()->SetExpressionPosition(property->key());
VisitForRegisterValue(property->key(), args[1]);
builder()->SetExpressionPosition(property->value());
VisitForRegisterValue(property->value(), args[2]);
if (property->emit_store()) {
builder()->CallRuntime(Runtime::kSetKeyedProperty, args);
Register value = args[2];
VisitSetHomeObject(value, literal, property);
}
}
break;
}
case ObjectLiteral::Property::PROTOTYPE: {
// __proto__:null is handled by CreateObjectLiteral.
if (property->IsNullPrototype()) break;
DCHECK(property->emit_store());
DCHECK(!property->NeedsSetFunctionName());
RegisterList args = register_allocator()->NewRegisterList(2);
builder()->MoveRegister(literal, args[0]);
builder()->SetExpressionPosition(property->value());
VisitForRegisterValue(property->value(), args[1]);
builder()->CallRuntime(Runtime::kInternalSetPrototype, args);
break;
}
case ObjectLiteral::Property::GETTER:
if (property->emit_store()) {
accessor_table.LookupOrInsert(key)->getter = property;
}
break;
case ObjectLiteral::Property::SETTER:
if (property->emit_store()) {
accessor_table.LookupOrInsert(key)->setter = property;
}
break;
}
}
// Define accessors, using only a single call to the runtime for each pair of
// corresponding getters and setters.
for (auto accessors : accessor_table.ordered_accessors()) {
RegisterAllocationScope inner_register_scope(this);
RegisterList args = register_allocator()->NewRegisterList(5);
builder()->MoveRegister(literal, args[0]);
VisitForRegisterValue(accessors.first, args[1]);
VisitLiteralAccessor(literal, accessors.second->getter, args[2]);
VisitLiteralAccessor(literal, accessors.second->setter, args[3]);
builder()
->LoadLiteral(Smi::FromInt(NONE))
.StoreAccumulatorInRegister(args[4])
.CallRuntime(Runtime::kDefineAccessorPropertyUnchecked, args);
}
// Object literals have two parts. The "static" part on the left contains no
// computed property names, and so we can compute its map ahead of time; see
// Runtime_CreateObjectLiteralBoilerplate. The second "dynamic" part starts
// with the first computed property name and continues with all properties to
// its right. All the code from above initializes the static component of the
// object literal, and arranges for the map of the result to reflect the
// static order in which the keys appear. For the dynamic properties, we
// compile them into a series of "SetOwnProperty" runtime calls. This will
// preserve insertion order.
for (; property_index < expr->properties()->length(); property_index++) {
ObjectLiteral::Property* property = expr->properties()->at(property_index);
RegisterAllocationScope inner_register_scope(this);
if (property->IsPrototype()) {
// __proto__:null is handled by CreateObjectLiteral.
if (property->IsNullPrototype()) continue;
DCHECK(property->emit_store());
DCHECK(!property->NeedsSetFunctionName());
RegisterList args = register_allocator()->NewRegisterList(2);
builder()->MoveRegister(literal, args[0]);
builder()->SetExpressionPosition(property->value());
VisitForRegisterValue(property->value(), args[1]);
builder()->CallRuntime(Runtime::kInternalSetPrototype, args);
continue;
}
switch (property->kind()) {
case ObjectLiteral::Property::CONSTANT:
case ObjectLiteral::Property::COMPUTED:
case ObjectLiteral::Property::MATERIALIZED_LITERAL: {
Register key = register_allocator()->NewRegister();
BuildLoadPropertyKey(property, key);
builder()->SetExpressionPosition(property->value());
Register value;
// Static class fields require the name property to be set on
// the class, meaning we can't wait until the
// StoreDataPropertyInLiteral call later to set the name.
if (property->value()->IsClassLiteral() &&
property->value()->AsClassLiteral()->static_fields_initializer() !=
nullptr) {
value = register_allocator()->NewRegister();
VisitClassLiteral(property->value()->AsClassLiteral(), key);
builder()->StoreAccumulatorInRegister(value);
} else {
value = VisitForRegisterValue(property->value());
}
VisitSetHomeObject(value, literal, property);
DataPropertyInLiteralFlags data_property_flags =
DataPropertyInLiteralFlag::kNoFlags;
if (property->NeedsSetFunctionName()) {
data_property_flags |= DataPropertyInLiteralFlag::kSetFunctionName;
}
FeedbackSlot slot =
feedback_spec()->AddStoreDataPropertyInLiteralICSlot();
builder()
->LoadAccumulatorWithRegister(value)
.StoreDataPropertyInLiteral(literal, key, data_property_flags,
feedback_index(slot));
break;
}
case ObjectLiteral::Property::GETTER:
case ObjectLiteral::Property::SETTER: {
RegisterList args = register_allocator()->NewRegisterList(4);
builder()->MoveRegister(literal, args[0]);
BuildLoadPropertyKey(property, args[1]);
builder()->SetExpressionPosition(property->value());
VisitForRegisterValue(property->value(), args[2]);
VisitSetHomeObject(args[2], literal, property);
builder()
->LoadLiteral(Smi::FromInt(NONE))
.StoreAccumulatorInRegister(args[3]);
Runtime::FunctionId function_id =
property->kind() == ObjectLiteral::Property::GETTER
? Runtime::kDefineGetterPropertyUnchecked
: Runtime::kDefineSetterPropertyUnchecked;
builder()->CallRuntime(function_id, args);
break;
}
case ObjectLiteral::Property::SPREAD: {
RegisterList args = register_allocator()->NewRegisterList(2);
builder()->MoveRegister(literal, args[0]);
builder()->SetExpressionPosition(property->value());
VisitForRegisterValue(property->value(), args[1]);
builder()->CallRuntime(Runtime::kInlineCopyDataProperties, args);
break;
}
case ObjectLiteral::Property::PROTOTYPE:
UNREACHABLE(); // Handled specially above.
break;
}
}
builder()->LoadAccumulatorWithRegister(literal);
}
// Fill an array with values from an iterator, starting at a given index. It is
// guaranteed that the loop will only terminate if the iterator is exhausted, or
// if one of iterator.next(), value.done, or value.value fail.
//
// In pseudocode:
//
// loop {
// value = iterator.next()
// if (value.done) break;
// value = value.value
// array[index++] = value
// }
void BytecodeGenerator::BuildFillArrayWithIterator(
IteratorRecord iterator, Register array, Register index, Register value,
FeedbackSlot next_value_slot, FeedbackSlot next_done_slot,
FeedbackSlot index_slot, FeedbackSlot element_slot) {
DCHECK(array.is_valid());
DCHECK(index.is_valid());
DCHECK(value.is_valid());
LoopBuilder loop_builder(builder(), nullptr, nullptr);
LoopScope loop_scope(this, &loop_builder);
// Call the iterator's .next() method. Break from the loop if the `done`
// property is truthy, otherwise load the value from the iterator result and
// append the argument.
BuildIteratorNext(iterator, value);
builder()->LoadNamedProperty(
value, ast_string_constants()->done_string(),
feedback_index(feedback_spec()->AddLoadICSlot()));
loop_builder.BreakIfTrue(ToBooleanMode::kConvertToBoolean);
loop_builder.LoopBody();
builder()
// value = value.value
->LoadNamedProperty(value, ast_string_constants()->value_string(),
feedback_index(next_value_slot))
// array[index] = value
.StoreInArrayLiteral(array, index, feedback_index(element_slot))
// index++
.LoadAccumulatorWithRegister(index)
.UnaryOperation(Token::INC, feedback_index(index_slot))
.StoreAccumulatorInRegister(index);
loop_builder.BindContinueTarget();
}
void BytecodeGenerator::BuildCreateArrayLiteral(
const ZonePtrList<Expression>* elements, ArrayLiteral* expr) {
RegisterAllocationScope register_scope(this);
Register index = register_allocator()->NewRegister();
Register array = register_allocator()->NewRegister();
SharedFeedbackSlot element_slot(feedback_spec(),
FeedbackSlotKind::kStoreInArrayLiteral);
ZonePtrList<Expression>::const_iterator current = elements->begin();
ZonePtrList<Expression>::const_iterator end = elements->end();
bool is_empty = elements->is_empty();
if (!is_empty && (*current)->IsSpread()) {
// If we have a leading spread, use CreateArrayFromIterable to create
// an array from it and then add the remaining components to that array.
VisitForAccumulatorValue(*current);
builder()->SetExpressionPosition((*current)->AsSpread()->expression());
builder()->CreateArrayFromIterable().StoreAccumulatorInRegister(array);
if (++current != end) {
// If there are remaning elements, prepare the index register that is
// used for adding those elements. The next index is the length of the
// newly created array.
auto length = ast_string_constants()->length_string();
int length_load_slot = feedback_index(feedback_spec()->AddLoadICSlot());
builder()
->LoadNamedProperty(array, length, length_load_slot)
.StoreAccumulatorInRegister(index);
}
} else if (expr != nullptr) {
// There are some elements before the first (if any) spread, and we can
// use a boilerplate when creating the initial array from those elements.
// First, allocate a constant pool entry for the boilerplate that will
// be created during finalization, and will contain all the constant
// elements before the first spread. This also handle the empty array case
// and one-shot optimization.
uint8_t flags = CreateArrayLiteralFlags::Encode(
expr->IsFastCloningSupported(), expr->ComputeFlags());
bool optimize_as_one_shot = ShouldOptimizeAsOneShot();
size_t entry;
if (is_empty && optimize_as_one_shot) {
entry = builder()->EmptyArrayBoilerplateDescriptionConstantPoolEntry();
} else if (!is_empty) {
entry = builder()->AllocateDeferredConstantPoolEntry();
array_literals_.push_back(std::make_pair(expr, entry));
}
if (optimize_as_one_shot) {
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadConstantPoolEntry(entry)
.StoreAccumulatorInRegister(args[0])
.LoadLiteral(Smi::FromInt(flags))
.StoreAccumulatorInRegister(args[1])
.CallRuntime(Runtime::kCreateArrayLiteralWithoutAllocationSite, args);
} else if (is_empty) {
// Empty array literal fast-path.
int literal_index = feedback_index(feedback_spec()->AddLiteralSlot());
DCHECK(expr->IsFastCloningSupported());
builder()->CreateEmptyArrayLiteral(literal_index);
} else {
// Create array literal from boilerplate.
int literal_index = feedback_index(feedback_spec()->AddLiteralSlot());
builder()->CreateArrayLiteral(entry, literal_index, flags);
}
builder()->StoreAccumulatorInRegister(array);
// Insert the missing non-constant elements, up until the first spread
// index, into the initial array (the remaining elements will be inserted
// below).
DCHECK_EQ(current, elements->begin());
ZonePtrList<Expression>::const_iterator first_spread_or_end =
expr->first_spread_index() >= 0 ? current + expr->first_spread_index()
: end;
int array_index = 0;
for (; current != first_spread_or_end; ++current, array_index++) {
Expression* subexpr = *current;
DCHECK(!subexpr->IsSpread());
// Skip the constants.
if (subexpr->IsCompileTimeValue()) continue;
builder()
->LoadLiteral(Smi::FromInt(array_index))
.StoreAccumulatorInRegister(index);
VisitForAccumulatorValue(subexpr);
builder()->StoreInArrayLiteral(array, index,
feedback_index(element_slot.Get()));
}
if (current != end) {
// If there are remaining elements, prepare the index register
// to store the next element, which comes from the first spread.
builder()->LoadLiteral(array_index).StoreAccumulatorInRegister(index);
}
} else {
// In other cases, we prepare an empty array to be filled in below.
DCHECK(!elements->is_empty());
int literal_index = feedback_index(feedback_spec()->AddLiteralSlot());
builder()
->CreateEmptyArrayLiteral(literal_index)
.StoreAccumulatorInRegister(array);
// Prepare the index for the first element.
builder()->LoadLiteral(Smi::FromInt(0)).StoreAccumulatorInRegister(index);
}
// Now build insertions for the remaining elements from current to end.
SharedFeedbackSlot index_slot(feedback_spec(), FeedbackSlotKind::kBinaryOp);
SharedFeedbackSlot length_slot(
feedback_spec(), feedback_spec()->GetStoreICSlot(LanguageMode::kStrict));
for (; current != end; ++current) {
Expression* subexpr = *current;
if (subexpr->IsSpread()) {
RegisterAllocationScope scope(this);
builder()->SetExpressionAsStatementPosition(
subexpr->AsSpread()->expression());
VisitForAccumulatorValue(subexpr->AsSpread()->expression());
builder()->SetExpressionPosition(subexpr->AsSpread()->expression());
IteratorRecord iterator = BuildGetIteratorRecord(IteratorType::kNormal);
Register value = register_allocator()->NewRegister();
FeedbackSlot next_value_load_slot = feedback_spec()->AddLoadICSlot();
FeedbackSlot next_done_load_slot = feedback_spec()->AddLoadICSlot();
FeedbackSlot real_index_slot = index_slot.Get();
FeedbackSlot real_element_slot = element_slot.Get();
BuildFillArrayWithIterator(iterator, array, index, value,
next_value_load_slot, next_done_load_slot,
real_index_slot, real_element_slot);
} else if (!subexpr->IsTheHoleLiteral()) {
// literal[index++] = subexpr
VisitForAccumulatorValue(subexpr);
builder()
->StoreInArrayLiteral(array, index,
feedback_index(element_slot.Get()))
.LoadAccumulatorWithRegister(index);
// Only increase the index if we are not the last element.
if (current + 1 != end) {
builder()
->UnaryOperation(Token::INC, feedback_index(index_slot.Get()))
.StoreAccumulatorInRegister(index);
}
} else {
// literal.length = ++index
// length_slot is only used when there are holes.
auto length = ast_string_constants()->length_string();
builder()
->LoadAccumulatorWithRegister(index)
.UnaryOperation(Token::INC, feedback_index(index_slot.Get()))
.StoreAccumulatorInRegister(index)
.StoreNamedProperty(array, length, feedback_index(length_slot.Get()),
LanguageMode::kStrict);
}
}
builder()->LoadAccumulatorWithRegister(array);
}
void BytecodeGenerator::VisitArrayLiteral(ArrayLiteral* expr) {
expr->InitDepthAndFlags();
BuildCreateArrayLiteral(expr->values(), expr);
}
void BytecodeGenerator::VisitVariableProxy(VariableProxy* proxy) {
builder()->SetExpressionPosition(proxy);
BuildVariableLoad(proxy->var(), proxy->hole_check_mode());
}
void BytecodeGenerator::BuildVariableLoad(Variable* variable,
HoleCheckMode hole_check_mode,
TypeofMode typeof_mode) {
switch (variable->location()) {
case VariableLocation::LOCAL: {
Register source(builder()->Local(variable->index()));
// We need to load the variable into the accumulator, even when in a
// VisitForRegisterScope, in order to avoid register aliasing if
// subsequent expressions assign to the same variable.
builder()->LoadAccumulatorWithRegister(source);
if (hole_check_mode == HoleCheckMode::kRequired) {
BuildThrowIfHole(variable);
}
break;
}
case VariableLocation::PARAMETER: {
Register source;
if (variable->IsReceiver()) {
source = builder()->Receiver();
} else {
source = builder()->Parameter(variable->index());
}
// We need to load the variable into the accumulator, even when in a
// VisitForRegisterScope, in order to avoid register aliasing if
// subsequent expressions assign to the same variable.
builder()->LoadAccumulatorWithRegister(source);
if (hole_check_mode == HoleCheckMode::kRequired) {
BuildThrowIfHole(variable);
}
break;
}
case VariableLocation::UNALLOCATED: {
// The global identifier "undefined" is immutable. Everything
// else could be reassigned. For performance, we do a pointer comparison
// rather than checking if the raw_name is really "undefined".
if (variable->raw_name() == ast_string_constants()->undefined_string()) {
builder()->LoadUndefined();
} else {
FeedbackSlot slot = GetCachedLoadGlobalICSlot(typeof_mode, variable);
builder()->LoadGlobal(variable->raw_name(), feedback_index(slot),
typeof_mode);
}
break;
}
case VariableLocation::CONTEXT: {
int depth = execution_context()->ContextChainDepth(variable->scope());
ContextScope* context = execution_context()->Previous(depth);
Register context_reg;
if (context) {
context_reg = context->reg();
depth = 0;
} else {
context_reg = execution_context()->reg();
}
BytecodeArrayBuilder::ContextSlotMutability immutable =
(variable->maybe_assigned() == kNotAssigned)
? BytecodeArrayBuilder::kImmutableSlot
: BytecodeArrayBuilder::kMutableSlot;
builder()->LoadContextSlot(context_reg, variable->index(), depth,
immutable);
if (hole_check_mode == HoleCheckMode::kRequired) {
BuildThrowIfHole(variable);
}
break;
}
case VariableLocation::LOOKUP: {
switch (variable->mode()) {
case VariableMode::kDynamicLocal: {
Variable* local_variable = variable->local_if_not_shadowed();
int depth =
execution_context()->ContextChainDepth(local_variable->scope());
builder()->LoadLookupContextSlot(variable->raw_name(), typeof_mode,
local_variable->index(), depth);
if (hole_check_mode == HoleCheckMode::kRequired) {
BuildThrowIfHole(variable);
}
break;
}
case VariableMode::kDynamicGlobal: {
int depth =
current_scope()->ContextChainLengthUntilOutermostSloppyEval();
// TODO(1008414): Add back caching here when bug is fixed properly.
FeedbackSlot slot = feedback_spec()->AddLoadGlobalICSlot(typeof_mode);
builder()->LoadLookupGlobalSlot(variable->raw_name(), typeof_mode,
feedback_index(slot), depth);
break;
}
default:
builder()->LoadLookupSlot(variable->raw_name(), typeof_mode);
}
break;
}
case VariableLocation::MODULE: {
int depth = execution_context()->ContextChainDepth(variable->scope());
builder()->LoadModuleVariable(variable->index(), depth);
if (hole_check_mode == HoleCheckMode::kRequired) {
BuildThrowIfHole(variable);
}
break;
}
case VariableLocation::REPL_GLOBAL: {
DCHECK(variable->IsReplGlobalLet());
FeedbackSlot slot = GetCachedLoadGlobalICSlot(typeof_mode, variable);
builder()->LoadGlobal(variable->raw_name(), feedback_index(slot),
typeof_mode);
break;
}
}
}
void BytecodeGenerator::BuildVariableLoadForAccumulatorValue(
Variable* variable, HoleCheckMode hole_check_mode, TypeofMode typeof_mode) {
ValueResultScope accumulator_result(this);
BuildVariableLoad(variable, hole_check_mode, typeof_mode);
}
void BytecodeGenerator::BuildReturn(int source_position) {
if (FLAG_trace) {
RegisterAllocationScope register_scope(this);
Register result = register_allocator()->NewRegister();
// Runtime returns {result} value, preserving accumulator.
builder()->StoreAccumulatorInRegister(result).CallRuntime(
Runtime::kTraceExit, result);
}
if (info()->flags().collect_type_profile()) {
builder()->CollectTypeProfile(info()->literal()->return_position());
}
builder()->SetReturnPosition(source_position, info()->literal());
builder()->Return();
}
void BytecodeGenerator::BuildAsyncReturn(int source_position) {
RegisterAllocationScope register_scope(this);
if (IsAsyncGeneratorFunction(info()->literal()->kind())) {
RegisterList args = register_allocator()->NewRegisterList(3);
builder()
->MoveRegister(generator_object(), args[0]) // generator
.StoreAccumulatorInRegister(args[1]) // value
.LoadTrue()
.StoreAccumulatorInRegister(args[2]) // done
.CallRuntime(Runtime::kInlineAsyncGeneratorResolve, args);
} else {
DCHECK(IsAsyncFunction(info()->literal()->kind()) ||
IsAsyncModule(info()->literal()->kind()));
RegisterList args = register_allocator()->NewRegisterList(3);
builder()
->MoveRegister(generator_object(), args[0]) // generator
.StoreAccumulatorInRegister(args[1]) // value
.LoadBoolean(info()->literal()->CanSuspend())
.StoreAccumulatorInRegister(args[2]) // can_suspend
.CallRuntime(Runtime::kInlineAsyncFunctionResolve, args);
}
BuildReturn(source_position);
}
void BytecodeGenerator::BuildReThrow() { builder()->ReThrow(); }
void BytecodeGenerator::BuildThrowIfHole(Variable* variable) {
if (variable->is_this()) {
DCHECK(variable->mode() == VariableMode::kConst);
builder()->ThrowSuperNotCalledIfHole();
} else {
builder()->ThrowReferenceErrorIfHole(variable->raw_name());
}
}
void BytecodeGenerator::BuildHoleCheckForVariableAssignment(Variable* variable,
Token::Value op) {
DCHECK(!IsPrivateMethodOrAccessorVariableMode(variable->mode()));
if (variable->is_this() && variable->mode() == VariableMode::kConst &&
op == Token::INIT) {
// Perform an initialization check for 'this'. 'this' variable is the
// only variable able to trigger bind operations outside the TDZ
// via 'super' calls.
builder()->ThrowSuperAlreadyCalledIfNotHole();
} else {
// Perform an initialization check for let/const declared variables.
// E.g. let x = (x = 20); is not allowed.
DCHECK(IsLexicalVariableMode(variable->mode()));
BuildThrowIfHole(variable);
}
}
void BytecodeGenerator::BuildVariableAssignment(
Variable* variable, Token::Value op, HoleCheckMode hole_check_mode,
LookupHoistingMode lookup_hoisting_mode) {
VariableMode mode = variable->mode();
RegisterAllocationScope assignment_register_scope(this);
BytecodeLabel end_label;
switch (variable->location()) {
case VariableLocation::PARAMETER:
case VariableLocation::LOCAL: {
Register destination;
if (VariableLocation::PARAMETER == variable->location()) {
if (variable->IsReceiver()) {
destination = builder()->Receiver();
} else {
destination = builder()->Parameter(variable->index());
}
} else {
destination = builder()->Local(variable->index());
}
if (hole_check_mode == HoleCheckMode::kRequired) {
// Load destination to check for hole.
Register value_temp = register_allocator()->NewRegister();
builder()
->StoreAccumulatorInRegister(value_temp)
.LoadAccumulatorWithRegister(destination);
BuildHoleCheckForVariableAssignment(variable, op);
builder()->LoadAccumulatorWithRegister(value_temp);
}
if (mode != VariableMode::kConst || op == Token::INIT) {
builder()->StoreAccumulatorInRegister(destination);
} else if (variable->throw_on_const_assignment(language_mode())) {
builder()->CallRuntime(Runtime::kThrowConstAssignError);
}
break;
}
case VariableLocation::UNALLOCATED: {
FeedbackSlot slot = GetCachedStoreGlobalICSlot(language_mode(), variable);
builder()->StoreGlobal(variable->raw_name(), feedback_index(slot));
break;
}
case VariableLocation::CONTEXT: {
int depth = execution_context()->ContextChainDepth(variable->scope());
ContextScope* context = execution_context()->Previous(depth);
Register context_reg;
if (context) {
context_reg = context->reg();
depth = 0;
} else {
context_reg = execution_context()->reg();
}
if (hole_check_mode == HoleCheckMode::kRequired) {
// Load destination to check for hole.
Register value_temp = register_allocator()->NewRegister();
builder()
->StoreAccumulatorInRegister(value_temp)
.LoadContextSlot(context_reg, variable->index(), depth,
BytecodeArrayBuilder::kMutableSlot);
BuildHoleCheckForVariableAssignment(variable, op);
builder()->LoadAccumulatorWithRegister(value_temp);
}
if (mode != VariableMode::kConst || op == Token::INIT) {
builder()->StoreContextSlot(context_reg, variable->index(), depth);
} else if (variable->throw_on_const_assignment(language_mode())) {
builder()->CallRuntime(Runtime::kThrowConstAssignError);
}
break;
}
case VariableLocation::LOOKUP: {
builder()->StoreLookupSlot(variable->raw_name(), language_mode(),
lookup_hoisting_mode);
break;
}
case VariableLocation::MODULE: {
DCHECK(IsDeclaredVariableMode(mode));
if (mode == VariableMode::kConst && op != Token::INIT) {
builder()->CallRuntime(Runtime::kThrowConstAssignError);
break;
}
// If we don't throw above, we know that we're dealing with an
// export because imports are const and we do not generate initializing
// assignments for them.
DCHECK(variable->IsExport());
int depth = execution_context()->ContextChainDepth(variable->scope());
if (hole_check_mode == HoleCheckMode::kRequired) {
Register value_temp = register_allocator()->NewRegister();
builder()
->StoreAccumulatorInRegister(value_temp)
.LoadModuleVariable(variable->index(), depth);
BuildHoleCheckForVariableAssignment(variable, op);
builder()->LoadAccumulatorWithRegister(value_temp);
}
builder()->StoreModuleVariable(variable->index(), depth);
break;
}
case VariableLocation::REPL_GLOBAL: {
// A let declaration like 'let x = 7' is effectively translated to:
// <top of the script>:
// ScriptContext.x = TheHole;
// ...
// <where the actual 'let' is>:
// ScriptContextTable.x = 7; // no hole check
//
// The ScriptContext slot for 'x' that we store to here is not
// necessarily the ScriptContext of this script, but rather the
// first ScriptContext that has a slot for name 'x'.
DCHECK(variable->IsReplGlobalLet());
if (op == Token::INIT) {
RegisterList store_args = register_allocator()->NewRegisterList(2);
builder()
->StoreAccumulatorInRegister(store_args[1])
.LoadLiteral(variable->raw_name())
.StoreAccumulatorInRegister(store_args[0]);
builder()->CallRuntime(Runtime::kStoreGlobalNoHoleCheckForReplLet,
store_args);
} else {
FeedbackSlot slot =
GetCachedStoreGlobalICSlot(language_mode(), variable);
builder()->StoreGlobal(variable->raw_name(), feedback_index(slot));
}
break;
}
}
}
void BytecodeGenerator::BuildLoadNamedProperty(const Expression* object_expr,
Register object,
const AstRawString* name) {
if (ShouldOptimizeAsOneShot()) {
builder()->LoadNamedPropertyNoFeedback(object, name);
} else {
FeedbackSlot slot = GetCachedLoadICSlot(object_expr, name);
builder()->LoadNamedProperty(object, name, feedback_index(slot));
}
}
void BytecodeGenerator::BuildStoreNamedProperty(const Expression* object_expr,
Register object,
const AstRawString* name) {
Register value;
if (!execution_result()->IsEffect()) {
value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
}
if (ShouldOptimizeAsOneShot()) {
builder()->StoreNamedPropertyNoFeedback(object, name, language_mode());
} else {
FeedbackSlot slot = GetCachedStoreICSlot(object_expr, name);
builder()->StoreNamedProperty(object, name, feedback_index(slot),
language_mode());
}
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::NonProperty(Expression* expr) {
return AssignmentLhsData(NON_PROPERTY, expr, RegisterList(), Register(),
Register(), nullptr, nullptr);
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::NamedProperty(Expression* object_expr,
Register object,
const AstRawString* name) {
return AssignmentLhsData(NAMED_PROPERTY, nullptr, RegisterList(), object,
Register(), object_expr, name);
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::KeyedProperty(Register object,
Register key) {
return AssignmentLhsData(KEYED_PROPERTY, nullptr, RegisterList(), object, key,
nullptr, nullptr);
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::NamedSuperProperty(
RegisterList super_property_args) {
return AssignmentLhsData(NAMED_SUPER_PROPERTY, nullptr, super_property_args,
Register(), Register(), nullptr, nullptr);
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::PrivateMethodOrAccessor(
AssignType type, Property* property) {
return AssignmentLhsData(type, property, RegisterList(), Register(),
Register(), nullptr, nullptr);
}
// static
BytecodeGenerator::AssignmentLhsData
BytecodeGenerator::AssignmentLhsData::KeyedSuperProperty(
RegisterList super_property_args) {
return AssignmentLhsData(KEYED_SUPER_PROPERTY, nullptr, super_property_args,
Register(), Register(), nullptr, nullptr);
}
BytecodeGenerator::AssignmentLhsData BytecodeGenerator::PrepareAssignmentLhs(
Expression* lhs, AccumulatorPreservingMode accumulator_preserving_mode) {
// Left-hand side can only be a property, a global or a variable slot.
Property* property = lhs->AsProperty();
AssignType assign_type = Property::GetAssignType(property);
// Evaluate LHS expression.
switch (assign_type) {
case NON_PROPERTY:
return AssignmentLhsData::NonProperty(lhs);
case NAMED_PROPERTY: {
AccumulatorPreservingScope scope(this, accumulator_preserving_mode);
Register object = VisitForRegisterValue(property->obj());
const AstRawString* name =
property->key()->AsLiteral()->AsRawPropertyName();
return AssignmentLhsData::NamedProperty(property->obj(), object, name);
}
case KEYED_PROPERTY: {
AccumulatorPreservingScope scope(this, accumulator_preserving_mode);
Register object = VisitForRegisterValue(property->obj());
Register key = VisitForRegisterValue(property->key());
return AssignmentLhsData::KeyedProperty(object, key);
}
case PRIVATE_METHOD:
case PRIVATE_GETTER_ONLY:
case PRIVATE_SETTER_ONLY:
case PRIVATE_GETTER_AND_SETTER: {
DCHECK(!property->IsSuperAccess());
return AssignmentLhsData::PrivateMethodOrAccessor(assign_type, property);
}
case NAMED_SUPER_PROPERTY: {
AccumulatorPreservingScope scope(this, accumulator_preserving_mode);
RegisterList super_property_args =
register_allocator()->NewRegisterList(4);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(super_property_args[0]);
VisitForRegisterValue(super_property->home_object(),
super_property_args[1]);
builder()
->LoadLiteral(property->key()->AsLiteral()->AsRawPropertyName())
.StoreAccumulatorInRegister(super_property_args[2]);
return AssignmentLhsData::NamedSuperProperty(super_property_args);
}
case KEYED_SUPER_PROPERTY: {
AccumulatorPreservingScope scope(this, accumulator_preserving_mode);
RegisterList super_property_args =
register_allocator()->NewRegisterList(4);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(super_property_args[0]);
VisitForRegisterValue(super_property->home_object(),
super_property_args[1]);
VisitForRegisterValue(property->key(), super_property_args[2]);
return AssignmentLhsData::KeyedSuperProperty(super_property_args);
}
}
UNREACHABLE();
}
// Build the iteration finalizer called in the finally block of an iteration
// protocol execution. This closes the iterator if needed, and suppresses any
// exception it throws if necessary, including the exception when the return
// method is not callable.
//
// In pseudo-code, this builds:
//
// if (!done) {
// try {
// let method = iterator.return
// if (method !== null && method !== undefined) {
// let return_val = method.call(iterator)
// if (!%IsObject(return_val)) throw TypeError
// }
// } catch (e) {
// if (iteration_continuation != RETHROW)
// rethrow e
// }
// }
//
// For async iterators, iterator.close() becomes await iterator.close().
void BytecodeGenerator::BuildFinalizeIteration(
IteratorRecord iterator, Register done,
Register iteration_continuation_token) {
RegisterAllocationScope register_scope(this);
BytecodeLabels iterator_is_done(zone());
// if (!done) {
builder()->LoadAccumulatorWithRegister(done).JumpIfTrue(
ToBooleanMode::kConvertToBoolean, iterator_is_done.New());
{
RegisterAllocationScope register_scope(this);
BuildTryCatch(
// try {
// let method = iterator.return
// if (method !== null && method !== undefined) {
// let return_val = method.call(iterator)
// if (!%IsObject(return_val)) throw TypeError
// }
// }
[&]() {
Register method = register_allocator()->NewRegister();
builder()
->LoadNamedProperty(
iterator.object(), ast_string_constants()->return_string(),
feedback_index(feedback_spec()->AddLoadICSlot()))
.JumpIfUndefinedOrNull(iterator_is_done.New())
.StoreAccumulatorInRegister(method);
RegisterList args(iterator.object());
builder()->CallProperty(
method, args, feedback_index(feedback_spec()->AddCallICSlot()));
if (iterator.type() == IteratorType::kAsync) {
BuildAwait();
}
builder()->JumpIfJSReceiver(iterator_is_done.New());
{
// Throw this exception inside the try block so that it is
// suppressed by the iteration continuation if necessary.
RegisterAllocationScope register_scope(this);
Register return_result = register_allocator()->NewRegister();
builder()
->StoreAccumulatorInRegister(return_result)
.CallRuntime(Runtime::kThrowIteratorResultNotAnObject,
return_result);
}
},
// catch (e) {
// if (iteration_continuation != RETHROW)
// rethrow e
// }
[&](Register context) {
// Reuse context register to store the exception.
Register close_exception = context;
builder()->StoreAccumulatorInRegister(close_exception);
BytecodeLabel suppress_close_exception;
builder()
->LoadLiteral(
Smi::FromInt(ControlScope::DeferredCommands::kRethrowToken))
.CompareReference(iteration_continuation_token)
.JumpIfTrue(ToBooleanMode::kAlreadyBoolean,
&suppress_close_exception)
.LoadAccumulatorWithRegister(close_exception)
.ReThrow()
.Bind(&suppress_close_exception);
},
HandlerTable::UNCAUGHT);
}
iterator_is_done.Bind(builder());
}
// Get the default value of a destructuring target. Will mutate the
// destructuring target expression if there is a default value.
//
// For
// a = b
// in
// let {a = b} = c
// returns b and mutates the input into a.
Expression* BytecodeGenerator::GetDestructuringDefaultValue(
Expression** target) {
Expression* default_value = nullptr;
if ((*target)->IsAssignment()) {
Assignment* default_init = (*target)->AsAssignment();
DCHECK_EQ(default_init->op(), Token::ASSIGN);
default_value = default_init->value();
*target = default_init->target();
DCHECK((*target)->IsValidReferenceExpression() || (*target)->IsPattern());
}
return default_value;
}
// Convert a destructuring assignment to an array literal into a sequence of
// iterator accesses into the value being assigned (in the accumulator).
//
// [a().x, ...b] = accumulator
//
// becomes
//
// iterator = %GetIterator(accumulator)
// try {
//
// // Individual assignments read off the value from iterator.next() This gets
// // repeated per destructuring element.
// if (!done) {
// // Make sure we are considered 'done' if .next(), .done or .value fail.
// done = true
// var next_result = iterator.next()
// var tmp_done = next_result.done
// if (!tmp_done) {
// value = next_result.value
// done = false
// }
// }
// if (done)
// value = undefined
// a().x = value
//
// // A spread receives the remaining items in the iterator.
// var array = []
// var index = 0
// %FillArrayWithIterator(iterator, array, index, done)
// done = true
// b = array
//
// } catch(e) {
// iteration_continuation = RETHROW
// } finally {
// %FinalizeIteration(iterator, done, iteration_continuation)
// }
void BytecodeGenerator::BuildDestructuringArrayAssignment(
ArrayLiteral* pattern, Token::Value op,
LookupHoistingMode lookup_hoisting_mode) {
RegisterAllocationScope scope(this);
Register value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
// Store the iterator in a dedicated register so that it can be closed on
// exit, and the 'done' value in a dedicated register so that it can be
// changed and accessed independently of the iteration result.
IteratorRecord iterator = BuildGetIteratorRecord(IteratorType::kNormal);
Register done = register_allocator()->NewRegister();
builder()->LoadFalse();
builder()->StoreAccumulatorInRegister(done);
BuildTryFinally(
// Try block.
[&]() {
Register next_result = register_allocator()->NewRegister();
FeedbackSlot next_value_load_slot = feedback_spec()->AddLoadICSlot();
FeedbackSlot next_done_load_slot = feedback_spec()->AddLoadICSlot();
Spread* spread = nullptr;
for (Expression* target : *pattern->values()) {
if (target->IsSpread()) {
spread = target->AsSpread();
break;
}
Expression* default_value = GetDestructuringDefaultValue(&target);
if (!target->IsPattern()) {
builder()->SetExpressionAsStatementPosition(target);
}
AssignmentLhsData lhs_data = PrepareAssignmentLhs(target);
// if (!done) {
// // Make sure we are considered done if .next(), .done or .value
// // fail.
// done = true
// var next_result = iterator.next()
// var tmp_done = next_result.done
// if (!tmp_done) {
// value = next_result.value
// done = false
// }
// }
// if (done)
// value = undefined
BytecodeLabels is_done(zone());
builder()->LoadAccumulatorWithRegister(done);
builder()->JumpIfTrue(ToBooleanMode::kConvertToBoolean,
is_done.New());
builder()->LoadTrue().StoreAccumulatorInRegister(done);
BuildIteratorNext(iterator, next_result);
builder()
->LoadNamedProperty(next_result,
ast_string_constants()->done_string(),
feedback_index(next_done_load_slot))
.JumpIfTrue(ToBooleanMode::kConvertToBoolean, is_done.New())
.LoadNamedProperty(next_result,
ast_string_constants()->value_string(),
feedback_index(next_value_load_slot))
.StoreAccumulatorInRegister(next_result)
.LoadFalse()
.StoreAccumulatorInRegister(done)
.LoadAccumulatorWithRegister(next_result);
// Only do the assignment if this is not a hole (i.e. 'elided').
if (!target->IsTheHoleLiteral()) {
// [<pattern> = <init>] = <value>
// becomes (roughly)
// temp = <value>.next();
// <pattern> = temp === undefined ? <init> : temp;
BytecodeLabel do_assignment;
if (default_value) {
builder()->JumpIfNotUndefined(&do_assignment);
// Since done == true => temp == undefined, jump directly to using
// the default value for that case.
is_done.Bind(builder());
VisitForAccumulatorValue(default_value);
} else {
builder()->Jump(&do_assignment);
is_done.Bind(builder());
builder()->LoadUndefined();
}
builder()->Bind(&do_assignment);
BuildAssignment(lhs_data, op, lookup_hoisting_mode);
} else {
DCHECK_EQ(lhs_data.assign_type(), NON_PROPERTY);
is_done.Bind(builder());
}
}
if (spread) {
RegisterAllocationScope scope(this);
BytecodeLabel is_done;
// A spread is turned into a loop over the remainer of the iterator.
Expression* target = spread->expression();
if (!target->IsPattern()) {
builder()->SetExpressionAsStatementPosition(spread);
}
AssignmentLhsData lhs_data = PrepareAssignmentLhs(target);
// var array = [];
Register array = register_allocator()->NewRegister();
builder()->CreateEmptyArrayLiteral(
feedback_index(feedback_spec()->AddLiteralSlot()));
builder()->StoreAccumulatorInRegister(array);
// If done, jump to assigning empty array
builder()->LoadAccumulatorWithRegister(done);
builder()->JumpIfTrue(ToBooleanMode::kConvertToBoolean, &is_done);
// var index = 0;
Register index = register_allocator()->NewRegister();
builder()->LoadLiteral(Smi::zero());
builder()->StoreAccumulatorInRegister(index);
// Set done to true, since it's guaranteed to be true by the time the
// array fill completes.
builder()->LoadTrue().StoreAccumulatorInRegister(done);
// Fill the array with the iterator.
FeedbackSlot element_slot =
feedback_spec()->AddStoreInArrayLiteralICSlot();
FeedbackSlot index_slot = feedback_spec()->AddBinaryOpICSlot();
BuildFillArrayWithIterator(iterator, array, index, next_result,
next_value_load_slot, next_done_load_slot,
index_slot, element_slot);
builder()->Bind(&is_done);
// Assign the array to the LHS.
builder()->LoadAccumulatorWithRegister(array);
BuildAssignment(lhs_data, op, lookup_hoisting_mode);
}
},
// Finally block.
[&](Register iteration_continuation_token) {
// Finish the iteration in the finally block.
BuildFinalizeIteration(iterator, done, iteration_continuation_token);
},
HandlerTable::UNCAUGHT);
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
}
// Convert a destructuring assignment to an object literal into a sequence of
// property accesses into the value being assigned (in the accumulator).
//
// { y, [x++]: a(), ...b.c } = value
//
// becomes
//
// var rest_runtime_callargs = new Array(3);
// rest_runtime_callargs[0] = value;
//
// rest_runtime_callargs[1] = value;
// y = value.y;
//
// var temp1 = %ToName(x++);
// rest_runtime_callargs[2] = temp1;
// a() = value[temp1];
//
// b.c = %CopyDataPropertiesWithExcludedProperties.call(rest_runtime_callargs);
void BytecodeGenerator::BuildDestructuringObjectAssignment(
ObjectLiteral* pattern, Token::Value op,
LookupHoistingMode lookup_hoisting_mode) {
RegisterAllocationScope scope(this);
// Store the assignment value in a register.
Register value;
RegisterList rest_runtime_callargs;
if (pattern->has_rest_property()) {
rest_runtime_callargs =
register_allocator()->NewRegisterList(pattern->properties()->length());
value = rest_runtime_callargs[0];
} else {
value = register_allocator()->NewRegister();
}
builder()->StoreAccumulatorInRegister(value);
// if (value === null || value === undefined)
// throw new TypeError(kNonCoercible);
//
// Since the first property access on null/undefined will also trigger a
// TypeError, we can elide this check. The exception is when there are no
// properties and no rest property (this is an empty literal), or when the
// first property is a computed name and accessing it can have side effects.
//
// TODO(leszeks): Also eliminate this check if the value is known to be
// non-null (e.g. an object literal).
if (pattern->properties()->is_empty() ||
(pattern->properties()->at(0)->is_computed_name() &&
pattern->properties()->at(0)->kind() != ObjectLiteralProperty::SPREAD)) {
BytecodeLabel is_null_or_undefined, not_null_or_undefined;
builder()
->JumpIfUndefinedOrNull(&is_null_or_undefined)
.Jump(&not_null_or_undefined);
{
builder()->Bind(&is_null_or_undefined);
builder()->SetExpressionPosition(pattern);
builder()->CallRuntime(Runtime::kThrowPatternAssignmentNonCoercible,
value);
}
builder()->Bind(&not_null_or_undefined);
}
int i = 0;
for (ObjectLiteralProperty* pattern_property : *pattern->properties()) {
RegisterAllocationScope scope(this);
// The key of the pattern becomes the key into the RHS value, and the value
// of the pattern becomes the target of the assignment.
//
// e.g. { a: b } = o becomes b = o.a
Expression* pattern_key = pattern_property->key();
Expression* target = pattern_property->value();
Expression* default_value = GetDestructuringDefaultValue(&target);
if (!target->IsPattern()) {
builder()->SetExpressionAsStatementPosition(target);
}
// Calculate this property's key into the assignment RHS value, additionally
// storing the key for rest_runtime_callargs if needed.
//
// The RHS is accessed using the key either by LoadNamedProperty (if
// value_name is valid) or by LoadKeyedProperty (otherwise).
const AstRawString* value_name = nullptr;
Register value_key;
if (pattern_property->kind() != ObjectLiteralProperty::Kind::SPREAD) {
if (pattern_key->IsPropertyName()) {
value_name = pattern_key->AsLiteral()->AsRawPropertyName();
}
if (pattern->has_rest_property() || !value_name) {
if (pattern->has_rest_property()) {
value_key = rest_runtime_callargs[i + 1];
} else {
value_key = register_allocator()->NewRegister();
}
if (pattern_property->is_computed_name()) {
// { [a()]: b().x } = c
// becomes
// var tmp = a()
// b().x = c[tmp]
DCHECK(!pattern_key->IsPropertyName() ||
!pattern_key->IsNumberLiteral());
VisitForAccumulatorValue(pattern_key);
builder()->ToName(value_key);
} else {
// We only need the key for non-computed properties when it is numeric
// or is being saved for the rest_runtime_callargs.
DCHECK(
pattern_key->IsNumberLiteral() ||
(pattern->has_rest_property() && pattern_key->IsPropertyName()));
VisitForRegisterValue(pattern_key, value_key);
}
}
}
AssignmentLhsData lhs_data = PrepareAssignmentLhs(target);
// Get the value from the RHS.
if (pattern_property->kind() == ObjectLiteralProperty::Kind::SPREAD) {
DCHECK_EQ(i, pattern->properties()->length() - 1);
DCHECK(!value_key.is_valid());
DCHECK_NULL(value_name);
builder()->CallRuntime(Runtime::kCopyDataPropertiesWithExcludedProperties,
rest_runtime_callargs);
} else if (value_name) {
builder()->LoadNamedProperty(
value, value_name, feedback_index(feedback_spec()->AddLoadICSlot()));
} else {
DCHECK(value_key.is_valid());
builder()->LoadAccumulatorWithRegister(value_key).LoadKeyedProperty(
value, feedback_index(feedback_spec()->AddKeyedLoadICSlot()));
}
// {<pattern> = <init>} = <value>
// becomes
// temp = <value>;
// <pattern> = temp === undefined ? <init> : temp;
if (default_value) {
BytecodeLabel value_not_undefined;
builder()->JumpIfNotUndefined(&value_not_undefined);
VisitForAccumulatorValue(default_value);
builder()->Bind(&value_not_undefined);
}
BuildAssignment(lhs_data, op, lookup_hoisting_mode);
i++;
}
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
}
void BytecodeGenerator::BuildAssignment(
const AssignmentLhsData& lhs_data, Token::Value op,
LookupHoistingMode lookup_hoisting_mode) {
// Assign the value to the LHS.
switch (lhs_data.assign_type()) {
case NON_PROPERTY: {
if (ObjectLiteral* pattern = lhs_data.expr()->AsObjectLiteral()) {
// Split object literals into destructuring.
BuildDestructuringObjectAssignment(pattern, op, lookup_hoisting_mode);
} else if (ArrayLiteral* pattern = lhs_data.expr()->AsArrayLiteral()) {
// Split object literals into destructuring.
BuildDestructuringArrayAssignment(pattern, op, lookup_hoisting_mode);
} else {
DCHECK(lhs_data.expr()->IsVariableProxy());
VariableProxy* proxy = lhs_data.expr()->AsVariableProxy();
BuildVariableAssignment(proxy->var(), op, proxy->hole_check_mode(),
lookup_hoisting_mode);
}
break;
}
case NAMED_PROPERTY: {
BuildStoreNamedProperty(lhs_data.object_expr(), lhs_data.object(),
lhs_data.name());
break;
}
case KEYED_PROPERTY: {
FeedbackSlot slot = feedback_spec()->AddKeyedStoreICSlot(language_mode());
Register value;
if (!execution_result()->IsEffect()) {
value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
}
builder()->StoreKeyedProperty(lhs_data.object(), lhs_data.key(),
feedback_index(slot), language_mode());
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
break;
}
case NAMED_SUPER_PROPERTY: {
builder()
->StoreAccumulatorInRegister(lhs_data.super_property_args()[3])
.CallRuntime(Runtime::kStoreToSuper, lhs_data.super_property_args());
break;
}
case KEYED_SUPER_PROPERTY: {
builder()
->StoreAccumulatorInRegister(lhs_data.super_property_args()[3])
.CallRuntime(Runtime::kStoreKeyedToSuper,
lhs_data.super_property_args());
break;
}
case PRIVATE_METHOD: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateMethodWrite,
lhs_data.expr()->AsProperty());
break;
}
case PRIVATE_GETTER_ONLY: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateSetterAccess,
lhs_data.expr()->AsProperty());
break;
}
case PRIVATE_SETTER_ONLY:
case PRIVATE_GETTER_AND_SETTER: {
Register value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
Property* property = lhs_data.expr()->AsProperty();
Register object = VisitForRegisterValue(property->obj());
Register key = VisitForRegisterValue(property->key());
BuildPrivateBrandCheck(property, object,
MessageTemplate::kInvalidPrivateMemberWrite);
BuildPrivateSetterAccess(object, key, value);
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
break;
}
}
}
void BytecodeGenerator::VisitAssignment(Assignment* expr) {
AssignmentLhsData lhs_data = PrepareAssignmentLhs(expr->target());
VisitForAccumulatorValue(expr->value());
builder()->SetExpressionPosition(expr);
BuildAssignment(lhs_data, expr->op(), expr->lookup_hoisting_mode());
}
void BytecodeGenerator::VisitCompoundAssignment(CompoundAssignment* expr) {
AssignmentLhsData lhs_data = PrepareAssignmentLhs(expr->target());
// Evaluate the value and potentially handle compound assignments by loading
// the left-hand side value and performing a binary operation.
switch (lhs_data.assign_type()) {
case NON_PROPERTY: {
VariableProxy* proxy = expr->target()->AsVariableProxy();
BuildVariableLoad(proxy->var(), proxy->hole_check_mode());
break;
}
case NAMED_PROPERTY: {
BuildLoadNamedProperty(lhs_data.object_expr(), lhs_data.object(),
lhs_data.name());
break;
}
case KEYED_PROPERTY: {
FeedbackSlot slot = feedback_spec()->AddKeyedLoadICSlot();
builder()
->LoadAccumulatorWithRegister(lhs_data.key())
.LoadKeyedProperty(lhs_data.object(), feedback_index(slot));
break;
}
case NAMED_SUPER_PROPERTY: {
builder()->CallRuntime(Runtime::kLoadFromSuper,
lhs_data.super_property_args().Truncate(3));
break;
}
case KEYED_SUPER_PROPERTY: {
builder()->CallRuntime(Runtime::kLoadKeyedFromSuper,
lhs_data.super_property_args().Truncate(3));
break;
}
case PRIVATE_METHOD:
case PRIVATE_GETTER_ONLY:
case PRIVATE_SETTER_ONLY:
case PRIVATE_GETTER_AND_SETTER: {
// ({ #foo: name } = obj) is currently syntactically invalid.
UNREACHABLE();
break;
}
}
BinaryOperation* binop = expr->binary_operation();
FeedbackSlot slot = feedback_spec()->AddBinaryOpICSlot();
BytecodeLabel short_circuit;
if (binop->op() == Token::NULLISH) {
BytecodeLabel nullish;
builder()
->JumpIfUndefinedOrNull(&nullish)
.Jump(&short_circuit)
.Bind(&nullish);
VisitForAccumulatorValue(expr->value());
} else if (binop->op() == Token::OR) {
builder()->JumpIfTrue(ToBooleanMode::kConvertToBoolean, &short_circuit);
VisitForAccumulatorValue(expr->value());
} else if (binop->op() == Token::AND) {
builder()->JumpIfFalse(ToBooleanMode::kConvertToBoolean, &short_circuit);
VisitForAccumulatorValue(expr->value());
} else if (expr->value()->IsSmiLiteral()) {
builder()->BinaryOperationSmiLiteral(
binop->op(), expr->value()->AsLiteral()->AsSmiLiteral(),
feedback_index(slot));
} else {
Register old_value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(old_value);
VisitForAccumulatorValue(expr->value());
builder()->BinaryOperation(binop->op(), old_value, feedback_index(slot));
}
builder()->SetExpressionPosition(expr);
BuildAssignment(lhs_data, expr->op(), expr->lookup_hoisting_mode());
builder()->Bind(&short_circuit);
}
// Suspends the generator to resume at the next suspend_id, with output stored
// in the accumulator. When the generator is resumed, the sent value is loaded
// in the accumulator.
void BytecodeGenerator::BuildSuspendPoint(int position) {
// Because we eliminate jump targets in dead code, we also eliminate resumes
// when the suspend is not emitted because otherwise the below call to Bind
// would start a new basic block and the code would be considered alive.
if (builder()->RemainderOfBlockIsDead()) {
return;
}
const int suspend_id = suspend_count_++;
RegisterList registers = register_allocator()->AllLiveRegisters();
// Save context, registers, and state. This bytecode then returns the value
// in the accumulator.
builder()->SetExpressionPosition(position);
builder()->SuspendGenerator(generator_object(), registers, suspend_id);
// Upon resume, we continue here.
builder()->Bind(generator_jump_table_, suspend_id);
// Clobbers all registers and sets the accumulator to the
// [[input_or_debug_pos]] slot of the generator object.
builder()->ResumeGenerator(generator_object(), registers);
}
void BytecodeGenerator::VisitYield(Yield* expr) {
builder()->SetExpressionPosition(expr);
VisitForAccumulatorValue(expr->expression());
// If this is not the first yield
if (suspend_count_ > 0) {
if (IsAsyncGeneratorFunction(function_kind())) {
// AsyncGenerator yields (with the exception of the initial yield)
// delegate work to the AsyncGeneratorYield stub, which Awaits the operand
// and on success, wraps the value in an IteratorResult.
RegisterAllocationScope register_scope(this);
RegisterList args = register_allocator()->NewRegisterList(3);
builder()
->MoveRegister(generator_object(), args[0]) // generator
.StoreAccumulatorInRegister(args[1]) // value
.LoadBoolean(catch_prediction() != HandlerTable::ASYNC_AWAIT)
.StoreAccumulatorInRegister(args[2]) // is_caught
.CallRuntime(Runtime::kInlineAsyncGeneratorYield, args);
} else {
// Generator yields (with the exception of the initial yield) wrap the
// value into IteratorResult.
RegisterAllocationScope register_scope(this);
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->StoreAccumulatorInRegister(args[0]) // value
.LoadFalse()
.StoreAccumulatorInRegister(args[1]) // done
.CallRuntime(Runtime::kInlineCreateIterResultObject, args);
}
}
BuildSuspendPoint(expr->position());
// At this point, the generator has been resumed, with the received value in
// the accumulator.
// TODO(caitp): remove once yield* desugaring for async generators is handled
// in BytecodeGenerator.
if (expr->on_abrupt_resume() == Yield::kNoControl) {
DCHECK(IsAsyncGeneratorFunction(function_kind()));
return;
}
Register input = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(input).CallRuntime(
Runtime::kInlineGeneratorGetResumeMode, generator_object());
// Now dispatch on resume mode.
STATIC_ASSERT(JSGeneratorObject::kNext + 1 == JSGeneratorObject::kReturn);
BytecodeJumpTable* jump_table =
builder()->AllocateJumpTable(2, JSGeneratorObject::kNext);
builder()->SwitchOnSmiNoFeedback(jump_table);
{
// Resume with throw (switch fallthrough).
// TODO(leszeks): Add a debug-only check that the accumulator is
// JSGeneratorObject::kThrow.
builder()->SetExpressionPosition(expr);
builder()->LoadAccumulatorWithRegister(input);
builder()->Throw();
}
{
// Resume with return.
builder()->Bind(jump_table, JSGeneratorObject::kReturn);
builder()->LoadAccumulatorWithRegister(input);
if (IsAsyncGeneratorFunction(function_kind())) {
execution_control()->AsyncReturnAccumulator();
} else {
execution_control()->ReturnAccumulator();
}
}
{
// Resume with next.
builder()->Bind(jump_table, JSGeneratorObject::kNext);
BuildIncrementBlockCoverageCounterIfEnabled(expr,
SourceRangeKind::kContinuation);
builder()->LoadAccumulatorWithRegister(input);
}
}
// Desugaring of (yield* iterable)
//
// do {
// const kNext = 0;
// const kReturn = 1;
// const kThrow = 2;
//
// let output; // uninitialized
//
// let iteratorRecord = GetIterator(iterable);
// let iterator = iteratorRecord.[[Iterator]];
// let next = iteratorRecord.[[NextMethod]];
// let input = undefined;
// let resumeMode = kNext;
//
// while (true) {
// // From the generator to the iterator:
// // Forward input according to resumeMode and obtain output.
// switch (resumeMode) {
// case kNext:
// output = next.[[Call]](iterator, « »);;
// break;
// case kReturn:
// let iteratorReturn = iterator.return;
// if (IS_NULL_OR_UNDEFINED(iteratorReturn)) {
// if (IS_ASYNC_GENERATOR) input = await input;
// return input;
// }
// output = iteratorReturn.[[Call]](iterator, «input»);
// break;
// case kThrow:
// let iteratorThrow = iterator.throw;
// if (IS_NULL_OR_UNDEFINED(iteratorThrow)) {
// let iteratorReturn = iterator.return;
// if (!IS_NULL_OR_UNDEFINED(iteratorReturn)) {
// output = iteratorReturn.[[Call]](iterator, « »);
// if (IS_ASYNC_GENERATOR) output = await output;
// if (!IS_RECEIVER(output)) %ThrowIterResultNotAnObject(output);
// }
// throw MakeTypeError(kThrowMethodMissing);
// }
// output = iteratorThrow.[[Call]](iterator, «input»);
// break;
// }
//
// if (IS_ASYNC_GENERATOR) output = await output;
// if (!IS_RECEIVER(output)) %ThrowIterResultNotAnObject(output);
// if (output.done) break;
//
// // From the generator to its user:
// // Forward output, receive new input, and determine resume mode.
// if (IS_ASYNC_GENERATOR) {
// // AsyncGeneratorYield abstract operation awaits the operand before
// // resolving the promise for the current AsyncGeneratorRequest.
// %_AsyncGeneratorYield(output.value)
// }
// input = Suspend(output);
// resumeMode = %GeneratorGetResumeMode();
// }
//
// if (resumeMode === kReturn) {
// return output.value;
// }
// output.value
// }
void BytecodeGenerator::VisitYieldStar(YieldStar* expr) {
Register output = register_allocator()->NewRegister();
Register resume_mode = register_allocator()->NewRegister();
IteratorType iterator_type = IsAsyncGeneratorFunction(function_kind())
? IteratorType::kAsync
: IteratorType::kNormal;
{
RegisterAllocationScope register_scope(this);
RegisterList iterator_and_input = register_allocator()->NewRegisterList(2);
VisitForAccumulatorValue(expr->expression());
IteratorRecord iterator = BuildGetIteratorRecord(
register_allocator()->NewRegister() /* next method */,
iterator_and_input[0], iterator_type);
Register input = iterator_and_input[1];
builder()->LoadUndefined().StoreAccumulatorInRegister(input);
builder()
->LoadLiteral(Smi::FromInt(JSGeneratorObject::kNext))
.StoreAccumulatorInRegister(resume_mode);
{
// This loop builder does not construct counters as the loop is not
// visible to the user, and we therefore neither pass the block coverage
// builder nor the expression.
//
// In addition to the normal suspend for yield*, a yield* in an async
// generator has 2 additional suspends:
// - One for awaiting the iterator result of closing the generator when
// resumed with a "throw" completion, and a throw method is not
// present on the delegated iterator
// - One for awaiting the iterator result yielded by the delegated
// iterator
LoopBuilder loop_builder(builder(), nullptr, nullptr);
LoopScope loop_scope(this, &loop_builder);
{
BytecodeLabels after_switch(zone());
BytecodeJumpTable* switch_jump_table =
builder()->AllocateJumpTable(2, 1);
builder()
->LoadAccumulatorWithRegister(resume_mode)
.SwitchOnSmiNoFeedback(switch_jump_table);
// Fallthrough to default case.
// TODO(tebbi): Add debug code to check that {resume_mode} really is
// {JSGeneratorObject::kNext} in this case.
STATIC_ASSERT(JSGeneratorObject::kNext == 0);
{
FeedbackSlot slot = feedback_spec()->AddCallICSlot();
builder()->CallProperty(iterator.next(), iterator_and_input,
feedback_index(slot));
builder()->Jump(after_switch.New());
}
STATIC_ASSERT(JSGeneratorObject::kReturn == 1);
builder()->Bind(switch_jump_table, JSGeneratorObject::kReturn);
{
const AstRawString* return_string =
ast_string_constants()->return_string();
BytecodeLabels no_return_method(zone());
BuildCallIteratorMethod(iterator.object(), return_string,
iterator_and_input, after_switch.New(),
&no_return_method);
no_return_method.Bind(builder());
builder()->LoadAccumulatorWithRegister(input);
if (iterator_type == IteratorType::kAsync) {
// Await input.
BuildAwait(expr->position());
execution_control()->AsyncReturnAccumulator();
} else {
execution_control()->ReturnAccumulator();
}
}
STATIC_ASSERT(JSGeneratorObject::kThrow == 2);
builder()->Bind(switch_jump_table, JSGeneratorObject::kThrow);
{
const AstRawString* throw_string =
ast_string_constants()->throw_string();
BytecodeLabels no_throw_method(zone());
BuildCallIteratorMethod(iterator.object(), throw_string,
iterator_and_input, after_switch.New(),
&no_throw_method);
// If there is no "throw" method, perform IteratorClose, and finally
// throw a TypeError.
no_throw_method.Bind(builder());
BuildIteratorClose(iterator, expr);
builder()->CallRuntime(Runtime::kThrowThrowMethodMissing);
}
after_switch.Bind(builder());
}
if (iterator_type == IteratorType::kAsync) {
// Await the result of the method invocation.
BuildAwait(expr->position());
}
// Check that output is an object.
BytecodeLabel check_if_done;
builder()
->StoreAccumulatorInRegister(output)
.JumpIfJSReceiver(&check_if_done)
.CallRuntime(Runtime::kThrowIteratorResultNotAnObject, output);
builder()->Bind(&check_if_done);
// Break once output.done is true.
builder()->LoadNamedProperty(
output, ast_string_constants()->done_string(),
feedback_index(feedback_spec()->AddLoadICSlot()));
loop_builder.BreakIfTrue(ToBooleanMode::kConvertToBoolean);
// Suspend the current generator.
if (iterator_type == IteratorType::kNormal) {
builder()->LoadAccumulatorWithRegister(output);
} else {
RegisterAllocationScope register_scope(this);
DCHECK_EQ(iterator_type, IteratorType::kAsync);
// If generatorKind is async, perform AsyncGeneratorYield(output.value),
// which will await `output.value` before resolving the current
// AsyncGeneratorRequest's promise.
builder()->LoadNamedProperty(
output, ast_string_constants()->value_string(),
feedback_index(feedback_spec()->AddLoadICSlot()));
RegisterList args = register_allocator()->NewRegisterList(3);
builder()
->MoveRegister(generator_object(), args[0]) // generator
.StoreAccumulatorInRegister(args[1]) // value
.LoadBoolean(catch_prediction() != HandlerTable::ASYNC_AWAIT)
.StoreAccumulatorInRegister(args[2]) // is_caught
.CallRuntime(Runtime::kInlineAsyncGeneratorYield, args);
}
BuildSuspendPoint(expr->position());
builder()->StoreAccumulatorInRegister(input);
builder()
->CallRuntime(Runtime::kInlineGeneratorGetResumeMode,
generator_object())
.StoreAccumulatorInRegister(resume_mode);
loop_builder.BindContinueTarget();
}
}
// Decide if we trigger a return or if the yield* expression should just
// produce a value.
BytecodeLabel completion_is_output_value;
Register output_value = register_allocator()->NewRegister();
builder()
->LoadNamedProperty(output, ast_string_constants()->value_string(),
feedback_index(feedback_spec()->AddLoadICSlot()))
.StoreAccumulatorInRegister(output_value)
.LoadLiteral(Smi::FromInt(JSGeneratorObject::kReturn))
.CompareReference(resume_mode)
.JumpIfFalse(ToBooleanMode::kAlreadyBoolean, &completion_is_output_value)
.LoadAccumulatorWithRegister(output_value);
if (iterator_type == IteratorType::kAsync) {
execution_control()->AsyncReturnAccumulator();
} else {
execution_control()->ReturnAccumulator();
}
builder()->Bind(&completion_is_output_value);
BuildIncrementBlockCoverageCounterIfEnabled(expr,
SourceRangeKind::kContinuation);
builder()->LoadAccumulatorWithRegister(output_value);
}
void BytecodeGenerator::BuildAwait(int position) {
// Rather than HandlerTable::UNCAUGHT, async functions use
// HandlerTable::ASYNC_AWAIT to communicate that top-level exceptions are
// transformed into promise rejections. This is necessary to prevent emitting
// multiple debug events for the same uncaught exception. There is no point
// in the body of an async function where catch prediction is
// HandlerTable::UNCAUGHT.
DCHECK(catch_prediction() != HandlerTable::UNCAUGHT ||
info()->scope()->is_repl_mode_scope());
{
// Await(operand) and suspend.
RegisterAllocationScope register_scope(this);
Runtime::FunctionId await_intrinsic_id;
if (IsAsyncGeneratorFunction(function_kind())) {
await_intrinsic_id = catch_prediction() == HandlerTable::ASYNC_AWAIT
? Runtime::kInlineAsyncGeneratorAwaitUncaught
: Runtime::kInlineAsyncGeneratorAwaitCaught;
} else {
await_intrinsic_id = catch_prediction() == HandlerTable::ASYNC_AWAIT
? Runtime::kInlineAsyncFunctionAwaitUncaught
: Runtime::kInlineAsyncFunctionAwaitCaught;
}
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->MoveRegister(generator_object(), args[0])
.StoreAccumulatorInRegister(args[1])
.CallRuntime(await_intrinsic_id, args);
}
BuildSuspendPoint(position);
Register input = register_allocator()->NewRegister();
Register resume_mode = register_allocator()->NewRegister();
// Now dispatch on resume mode.
BytecodeLabel resume_next;
builder()
->StoreAccumulatorInRegister(input)
.CallRuntime(Runtime::kInlineGeneratorGetResumeMode, generator_object())
.StoreAccumulatorInRegister(resume_mode)
.LoadLiteral(Smi::FromInt(JSGeneratorObject::kNext))
.CompareReference(resume_mode)
.JumpIfTrue(ToBooleanMode::kAlreadyBoolean, &resume_next);
// Resume with "throw" completion (rethrow the received value).
// TODO(leszeks): Add a debug-only check that the accumulator is
// JSGeneratorObject::kThrow.
builder()->LoadAccumulatorWithRegister(input).ReThrow();
// Resume with next.
builder()->Bind(&resume_next);
builder()->LoadAccumulatorWithRegister(input);
}
void BytecodeGenerator::VisitAwait(Await* expr) {
builder()->SetExpressionPosition(expr);
VisitForAccumulatorValue(expr->expression());
BuildAwait(expr->position());
BuildIncrementBlockCoverageCounterIfEnabled(expr,
SourceRangeKind::kContinuation);
}
void BytecodeGenerator::VisitThrow(Throw* expr) {
AllocateBlockCoverageSlotIfEnabled(expr, SourceRangeKind::kContinuation);
VisitForAccumulatorValue(expr->exception());
builder()->SetExpressionPosition(expr);
builder()->Throw();
}
void BytecodeGenerator::VisitPropertyLoad(Register obj, Property* property) {
if (property->is_optional_chain_link()) {
DCHECK_NOT_NULL(optional_chaining_null_labels_);
builder()->LoadAccumulatorWithRegister(obj).JumpIfUndefinedOrNull(
optional_chaining_null_labels_->New());
}
AssignType property_kind = Property::GetAssignType(property);
switch (property_kind) {
case NON_PROPERTY:
UNREACHABLE();
case NAMED_PROPERTY: {
builder()->SetExpressionPosition(property);
const AstRawString* name =
property->key()->AsLiteral()->AsRawPropertyName();
BuildLoadNamedProperty(property->obj(), obj, name);
break;
}
case KEYED_PROPERTY: {
VisitForAccumulatorValue(property->key());
builder()->SetExpressionPosition(property);
builder()->LoadKeyedProperty(
obj, feedback_index(feedback_spec()->AddKeyedLoadICSlot()));
break;
}
case NAMED_SUPER_PROPERTY:
VisitNamedSuperPropertyLoad(property, Register::invalid_value());
break;
case KEYED_SUPER_PROPERTY:
VisitKeyedSuperPropertyLoad(property, Register::invalid_value());
break;
case PRIVATE_SETTER_ONLY: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateGetterAccess,
property);
break;
}
case PRIVATE_GETTER_ONLY:
case PRIVATE_GETTER_AND_SETTER: {
Register key = VisitForRegisterValue(property->key());
BuildPrivateBrandCheck(property, obj,
MessageTemplate::kInvalidPrivateMemberRead);
BuildPrivateGetterAccess(obj, key);
break;
}
case PRIVATE_METHOD: {
BuildPrivateBrandCheck(property, obj,
MessageTemplate::kInvalidPrivateMemberRead);
// In the case of private methods, property->key() is the function to be
// loaded (stored in a context slot), so load this directly.
VisitForAccumulatorValue(property->key());
break;
}
}
}
void BytecodeGenerator::BuildPrivateGetterAccess(Register object,
Register accessor_pair) {
RegisterAllocationScope scope(this);
Register accessor = register_allocator()->NewRegister();
RegisterList args = register_allocator()->NewRegisterList(1);
builder()
->CallRuntime(Runtime::kLoadPrivateGetter, accessor_pair)
.StoreAccumulatorInRegister(accessor)
.MoveRegister(object, args[0])
.CallProperty(accessor, args,
feedback_index(feedback_spec()->AddCallICSlot()));
}
void BytecodeGenerator::BuildPrivateSetterAccess(Register object,
Register accessor_pair,
Register value) {
RegisterAllocationScope scope(this);
Register accessor = register_allocator()->NewRegister();
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->CallRuntime(Runtime::kLoadPrivateSetter, accessor_pair)
.StoreAccumulatorInRegister(accessor)
.MoveRegister(object, args[0])
.MoveRegister(value, args[1])
.CallProperty(accessor, args,
feedback_index(feedback_spec()->AddCallICSlot()));
}
void BytecodeGenerator::BuildPrivateBrandCheck(Property* property,
Register object,
MessageTemplate tmpl) {
Variable* private_name = property->key()->AsVariableProxy()->var();
DCHECK(IsPrivateMethodOrAccessorVariableMode(private_name->mode()));
ClassScope* scope = private_name->scope()->AsClassScope();
if (private_name->is_static()) {
// For static private methods, the only valid receiver is the class.
// Load the class constructor.
if (scope->class_variable() == nullptr) {
// If the static private method has not been used used in source
// code (either explicitly or through the presence of eval), but is
// accessed by the debugger at runtime, reference to the class variable
// is not available since it was not be context-allocated. Therefore we
// can't build a branch check, and throw an ReferenceError as if the
// method was optimized away.
// TODO(joyee): get a reference to the class constructor through
// something other than scope->class_variable() in this scenario.
RegisterAllocationScope register_scope(this);
RegisterList args = register_allocator()->NewRegisterList(2);
builder()
->LoadLiteral(Smi::FromEnum(
MessageTemplate::
kInvalidUnusedPrivateStaticMethodAccessedByDebugger))
.StoreAccumulatorInRegister(args[0])
.LoadLiteral(private_name->raw_name())
.StoreAccumulatorInRegister(args[1])
.CallRuntime(Runtime::kNewError, args)
.Throw();
} else {
BuildVariableLoadForAccumulatorValue(scope->class_variable(),
HoleCheckMode::kElided);
BytecodeLabel return_check;
builder()->CompareReference(object).JumpIfTrue(
ToBooleanMode::kAlreadyBoolean, &return_check);
BuildInvalidPropertyAccess(tmpl, property);
builder()->Bind(&return_check);
}
} else {
BuildVariableLoadForAccumulatorValue(scope->brand(),
HoleCheckMode::kElided);
builder()->SetExpressionPosition(property);
builder()->LoadKeyedProperty(
object, feedback_index(feedback_spec()->AddKeyedLoadICSlot()));
}
}
void BytecodeGenerator::VisitPropertyLoadForRegister(Register obj,
Property* expr,
Register destination) {
ValueResultScope result_scope(this);
VisitPropertyLoad(obj, expr);
builder()->StoreAccumulatorInRegister(destination);
}
void BytecodeGenerator::VisitNamedSuperPropertyLoad(Property* property,
Register opt_receiver_out) {
RegisterAllocationScope register_scope(this);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
if (FLAG_super_ic) {
Register receiver = register_allocator()->NewRegister();
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(receiver);
VisitForAccumulatorValue(super_property->home_object());
builder()->SetExpressionPosition(property);
auto name = property->key()->AsLiteral()->AsRawPropertyName();
FeedbackSlot slot = GetCachedLoadSuperICSlot(name);
builder()->LoadNamedPropertyFromSuper(receiver, name, feedback_index(slot));
if (opt_receiver_out.is_valid()) {
builder()->MoveRegister(receiver, opt_receiver_out);
}
} else {
RegisterList args = register_allocator()->NewRegisterList(3);
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(args[0]);
VisitForRegisterValue(super_property->home_object(), args[1]);
builder()->SetExpressionPosition(property);
builder()
->LoadLiteral(property->key()->AsLiteral()->AsRawPropertyName())
.StoreAccumulatorInRegister(args[2])
.CallRuntime(Runtime::kLoadFromSuper, args);
if (opt_receiver_out.is_valid()) {
builder()->MoveRegister(args[0], opt_receiver_out);
}
}
}
void BytecodeGenerator::VisitKeyedSuperPropertyLoad(Property* property,
Register opt_receiver_out) {
RegisterAllocationScope register_scope(this);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
RegisterList args = register_allocator()->NewRegisterList(3);
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(args[0]);
VisitForRegisterValue(super_property->home_object(), args[1]);
VisitForRegisterValue(property->key(), args[2]);
builder()->SetExpressionPosition(property);
builder()->CallRuntime(Runtime::kLoadKeyedFromSuper, args);
if (opt_receiver_out.is_valid()) {
builder()->MoveRegister(args[0], opt_receiver_out);
}
}
template <typename ExpressionFunc>
void BytecodeGenerator::BuildOptionalChain(ExpressionFunc expression_func) {
BytecodeLabel done;
OptionalChainNullLabelScope label_scope(this);
expression_func();
builder()->Jump(&done);
label_scope.labels()->Bind(builder());
builder()->LoadUndefined();
builder()->Bind(&done);
}
void BytecodeGenerator::VisitOptionalChain(OptionalChain* expr) {
BuildOptionalChain([&]() { VisitForAccumulatorValue(expr->expression()); });
}
void BytecodeGenerator::VisitProperty(Property* expr) {
AssignType property_kind = Property::GetAssignType(expr);
if (property_kind != NAMED_SUPER_PROPERTY &&
property_kind != KEYED_SUPER_PROPERTY) {
Register obj = VisitForRegisterValue(expr->obj());
VisitPropertyLoad(obj, expr);
} else {
VisitPropertyLoad(Register::invalid_value(), expr);
}
}
void BytecodeGenerator::VisitArguments(const ZonePtrList<Expression>* args,
RegisterList* arg_regs) {
// Visit arguments.
for (int i = 0; i < static_cast<int>(args->length()); i++) {
VisitAndPushIntoRegisterList(args->at(i), arg_regs);
}
}
void BytecodeGenerator::VisitCall(Call* expr) {
Expression* callee_expr = expr->expression();
Call::CallType call_type = expr->GetCallType();
if (call_type == Call::SUPER_CALL) {
return VisitCallSuper(expr);
}
// Grow the args list as we visit receiver / arguments to avoid allocating all
// the registers up-front. Otherwise these registers are unavailable during
// receiver / argument visiting and we can end up with memory leaks due to
// registers keeping objects alive.
Register callee = register_allocator()->NewRegister();
RegisterList args = register_allocator()->NewGrowableRegisterList();
bool implicit_undefined_receiver = false;
// When a call contains a spread, a Call AST node is only created if there is
// exactly one spread, and it is the last argument.
bool is_spread_call = expr->only_last_arg_is_spread();
bool optimize_as_one_shot = ShouldOptimizeAsOneShot();
// TODO(petermarshall): We have a lot of call bytecodes that are very similar,
// see if we can reduce the number by adding a separate argument which
// specifies the call type (e.g., property, spread, tailcall, etc.).
// Prepare the callee and the receiver to the function call. This depends on
// the semantics of the underlying call type.
switch (call_type) {
case Call::NAMED_PROPERTY_CALL:
case Call::KEYED_PROPERTY_CALL:
case Call::PRIVATE_CALL: {
Property* property = callee_expr->AsProperty();
VisitAndPushIntoRegisterList(property->obj(), &args);
VisitPropertyLoadForRegister(args.last_register(), property, callee);
break;
}
case Call::GLOBAL_CALL: {
// Receiver is undefined for global calls.
if (!is_spread_call && !optimize_as_one_shot) {
implicit_undefined_receiver = true;
} else {
// TODO(leszeks): There's no special bytecode for tail calls or spread
// calls with an undefined receiver, so just push undefined ourselves.
BuildPushUndefinedIntoRegisterList(&args);
}
// Load callee as a global variable.
VariableProxy* proxy = callee_expr->AsVariableProxy();
BuildVariableLoadForAccumulatorValue(proxy->var(),
proxy->hole_check_mode());
builder()->StoreAccumulatorInRegister(callee);
break;
}
case Call::WITH_CALL: {
Register receiver = register_allocator()->GrowRegisterList(&args);
DCHECK(callee_expr->AsVariableProxy()->var()->IsLookupSlot());
{
RegisterAllocationScope inner_register_scope(this);
Register name = register_allocator()->NewRegister();
// Call %LoadLookupSlotForCall to get the callee and receiver.
RegisterList result_pair = register_allocator()->NewRegisterList(2);
Variable* variable = callee_expr->AsVariableProxy()->var();
builder()
->LoadLiteral(variable->raw_name())
.StoreAccumulatorInRegister(name)
.CallRuntimeForPair(Runtime::kLoadLookupSlotForCall, name,
result_pair)
.MoveRegister(result_pair[0], callee)
.MoveRegister(result_pair[1], receiver);
}
break;
}
case Call::OTHER_CALL: {
// Receiver is undefined for other calls.
if (!is_spread_call && !optimize_as_one_shot) {
implicit_undefined_receiver = true;
} else {
// TODO(leszeks): There's no special bytecode for tail calls or spread
// calls with an undefined receiver, so just push undefined ourselves.
BuildPushUndefinedIntoRegisterList(&args);
}
VisitForRegisterValue(callee_expr, callee);
break;
}
case Call::NAMED_SUPER_PROPERTY_CALL: {
Register receiver = register_allocator()->GrowRegisterList(&args);
Property* property = callee_expr->AsProperty();
VisitNamedSuperPropertyLoad(property, receiver);
builder()->StoreAccumulatorInRegister(callee);
break;
}
case Call::KEYED_SUPER_PROPERTY_CALL: {
Register receiver = register_allocator()->GrowRegisterList(&args);
Property* property = callee_expr->AsProperty();
VisitKeyedSuperPropertyLoad(property, receiver);
builder()->StoreAccumulatorInRegister(callee);
break;
}
case Call::NAMED_OPTIONAL_CHAIN_PROPERTY_CALL:
case Call::KEYED_OPTIONAL_CHAIN_PROPERTY_CALL:
case Call::PRIVATE_OPTIONAL_CHAIN_CALL: {
OptionalChain* chain = callee_expr->AsOptionalChain();
Property* property = chain->expression()->AsProperty();
BuildOptionalChain([&]() {
VisitAndPushIntoRegisterList(property->obj(), &args);
VisitPropertyLoadForRegister(args.last_register(), property, callee);
});
break;
}
case Call::SUPER_CALL:
UNREACHABLE();
}
if (expr->is_optional_chain_link()) {
DCHECK_NOT_NULL(optional_chaining_null_labels_);
builder()->LoadAccumulatorWithRegister(callee).JumpIfUndefinedOrNull(
optional_chaining_null_labels_->New());
}
// Evaluate all arguments to the function call and store in sequential args
// registers.
VisitArguments(expr->arguments(), &args);
int receiver_arg_count = implicit_undefined_receiver ? 0 : 1;
CHECK_EQ(receiver_arg_count + expr->arguments()->length(),
args.register_count());
// Resolve callee for a potential direct eval call. This block will mutate the
// callee value.
if (expr->is_possibly_eval() && expr->arguments()->length() > 0) {
RegisterAllocationScope inner_register_scope(this);
// Set up arguments for ResolvePossiblyDirectEval by copying callee, source
// strings and function closure, and loading language and
// position.
Register first_arg = args[receiver_arg_count];
RegisterList runtime_call_args = register_allocator()->NewRegisterList(6);
builder()
->MoveRegister(callee, runtime_call_args[0])
.MoveRegister(first_arg, runtime_call_args[1])
.MoveRegister(Register::function_closure(), runtime_call_args[2])
.LoadLiteral(Smi::FromEnum(language_mode()))
.StoreAccumulatorInRegister(runtime_call_args[3])
.LoadLiteral(Smi::FromInt(current_scope()->start_position()))
.StoreAccumulatorInRegister(runtime_call_args[4])
.LoadLiteral(Smi::FromInt(expr->position()))
.StoreAccumulatorInRegister(runtime_call_args[5]);
// Call ResolvePossiblyDirectEval and modify the callee.
builder()
->CallRuntime(Runtime::kResolvePossiblyDirectEval, runtime_call_args)
.StoreAccumulatorInRegister(callee);
}
builder()->SetExpressionPosition(expr);
if (is_spread_call) {
DCHECK(!implicit_undefined_receiver);
builder()->CallWithSpread(callee, args,
feedback_index(feedback_spec()->AddCallICSlot()));
} else if (optimize_as_one_shot) {
DCHECK(!implicit_undefined_receiver);
builder()->CallNoFeedback(callee, args);
} else if (call_type == Call::NAMED_PROPERTY_CALL ||
call_type == Call::KEYED_PROPERTY_CALL) {
DCHECK(!implicit_undefined_receiver);
builder()->CallProperty(callee, args,
feedback_index(feedback_spec()->AddCallICSlot()));
} else if (implicit_undefined_receiver) {
builder()->CallUndefinedReceiver(
callee, args, feedback_index(feedback_spec()->AddCallICSlot()));
} else {
builder()->CallAnyReceiver(
callee, args, feedback_index(feedback_spec()->AddCallICSlot()));
}
}
void BytecodeGenerator::VisitCallSuper(Call* expr) {
RegisterAllocationScope register_scope(this);
SuperCallReference* super = expr->expression()->AsSuperCallReference();
const ZonePtrList<Expression>* args = expr->arguments();
int first_spread_index = 0;
for (; first_spread_index < args->length(); first_spread_index++) {
if (args->at(first_spread_index)->IsSpread()) break;
}
// Prepare the constructor to the super call.
Register this_function = VisitForRegisterValue(super->this_function_var());
Register constructor = register_allocator()->NewRegister();
builder()
->LoadAccumulatorWithRegister(this_function)
.GetSuperConstructor(constructor);
if (first_spread_index < expr->arguments()->length() - 1) {
// We rewrite something like
// super(1, ...x, 2)
// to
// %reflect_construct(constructor, [1, ...x, 2], new_target)
// That is, we implement (non-last-arg) spreads in super calls via our
// mechanism for spreads in array literals.
// First generate the array containing all arguments.
BuildCreateArrayLiteral(args, nullptr);
// Check if the constructor is in fact a constructor.
builder()->ThrowIfNotSuperConstructor(constructor);
// Now pass that array to %reflect_construct.
RegisterList construct_args = register_allocator()->NewRegisterList(3);
builder()->StoreAccumulatorInRegister(construct_args[1]);
builder()->MoveRegister(constructor, construct_args[0]);
VisitForRegisterValue(super->new_target_var(), construct_args[2]);
builder()->CallJSRuntime(Context::REFLECT_CONSTRUCT_INDEX, construct_args);
} else {
RegisterList args_regs = register_allocator()->NewGrowableRegisterList();
VisitArguments(args, &args_regs);
// Check if the constructor is in fact a constructor.
builder()->ThrowIfNotSuperConstructor(constructor);
// The new target is loaded into the accumulator from the
// {new.target} variable.
VisitForAccumulatorValue(super->new_target_var());
builder()->SetExpressionPosition(expr);
int feedback_slot_index = feedback_index(feedback_spec()->AddCallICSlot());
if (first_spread_index == expr->arguments()->length() - 1) {
builder()->ConstructWithSpread(constructor, args_regs,
feedback_slot_index);
} else {
DCHECK_EQ(first_spread_index, expr->arguments()->length());
// Call construct.
// TODO(turbofan): For now we do gather feedback on super constructor
// calls, utilizing the existing machinery to inline the actual call
// target and the JSCreate for the implicit receiver allocation. This
// is not an ideal solution for super constructor calls, but it gets
// the job done for now. In the long run we might want to revisit this
// and come up with a better way.
builder()->Construct(constructor, args_regs, feedback_slot_index);
}
}
// Explicit calls to the super constructor using super() perform an
// implicit binding assignment to the 'this' variable.
//
// Default constructors don't need have to do the assignment because
// 'this' isn't accessed in default constructors.
if (!IsDefaultConstructor(info()->literal()->kind())) {
Variable* var = closure_scope()->GetReceiverScope()->receiver();
BuildVariableAssignment(var, Token::INIT, HoleCheckMode::kRequired);
}
Register instance = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(instance);
if (info()->literal()->class_scope_has_private_brand()) {
BuildPrivateBrandInitialization(instance);
}
// The derived constructor has the correct bit set always, so we
// don't emit code to load and call the initializer if not
// required.
//
// For the arrow function or eval case, we always emit code to load
// and call the initializer.
//
// TODO(gsathya): In the future, we could tag nested arrow functions
// or eval with the correct bit so that we do the load conditionally
// if required.
if (info()->literal()->requires_instance_members_initializer() ||
!IsDerivedConstructor(info()->literal()->kind())) {
BuildInstanceMemberInitialization(this_function, instance);
}
builder()->LoadAccumulatorWithRegister(instance);
}
void BytecodeGenerator::VisitCallNew(CallNew* expr) {
Register constructor = VisitForRegisterValue(expr->expression());
RegisterList args = register_allocator()->NewGrowableRegisterList();
VisitArguments(expr->arguments(), &args);
// The accumulator holds new target which is the same as the
// constructor for CallNew.
builder()->SetExpressionPosition(expr);
builder()->LoadAccumulatorWithRegister(constructor);
int feedback_slot_index = feedback_index(feedback_spec()->AddCallICSlot());
if (expr->only_last_arg_is_spread()) {
builder()->ConstructWithSpread(constructor, args, feedback_slot_index);
} else {
builder()->Construct(constructor, args, feedback_slot_index);
}
}
void BytecodeGenerator::VisitCallRuntime(CallRuntime* expr) {
if (expr->is_jsruntime()) {
RegisterList args = register_allocator()->NewGrowableRegisterList();
VisitArguments(expr->arguments(), &args);
builder()->CallJSRuntime(expr->context_index(), args);
} else {
// Evaluate all arguments to the runtime call.
RegisterList args = register_allocator()->NewGrowableRegisterList();
VisitArguments(expr->arguments(), &args);
Runtime::FunctionId function_id = expr->function()->function_id;
builder()->CallRuntime(function_id, args);
}
}
void BytecodeGenerator::VisitVoid(UnaryOperation* expr) {
VisitForEffect(expr->expression());
builder()->LoadUndefined();
}
void BytecodeGenerator::VisitForTypeOfValue(Expression* expr) {
if (expr->IsVariableProxy()) {
// Typeof does not throw a reference error on global variables, hence we
// perform a non-contextual load in case the operand is a variable proxy.
VariableProxy* proxy = expr->AsVariableProxy();
BuildVariableLoadForAccumulatorValue(proxy->var(), proxy->hole_check_mode(),
INSIDE_TYPEOF);
} else {
VisitForAccumulatorValue(expr);
}
}
void BytecodeGenerator::VisitTypeOf(UnaryOperation* expr) {
VisitForTypeOfValue(expr->expression());
builder()->TypeOf();
}
void BytecodeGenerator::VisitNot(UnaryOperation* expr) {
if (execution_result()->IsEffect()) {
VisitForEffect(expr->expression());
} else if (execution_result()->IsTest()) {
// No actual logical negation happening, we just swap the control flow, by
// swapping the target labels and the fallthrough branch, and visit in the
// same test result context.
TestResultScope* test_result = execution_result()->AsTest();
test_result->InvertControlFlow();
VisitInSameTestExecutionScope(expr->expression());
} else {
TypeHint type_hint = VisitForAccumulatorValue(expr->expression());
builder()->LogicalNot(ToBooleanModeFromTypeHint(type_hint));
// Always returns a boolean value.
execution_result()->SetResultIsBoolean();
}
}
void BytecodeGenerator::VisitUnaryOperation(UnaryOperation* expr) {
switch (expr->op()) {
case Token::Value::NOT:
VisitNot(expr);
break;
case Token::Value::TYPEOF:
VisitTypeOf(expr);
break;
case Token::Value::VOID:
VisitVoid(expr);
break;
case Token::Value::DELETE:
VisitDelete(expr);
break;
case Token::Value::ADD:
case Token::Value::SUB:
case Token::Value::BIT_NOT:
VisitForAccumulatorValue(expr->expression());
builder()->SetExpressionPosition(expr);
builder()->UnaryOperation(
expr->op(), feedback_index(feedback_spec()->AddBinaryOpICSlot()));
break;
default:
UNREACHABLE();
}
}
void BytecodeGenerator::VisitDelete(UnaryOperation* unary) {
Expression* expr = unary->expression();
if (expr->IsProperty()) {
// Delete of an object property is allowed both in sloppy
// and strict modes.
Property* property = expr->AsProperty();
DCHECK(!property->IsPrivateReference());
Register object = VisitForRegisterValue(property->obj());
VisitForAccumulatorValue(property->key());
builder()->Delete(object, language_mode());
} else if (expr->IsOptionalChain()) {
Expression* expr_inner = expr->AsOptionalChain()->expression();
if (expr_inner->IsProperty()) {
Property* property = expr_inner->AsProperty();
DCHECK(!property->IsPrivateReference());
BytecodeLabel done;
OptionalChainNullLabelScope label_scope(this);
VisitForAccumulatorValue(property->obj());
if (property->is_optional_chain_link()) {
builder()->JumpIfUndefinedOrNull(label_scope.labels()->New());
}
Register object = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(object);
VisitForAccumulatorValue(property->key());
builder()->Delete(object, language_mode());
builder()->Jump(&done);
label_scope.labels()->Bind(builder());
builder()->LoadTrue();
builder()->Bind(&done);
} else {
VisitForEffect(expr);
builder()->LoadTrue();
}
} else if (expr->IsVariableProxy() &&
!expr->AsVariableProxy()->is_new_target()) {
// Delete of an unqualified identifier is allowed in sloppy mode but is
// not allowed in strict mode.
DCHECK(is_sloppy(language_mode()));
Variable* variable = expr->AsVariableProxy()->var();
switch (variable->location()) {
case VariableLocation::PARAMETER:
case VariableLocation::LOCAL:
case VariableLocation::CONTEXT:
case VariableLocation::REPL_GLOBAL: {
// Deleting local var/let/const, context variables, and arguments
// does not have any effect.
builder()->LoadFalse();
break;
}
case VariableLocation::UNALLOCATED:
// TODO(adamk): Falling through to the runtime results in correct
// behavior, but does unnecessary context-walking (since scope
// analysis has already proven that the variable doesn't exist in
// any non-global scope). Consider adding a DeleteGlobal bytecode
// that knows how to deal with ScriptContexts as well as global
// object properties.
case VariableLocation::LOOKUP: {
Register name_reg = register_allocator()->NewRegister();
builder()
->LoadLiteral(variable->raw_name())
.StoreAccumulatorInRegister(name_reg)
.CallRuntime(Runtime::kDeleteLookupSlot, name_reg);
break;
}
case VariableLocation::MODULE:
// Modules are always in strict mode and unqualified identifers are not
// allowed in strict mode.
UNREACHABLE();
}
} else {
// Delete of an unresolvable reference, new.target, and this returns true.
VisitForEffect(expr);
builder()->LoadTrue();
}
}
void BytecodeGenerator::VisitCountOperation(CountOperation* expr) {
DCHECK(expr->expression()->IsValidReferenceExpression());
// Left-hand side can only be a property, a global or a variable slot.
Property* property = expr->expression()->AsProperty();
AssignType assign_type = Property::GetAssignType(property);
bool is_postfix = expr->is_postfix() && !execution_result()->IsEffect();
// Evaluate LHS expression and get old value.
Register object, key, old_value;
RegisterList super_property_args;
const AstRawString* name;
switch (assign_type) {
case NON_PROPERTY: {
VariableProxy* proxy = expr->expression()->AsVariableProxy();
BuildVariableLoadForAccumulatorValue(proxy->var(),
proxy->hole_check_mode());
break;
}
case NAMED_PROPERTY: {
object = VisitForRegisterValue(property->obj());
name = property->key()->AsLiteral()->AsRawPropertyName();
builder()->LoadNamedProperty(
object, name,
feedback_index(GetCachedLoadICSlot(property->obj(), name)));
break;
}
case KEYED_PROPERTY: {
object = VisitForRegisterValue(property->obj());
// Use visit for accumulator here since we need the key in the accumulator
// for the LoadKeyedProperty.
key = register_allocator()->NewRegister();
VisitForAccumulatorValue(property->key());
builder()->StoreAccumulatorInRegister(key).LoadKeyedProperty(
object, feedback_index(feedback_spec()->AddKeyedLoadICSlot()));
break;
}
case NAMED_SUPER_PROPERTY: {
super_property_args = register_allocator()->NewRegisterList(4);
RegisterList load_super_args = super_property_args.Truncate(3);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(load_super_args[0]);
VisitForRegisterValue(super_property->home_object(), load_super_args[1]);
builder()
->LoadLiteral(property->key()->AsLiteral()->AsRawPropertyName())
.StoreAccumulatorInRegister(load_super_args[2])
.CallRuntime(Runtime::kLoadFromSuper, load_super_args);
break;
}
case KEYED_SUPER_PROPERTY: {
super_property_args = register_allocator()->NewRegisterList(4);
RegisterList load_super_args = super_property_args.Truncate(3);
SuperPropertyReference* super_property =
property->obj()->AsSuperPropertyReference();
BuildThisVariableLoad();
builder()->StoreAccumulatorInRegister(load_super_args[0]);
VisitForRegisterValue(super_property->home_object(), load_super_args[1]);
VisitForRegisterValue(property->key(), load_super_args[2]);
builder()->CallRuntime(Runtime::kLoadKeyedFromSuper, load_super_args);
break;
}
case PRIVATE_METHOD: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateMethodWrite,
property);
return;
}
case PRIVATE_GETTER_ONLY: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateSetterAccess,
property);
return;
}
case PRIVATE_SETTER_ONLY: {
BuildInvalidPropertyAccess(MessageTemplate::kInvalidPrivateGetterAccess,
property);
return;
}
case PRIVATE_GETTER_AND_SETTER: {
object = VisitForRegisterValue(property->obj());
key = VisitForRegisterValue(property->key());
BuildPrivateBrandCheck(property, object,
MessageTemplate::kInvalidPrivateMemberRead);
BuildPrivateGetterAccess(object, key);
break;
}
}
// Save result for postfix expressions.
FeedbackSlot count_slot = feedback_spec()->AddBinaryOpICSlot();
if (is_postfix) {
old_value = register_allocator()->NewRegister();
// Convert old value into a number before saving it.
// TODO(ignition): Think about adding proper PostInc/PostDec bytecodes
// instead of this ToNumeric + Inc/Dec dance.
builder()
->ToNumeric(feedback_index(count_slot))
.StoreAccumulatorInRegister(old_value);
}
// Perform +1/-1 operation.
builder()->UnaryOperation(expr->op(), feedback_index(count_slot));
// Store the value.
builder()->SetExpressionPosition(expr);
switch (assign_type) {
case NON_PROPERTY: {
VariableProxy* proxy = expr->expression()->AsVariableProxy();
BuildVariableAssignment(proxy->var(), expr->op(),
proxy->hole_check_mode());
break;
}
case NAMED_PROPERTY: {
FeedbackSlot slot = GetCachedStoreICSlot(property->obj(), name);
Register value;
if (!execution_result()->IsEffect()) {
value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
}
builder()->StoreNamedProperty(object, name, feedback_index(slot),
language_mode());
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
break;
}
case KEYED_PROPERTY: {
FeedbackSlot slot = feedback_spec()->AddKeyedStoreICSlot(language_mode());
Register value;
if (!execution_result()->IsEffect()) {
value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
}
builder()->StoreKeyedProperty(object, key, feedback_index(slot),
language_mode());
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
break;
}
case NAMED_SUPER_PROPERTY: {
builder()
->StoreAccumulatorInRegister(super_property_args[3])
.CallRuntime(Runtime::kStoreToSuper, super_property_args);
break;
}
case KEYED_SUPER_PROPERTY: {
builder()
->StoreAccumulatorInRegister(super_property_args[3])
.CallRuntime(Runtime::kStoreKeyedToSuper, super_property_args);
break;
}
case PRIVATE_SETTER_ONLY:
case PRIVATE_GETTER_ONLY:
case PRIVATE_METHOD: {
UNREACHABLE();
}
case PRIVATE_GETTER_AND_SETTER: {
Register value = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(value);
BuildPrivateSetterAccess(object, key, value);
if (!execution_result()->IsEffect()) {
builder()->LoadAccumulatorWithRegister(value);
}
break;
}
}
// Restore old value for postfix expressions.
if (is_postfix) {
builder()->LoadAccumulatorWithRegister(old_value);
}
}
void BytecodeGenerator::VisitBinaryOperation(BinaryOperation* binop) {
switch (binop->op()) {
case Token::COMMA:
VisitCommaExpression(binop);
break;
case Token::OR:
VisitLogicalOrExpression(binop);
break;
case Token::AND:
VisitLogicalAndExpression(binop);
break;
case Token::NULLISH:
VisitNullishExpression(binop);
break;
default:
VisitArithmeticExpression(binop);
break;
}
}
void BytecodeGenerator::VisitNaryOperation(NaryOperation* expr) {
switch (expr->op()) {
case Token::COMMA:
VisitNaryCommaExpression(expr);
break;
case Token::OR:
VisitNaryLogicalOrExpression(expr);
break;
case Token::AND:
VisitNaryLogicalAndExpression(expr);
break;
case Token::NULLISH:
VisitNaryNullishExpression(expr);
break;
default:
VisitNaryArithmeticExpression(expr);
break;
}
}
void BytecodeGenerator::BuildLiteralCompareNil(
Token::Value op, BytecodeArrayBuilder::NilValue nil) {
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
switch (test_result->fallthrough()) {
case TestFallthrough::kThen:
builder()->JumpIfNotNil(test_result->NewElseLabel(), op, nil);
break;
case TestFallthrough::kElse:
builder()->JumpIfNil(test_result->NewThenLabel(), op, nil);
break;
case TestFallthrough::kNone:
builder()
->JumpIfNil(test_result->NewThenLabel(), op, nil)
.Jump(test_result->NewElseLabel());
}
test_result->SetResultConsumedByTest();
} else {
builder()->CompareNil(op, nil);
}
}
void BytecodeGenerator::VisitCompareOperation(CompareOperation* expr) {
Expression* sub_expr;
Literal* literal;
if (expr->IsLiteralCompareTypeof(&sub_expr, &literal)) {
// Emit a fast literal comparion for expressions of the form:
// typeof(x) === 'string'.
VisitForTypeOfValue(sub_expr);
builder()->SetExpressionPosition(expr);
TestTypeOfFlags::LiteralFlag literal_flag =
TestTypeOfFlags::GetFlagForLiteral(ast_string_constants(), literal);
if (literal_flag == TestTypeOfFlags::LiteralFlag::kOther) {
builder()->LoadFalse();
} else {
builder()->CompareTypeOf(literal_flag);
}
} else if (expr->IsLiteralCompareUndefined(&sub_expr)) {
VisitForAccumulatorValue(sub_expr);
builder()->SetExpressionPosition(expr);
BuildLiteralCompareNil(expr->op(), BytecodeArrayBuilder::kUndefinedValue);
} else if (expr->IsLiteralCompareNull(&sub_expr)) {
VisitForAccumulatorValue(sub_expr);
builder()->SetExpressionPosition(expr);
BuildLiteralCompareNil(expr->op(), BytecodeArrayBuilder::kNullValue);
} else {
Register lhs = VisitForRegisterValue(expr->left());
VisitForAccumulatorValue(expr->right());
builder()->SetExpressionPosition(expr);
FeedbackSlot slot;
if (expr->op() == Token::IN) {
slot = feedback_spec()->AddKeyedHasICSlot();
} else if (expr->op() == Token::INSTANCEOF) {
slot = feedback_spec()->AddInstanceOfSlot();
} else {
slot = feedback_spec()->AddCompareICSlot();
}
builder()->CompareOperation(expr->op(), lhs, feedback_index(slot));
}
// Always returns a boolean value.
execution_result()->SetResultIsBoolean();
}
void BytecodeGenerator::VisitArithmeticExpression(BinaryOperation* expr) {
FeedbackSlot slot = feedback_spec()->AddBinaryOpICSlot();
Expression* subexpr;
Smi literal;
if (expr->IsSmiLiteralOperation(&subexpr, &literal)) {
TypeHint type_hint = VisitForAccumulatorValue(subexpr);
builder()->SetExpressionPosition(expr);
builder()->BinaryOperationSmiLiteral(expr->op(), literal,
feedback_index(slot));
if (expr->op() == Token::ADD && type_hint == TypeHint::kString) {
execution_result()->SetResultIsString();
}
} else {
TypeHint lhs_type = VisitForAccumulatorValue(expr->left());
Register lhs = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(lhs);
TypeHint rhs_type = VisitForAccumulatorValue(expr->right());
if (expr->op() == Token::ADD &&
(lhs_type == TypeHint::kString || rhs_type == TypeHint::kString)) {
execution_result()->SetResultIsString();
}
builder()->SetExpressionPosition(expr);
builder()->BinaryOperation(expr->op(), lhs, feedback_index(slot));
}
}
void BytecodeGenerator::VisitNaryArithmeticExpression(NaryOperation* expr) {
// TODO(leszeks): Add support for lhs smi in commutative ops.
TypeHint type_hint = VisitForAccumulatorValue(expr->first());
for (size_t i = 0; i < expr->subsequent_length(); ++i) {
RegisterAllocationScope register_scope(this);
if (expr->subsequent(i)->IsSmiLiteral()) {
builder()->SetExpressionPosition(expr->subsequent_op_position(i));
builder()->BinaryOperationSmiLiteral(
expr->op(), expr->subsequent(i)->AsLiteral()->AsSmiLiteral(),
feedback_index(feedback_spec()->AddBinaryOpICSlot()));
} else {
Register lhs = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(lhs);
TypeHint rhs_hint = VisitForAccumulatorValue(expr->subsequent(i));
if (rhs_hint == TypeHint::kString) type_hint = TypeHint::kString;
builder()->SetExpressionPosition(expr->subsequent_op_position(i));
builder()->BinaryOperation(
expr->op(), lhs,
feedback_index(feedback_spec()->AddBinaryOpICSlot()));
}
}
if (type_hint == TypeHint::kString && expr->op() == Token::ADD) {
// If any operand of an ADD is a String, a String is produced.
execution_result()->SetResultIsString();
}
}
// Note: the actual spreading is performed by the surrounding expression's
// visitor.
void BytecodeGenerator::VisitSpread(Spread* expr) { Visit(expr->expression()); }
void BytecodeGenerator::VisitEmptyParentheses(EmptyParentheses* expr) {
UNREACHABLE();
}
void BytecodeGenerator::VisitImportCallExpression(ImportCallExpression* expr) {
RegisterList args = register_allocator()->NewRegisterList(2);
VisitForRegisterValue(expr->argument(), args[1]);
builder()
->MoveRegister(Register::function_closure(), args[0])
.CallRuntime(Runtime::kDynamicImportCall, args);
}
void BytecodeGenerator::BuildGetIterator(IteratorType hint) {
if (hint == IteratorType::kAsync) {
RegisterAllocationScope scope(this);
Register obj = register_allocator()->NewRegister();
Register method = register_allocator()->NewRegister();
// Set method to GetMethod(obj, @@asyncIterator)
builder()->StoreAccumulatorInRegister(obj).LoadAsyncIteratorProperty(
obj, feedback_index(feedback_spec()->AddLoadICSlot()));
BytecodeLabel async_iterator_undefined, done;
builder()->JumpIfUndefinedOrNull(&async_iterator_undefined);
// Let iterator be Call(method, obj)
builder()->StoreAccumulatorInRegister(method).CallProperty(
method, RegisterList(obj),
feedback_index(feedback_spec()->AddCallICSlot()));
// If Type(iterator) is not Object, throw a TypeError exception.
builder()->JumpIfJSReceiver(&done);
builder()->CallRuntime(Runtime::kThrowSymbolAsyncIteratorInvalid);
builder()->Bind(&async_iterator_undefined);
// If method is undefined,
// Let syncMethod be GetMethod(obj, @@iterator)
builder()
->LoadIteratorProperty(obj,
feedback_index(feedback_spec()->AddLoadICSlot()))
.StoreAccumulatorInRegister(method);
// Let syncIterator be Call(syncMethod, obj)
builder()->CallProperty(method, RegisterList(obj),
feedback_index(feedback_spec()->AddCallICSlot()));
// Return CreateAsyncFromSyncIterator(syncIterator)
// alias `method` register as it's no longer used
Register sync_iter = method;
builder()->StoreAccumulatorInRegister(sync_iter).CallRuntime(
Runtime::kInlineCreateAsyncFromSyncIterator, sync_iter);
builder()->Bind(&done);
} else {
{
RegisterAllocationScope scope(this);
Register obj = register_allocator()->NewRegister();
int load_feedback_index =
feedback_index(feedback_spec()->AddLoadICSlot());
int call_feedback_index =
feedback_index(feedback_spec()->AddCallICSlot());
// Let method be GetMethod(obj, @@iterator) and
// iterator be Call(method, obj).
builder()->StoreAccumulatorInRegister(obj).GetIterator(
obj, load_feedback_index, call_feedback_index);
}
// If Type(iterator) is not Object, throw a TypeError exception.
BytecodeLabel no_type_error;
builder()->JumpIfJSReceiver(&no_type_error);
builder()->CallRuntime(Runtime::kThrowSymbolIteratorInvalid);
builder()->Bind(&no_type_error);
}
}
// Returns an IteratorRecord which is valid for the lifetime of the current
// register_allocation_scope.
BytecodeGenerator::IteratorRecord BytecodeGenerator::BuildGetIteratorRecord(
Register next, Register object, IteratorType hint) {
DCHECK(next.is_valid() && object.is_valid());
BuildGetIterator(hint);
builder()
->StoreAccumulatorInRegister(object)
.LoadNamedProperty(object, ast_string_constants()->next_string(),
feedback_index(feedback_spec()->AddLoadICSlot()))
.StoreAccumulatorInRegister(next);
return IteratorRecord(object, next, hint);
}
BytecodeGenerator::IteratorRecord BytecodeGenerator::BuildGetIteratorRecord(
IteratorType hint) {
Register next = register_allocator()->NewRegister();
Register object = register_allocator()->NewRegister();
return BuildGetIteratorRecord(next, object, hint);
}
void BytecodeGenerator::BuildIteratorNext(const IteratorRecord& iterator,
Register next_result) {
DCHECK(next_result.is_valid());
builder()->CallProperty(iterator.next(), RegisterList(iterator.object()),
feedback_index(feedback_spec()->AddCallICSlot()));
if (iterator.type() == IteratorType::kAsync) {
BuildAwait();
}
BytecodeLabel is_object;
builder()
->StoreAccumulatorInRegister(next_result)
.JumpIfJSReceiver(&is_object)
.CallRuntime(Runtime::kThrowIteratorResultNotAnObject, next_result)
.Bind(&is_object);
}
void BytecodeGenerator::BuildCallIteratorMethod(Register iterator,
const AstRawString* method_name,
RegisterList receiver_and_args,
BytecodeLabel* if_called,
BytecodeLabels* if_notcalled) {
RegisterAllocationScope register_scope(this);
Register method = register_allocator()->NewRegister();
FeedbackSlot slot = feedback_spec()->AddLoadICSlot();
builder()
->LoadNamedProperty(iterator, method_name, feedback_index(slot))
.JumpIfUndefinedOrNull(if_notcalled->New())
.StoreAccumulatorInRegister(method)
.CallProperty(method, receiver_and_args,
feedback_index(feedback_spec()->AddCallICSlot()))
.Jump(if_called);
}
void BytecodeGenerator::BuildIteratorClose(const IteratorRecord& iterator,
Expression* expr) {
RegisterAllocationScope register_scope(this);
BytecodeLabels done(zone());
BytecodeLabel if_called;
RegisterList args = RegisterList(iterator.object());
BuildCallIteratorMethod(iterator.object(),
ast_string_constants()->return_string(), args,
&if_called, &done);
builder()->Bind(&if_called);
if (iterator.type() == IteratorType::kAsync) {
DCHECK_NOT_NULL(expr);
BuildAwait(expr->position());
}
builder()->JumpIfJSReceiver(done.New());
{
RegisterAllocationScope register_scope(this);
Register return_result = register_allocator()->NewRegister();
builder()
->StoreAccumulatorInRegister(return_result)
.CallRuntime(Runtime::kThrowIteratorResultNotAnObject, return_result);
}
done.Bind(builder());
}
void BytecodeGenerator::VisitGetTemplateObject(GetTemplateObject* expr) {
builder()->SetExpressionPosition(expr);
size_t entry = builder()->AllocateDeferredConstantPoolEntry();
template_objects_.push_back(std::make_pair(expr, entry));
FeedbackSlot literal_slot = feedback_spec()->AddLiteralSlot();
builder()->GetTemplateObject(entry, feedback_index(literal_slot));
}
void BytecodeGenerator::VisitTemplateLiteral(TemplateLiteral* expr) {
const ZonePtrList<const AstRawString>& parts = *expr->string_parts();
const ZonePtrList<Expression>& substitutions = *expr->substitutions();
// Template strings with no substitutions are turned into StringLiterals.
DCHECK_GT(substitutions.length(), 0);
DCHECK_EQ(parts.length(), substitutions.length() + 1);
// Generate string concatenation
// TODO(caitp): Don't generate feedback slot if it's not used --- introduce
// a simple, concise, reusable mechanism to lazily create reusable slots.
FeedbackSlot slot = feedback_spec()->AddBinaryOpICSlot();
Register last_part = register_allocator()->NewRegister();
bool last_part_valid = false;
builder()->SetExpressionPosition(expr);
for (int i = 0; i < substitutions.length(); ++i) {
if (i != 0) {
builder()->StoreAccumulatorInRegister(last_part);
last_part_valid = true;
}
if (!parts[i]->IsEmpty()) {
builder()->LoadLiteral(parts[i]);
if (last_part_valid) {
builder()->BinaryOperation(Token::ADD, last_part, feedback_index(slot));
}
builder()->StoreAccumulatorInRegister(last_part);
last_part_valid = true;
}
TypeHint type_hint = VisitForAccumulatorValue(substitutions[i]);
if (type_hint != TypeHint::kString) {
builder()->ToString();
}
if (last_part_valid) {
builder()->BinaryOperation(Token::ADD, last_part, feedback_index(slot));
}
last_part_valid = false;
}
if (!parts.last()->IsEmpty()) {
builder()->StoreAccumulatorInRegister(last_part);
builder()->LoadLiteral(parts.last());
builder()->BinaryOperation(Token::ADD, last_part, feedback_index(slot));
}
}
void BytecodeGenerator::BuildThisVariableLoad() {
DeclarationScope* receiver_scope = closure_scope()->GetReceiverScope();
Variable* var = receiver_scope->receiver();
// TODO(littledan): implement 'this' hole check elimination.
HoleCheckMode hole_check_mode =
IsDerivedConstructor(receiver_scope->function_kind())
? HoleCheckMode::kRequired
: HoleCheckMode::kElided;
BuildVariableLoad(var, hole_check_mode);
}
void BytecodeGenerator::VisitThisExpression(ThisExpression* expr) {
BuildThisVariableLoad();
}
void BytecodeGenerator::VisitSuperCallReference(SuperCallReference* expr) {
// Handled by VisitCall().
UNREACHABLE();
}
void BytecodeGenerator::VisitSuperPropertyReference(
SuperPropertyReference* expr) {
builder()->CallRuntime(Runtime::kThrowUnsupportedSuperError);
}
void BytecodeGenerator::VisitCommaExpression(BinaryOperation* binop) {
VisitForEffect(binop->left());
Visit(binop->right());
}
void BytecodeGenerator::VisitNaryCommaExpression(NaryOperation* expr) {
DCHECK_GT(expr->subsequent_length(), 0);
VisitForEffect(expr->first());
for (size_t i = 0; i < expr->subsequent_length() - 1; ++i) {
VisitForEffect(expr->subsequent(i));
}
Visit(expr->subsequent(expr->subsequent_length() - 1));
}
void BytecodeGenerator::VisitLogicalTestSubExpression(
Token::Value token, Expression* expr, BytecodeLabels* then_labels,
BytecodeLabels* else_labels, int coverage_slot) {
DCHECK(token == Token::OR || token == Token::AND || token == Token::NULLISH);
BytecodeLabels test_next(zone());
if (token == Token::OR) {
VisitForTest(expr, then_labels, &test_next, TestFallthrough::kElse);
} else if (token == Token::AND) {
VisitForTest(expr, &test_next, else_labels, TestFallthrough::kThen);
} else {
DCHECK_EQ(Token::NULLISH, token);
VisitForNullishTest(expr, then_labels, &test_next, else_labels);
}
test_next.Bind(builder());
BuildIncrementBlockCoverageCounterIfEnabled(coverage_slot);
}
void BytecodeGenerator::VisitLogicalTest(Token::Value token, Expression* left,
Expression* right,
int right_coverage_slot) {
DCHECK(token == Token::OR || token == Token::AND || token == Token::NULLISH);
TestResultScope* test_result = execution_result()->AsTest();
BytecodeLabels* then_labels = test_result->then_labels();
BytecodeLabels* else_labels = test_result->else_labels();
TestFallthrough fallthrough = test_result->fallthrough();
VisitLogicalTestSubExpression(token, left, then_labels, else_labels,
right_coverage_slot);
// The last test has the same then, else and fallthrough as the parent test.
VisitForTest(right, then_labels, else_labels, fallthrough);
}
void BytecodeGenerator::VisitNaryLogicalTest(
Token::Value token, NaryOperation* expr,
const NaryCodeCoverageSlots* coverage_slots) {
DCHECK(token == Token::OR || token == Token::AND || token == Token::NULLISH);
DCHECK_GT(expr->subsequent_length(), 0);
TestResultScope* test_result = execution_result()->AsTest();
BytecodeLabels* then_labels = test_result->then_labels();
BytecodeLabels* else_labels = test_result->else_labels();
TestFallthrough fallthrough = test_result->fallthrough();
VisitLogicalTestSubExpression(token, expr->first(), then_labels, else_labels,
coverage_slots->GetSlotFor(0));
for (size_t i = 0; i < expr->subsequent_length() - 1; ++i) {
VisitLogicalTestSubExpression(token, expr->subsequent(i), then_labels,
else_labels,
coverage_slots->GetSlotFor(i + 1));
}
// The last test has the same then, else and fallthrough as the parent test.
VisitForTest(expr->subsequent(expr->subsequent_length() - 1), then_labels,
else_labels, fallthrough);
}
bool BytecodeGenerator::VisitLogicalOrSubExpression(Expression* expr,
BytecodeLabels* end_labels,
int coverage_slot) {
if (expr->ToBooleanIsTrue()) {
VisitForAccumulatorValue(expr);
end_labels->Bind(builder());
return true;
} else if (!expr->ToBooleanIsFalse()) {
TypeHint type_hint = VisitForAccumulatorValue(expr);
builder()->JumpIfTrue(ToBooleanModeFromTypeHint(type_hint),
end_labels->New());
}
BuildIncrementBlockCoverageCounterIfEnabled(coverage_slot);
return false;
}
bool BytecodeGenerator::VisitLogicalAndSubExpression(Expression* expr,
BytecodeLabels* end_labels,
int coverage_slot) {
if (expr->ToBooleanIsFalse()) {
VisitForAccumulatorValue(expr);
end_labels->Bind(builder());
return true;
} else if (!expr->ToBooleanIsTrue()) {
TypeHint type_hint = VisitForAccumulatorValue(expr);
builder()->JumpIfFalse(ToBooleanModeFromTypeHint(type_hint),
end_labels->New());
}
BuildIncrementBlockCoverageCounterIfEnabled(coverage_slot);
return false;
}
bool BytecodeGenerator::VisitNullishSubExpression(Expression* expr,
BytecodeLabels* end_labels,
int coverage_slot) {
if (expr->IsLiteralButNotNullOrUndefined()) {
VisitForAccumulatorValue(expr);
end_labels->Bind(builder());
return true;
} else if (!expr->IsNullOrUndefinedLiteral()) {
VisitForAccumulatorValue(expr);
BytecodeLabel is_null_or_undefined;
builder()
->JumpIfUndefinedOrNull(&is_null_or_undefined)
.Jump(end_labels->New());
builder()->Bind(&is_null_or_undefined);
}
BuildIncrementBlockCoverageCounterIfEnabled(coverage_slot);
return false;
}
void BytecodeGenerator::VisitLogicalOrExpression(BinaryOperation* binop) {
Expression* left = binop->left();
Expression* right = binop->right();
int right_coverage_slot =
AllocateBlockCoverageSlotIfEnabled(binop, SourceRangeKind::kRight);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (left->ToBooleanIsTrue()) {
builder()->Jump(test_result->NewThenLabel());
} else if (left->ToBooleanIsFalse() && right->ToBooleanIsFalse()) {
BuildIncrementBlockCoverageCounterIfEnabled(right_coverage_slot);
builder()->Jump(test_result->NewElseLabel());
} else {
VisitLogicalTest(Token::OR, left, right, right_coverage_slot);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitLogicalOrSubExpression(left, &end_labels, right_coverage_slot)) {
return;
}
VisitForAccumulatorValue(right);
end_labels.Bind(builder());
}
}
void BytecodeGenerator::VisitNaryLogicalOrExpression(NaryOperation* expr) {
Expression* first = expr->first();
DCHECK_GT(expr->subsequent_length(), 0);
NaryCodeCoverageSlots coverage_slots(this, expr);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (first->ToBooleanIsTrue()) {
builder()->Jump(test_result->NewThenLabel());
} else {
VisitNaryLogicalTest(Token::OR, expr, &coverage_slots);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitLogicalOrSubExpression(first, &end_labels,
coverage_slots.GetSlotFor(0))) {
return;
}
for (size_t i = 0; i < expr->subsequent_length() - 1; ++i) {
if (VisitLogicalOrSubExpression(expr->subsequent(i), &end_labels,
coverage_slots.GetSlotFor(i + 1))) {
return;
}
}
// We have to visit the last value even if it's true, because we need its
// actual value.
VisitForAccumulatorValue(expr->subsequent(expr->subsequent_length() - 1));
end_labels.Bind(builder());
}
}
void BytecodeGenerator::VisitLogicalAndExpression(BinaryOperation* binop) {
Expression* left = binop->left();
Expression* right = binop->right();
int right_coverage_slot =
AllocateBlockCoverageSlotIfEnabled(binop, SourceRangeKind::kRight);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (left->ToBooleanIsFalse()) {
builder()->Jump(test_result->NewElseLabel());
} else if (left->ToBooleanIsTrue() && right->ToBooleanIsTrue()) {
BuildIncrementBlockCoverageCounterIfEnabled(right_coverage_slot);
builder()->Jump(test_result->NewThenLabel());
} else {
VisitLogicalTest(Token::AND, left, right, right_coverage_slot);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitLogicalAndSubExpression(left, &end_labels, right_coverage_slot)) {
return;
}
VisitForAccumulatorValue(right);
end_labels.Bind(builder());
}
}
void BytecodeGenerator::VisitNaryLogicalAndExpression(NaryOperation* expr) {
Expression* first = expr->first();
DCHECK_GT(expr->subsequent_length(), 0);
NaryCodeCoverageSlots coverage_slots(this, expr);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (first->ToBooleanIsFalse()) {
builder()->Jump(test_result->NewElseLabel());
} else {
VisitNaryLogicalTest(Token::AND, expr, &coverage_slots);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitLogicalAndSubExpression(first, &end_labels,
coverage_slots.GetSlotFor(0))) {
return;
}
for (size_t i = 0; i < expr->subsequent_length() - 1; ++i) {
if (VisitLogicalAndSubExpression(expr->subsequent(i), &end_labels,
coverage_slots.GetSlotFor(i + 1))) {
return;
}
}
// We have to visit the last value even if it's false, because we need its
// actual value.
VisitForAccumulatorValue(expr->subsequent(expr->subsequent_length() - 1));
end_labels.Bind(builder());
}
}
void BytecodeGenerator::VisitNullishExpression(BinaryOperation* binop) {
Expression* left = binop->left();
Expression* right = binop->right();
int right_coverage_slot =
AllocateBlockCoverageSlotIfEnabled(binop, SourceRangeKind::kRight);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (left->IsLiteralButNotNullOrUndefined() && left->ToBooleanIsTrue()) {
builder()->Jump(test_result->NewThenLabel());
} else if (left->IsNullOrUndefinedLiteral() &&
right->IsNullOrUndefinedLiteral()) {
BuildIncrementBlockCoverageCounterIfEnabled(right_coverage_slot);
builder()->Jump(test_result->NewElseLabel());
} else {
VisitLogicalTest(Token::NULLISH, left, right, right_coverage_slot);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitNullishSubExpression(left, &end_labels, right_coverage_slot)) {
return;
}
VisitForAccumulatorValue(right);
end_labels.Bind(builder());
}
}
void BytecodeGenerator::VisitNaryNullishExpression(NaryOperation* expr) {
Expression* first = expr->first();
DCHECK_GT(expr->subsequent_length(), 0);
NaryCodeCoverageSlots coverage_slots(this, expr);
if (execution_result()->IsTest()) {
TestResultScope* test_result = execution_result()->AsTest();
if (first->IsLiteralButNotNullOrUndefined() && first->ToBooleanIsTrue()) {
builder()->Jump(test_result->NewThenLabel());
} else {
VisitNaryLogicalTest(Token::NULLISH, expr, &coverage_slots);
}
test_result->SetResultConsumedByTest();
} else {
BytecodeLabels end_labels(zone());
if (VisitNullishSubExpression(first, &end_labels,
coverage_slots.GetSlotFor(0))) {
return;
}
for (size_t i = 0; i < expr->subsequent_length() - 1; ++i) {
if (VisitNullishSubExpression(expr->subsequent(i), &end_labels,
coverage_slots.GetSlotFor(i + 1))) {
return;
}
}
// We have to visit the last value even if it's nullish, because we need its
// actual value.
VisitForAccumulatorValue(expr->subsequent(expr->subsequent_length() - 1));
end_labels.Bind(builder());
}
}
void BytecodeGenerator::BuildNewLocalActivationContext() {
ValueResultScope value_execution_result(this);
Scope* scope = closure_scope();
DCHECK_EQ(current_scope(), closure_scope());
// Create the appropriate context.
DCHECK(scope->is_function_scope() || scope->is_eval_scope());
int slot_count = scope->num_heap_slots() - Context::MIN_CONTEXT_SLOTS;
if (slot_count <= ConstructorBuiltins::MaximumFunctionContextSlots()) {
switch (scope->scope_type()) {
case EVAL_SCOPE:
builder()->CreateEvalContext(scope, slot_count);
break;
case FUNCTION_SCOPE:
builder()->CreateFunctionContext(scope, slot_count);
break;
default:
UNREACHABLE();
}
} else {
Register arg = register_allocator()->NewRegister();
builder()->LoadLiteral(scope).StoreAccumulatorInRegister(arg).CallRuntime(
Runtime::kNewFunctionContext, arg);
}
}
void BytecodeGenerator::BuildLocalActivationContextInitialization() {
DeclarationScope* scope = closure_scope();
if (scope->has_this_declaration() && scope->receiver()->IsContextSlot()) {
Variable* variable = scope->receiver();
Register receiver(builder()->Receiver());
// Context variable (at bottom of the context chain).
DCHECK_EQ(0, scope->ContextChainLength(variable->scope()));
builder()->LoadAccumulatorWithRegister(receiver).StoreContextSlot(
execution_context()->reg(), variable->index(), 0);
}
// Copy parameters into context if necessary.
int num_parameters = scope->num_parameters();
for (int i = 0; i < num_parameters; i++) {
Variable* variable = scope->parameter(i);
if (!variable->IsContextSlot()) continue;
Register parameter(builder()->Parameter(i));
// Context variable (at bottom of the context chain).
DCHECK_EQ(0, scope->ContextChainLength(variable->scope()));
builder()->LoadAccumulatorWithRegister(parameter).StoreContextSlot(
execution_context()->reg(), variable->index(), 0);
}
}
void BytecodeGenerator::BuildNewLocalBlockContext(Scope* scope) {
ValueResultScope value_execution_result(this);
DCHECK(scope->is_block_scope());
builder()->CreateBlockContext(scope);
}
void BytecodeGenerator::BuildNewLocalWithContext(Scope* scope) {
ValueResultScope value_execution_result(this);
Register extension_object = register_allocator()->NewRegister();
builder()->ToObject(extension_object);
builder()->CreateWithContext(extension_object, scope);
}
void BytecodeGenerator::BuildNewLocalCatchContext(Scope* scope) {
ValueResultScope value_execution_result(this);
DCHECK(scope->catch_variable()->IsContextSlot());
Register exception = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(exception);
builder()->CreateCatchContext(exception, scope);
}
void BytecodeGenerator::VisitLiteralAccessor(Register home_object,
LiteralProperty* property,
Register value_out) {
if (property == nullptr) {
builder()->LoadNull().StoreAccumulatorInRegister(value_out);
} else {
VisitForRegisterValue(property->value(), value_out);
VisitSetHomeObject(value_out, home_object, property);
}
}
void BytecodeGenerator::VisitSetHomeObject(Register value, Register home_object,
LiteralProperty* property) {
Expression* expr = property->value();
if (FunctionLiteral::NeedsHomeObject(expr)) {
FeedbackSlot slot = feedback_spec()->AddStoreICSlot(language_mode());
builder()
->LoadAccumulatorWithRegister(home_object)
.StoreHomeObjectProperty(value, feedback_index(slot), language_mode());
}
}
void BytecodeGenerator::VisitArgumentsObject(Variable* variable) {
if (variable == nullptr) return;
DCHECK(variable->IsContextSlot() || variable->IsStackAllocated());
// Allocate and initialize a new arguments object and assign to the
// {arguments} variable.
builder()->CreateArguments(closure_scope()->GetArgumentsType());
BuildVariableAssignment(variable, Token::ASSIGN, HoleCheckMode::kElided);
}
void BytecodeGenerator::VisitRestArgumentsArray(Variable* rest) {
if (rest == nullptr) return;
// Allocate and initialize a new rest parameter and assign to the {rest}
// variable.
builder()->CreateArguments(CreateArgumentsType::kRestParameter);
DCHECK(rest->IsContextSlot() || rest->IsStackAllocated());
BuildVariableAssignment(rest, Token::ASSIGN, HoleCheckMode::kElided);
}
void BytecodeGenerator::VisitThisFunctionVariable(Variable* variable) {
if (variable == nullptr) return;
// Store the closure we were called with in the given variable.
builder()->LoadAccumulatorWithRegister(Register::function_closure());
BuildVariableAssignment(variable, Token::INIT, HoleCheckMode::kElided);
}
void BytecodeGenerator::VisitNewTargetVariable(Variable* variable) {
if (variable == nullptr) return;
// The generator resume trampoline abuses the new.target register
// to pass in the generator object. In ordinary calls, new.target is always
// undefined because generator functions are non-constructible, so don't
// assign anything to the new.target variable.
if (IsResumableFunction(info()->literal()->kind())) return;
if (variable->location() == VariableLocation::LOCAL) {
// The new.target register was already assigned by entry trampoline.
DCHECK_EQ(incoming_new_target_or_generator_.index(),
GetRegisterForLocalVariable(variable).index());
return;
}
// Store the new target we were called with in the given variable.
builder()->LoadAccumulatorWithRegister(incoming_new_target_or_generator_);
BuildVariableAssignment(variable, Token::INIT, HoleCheckMode::kElided);
}
void BytecodeGenerator::BuildGeneratorObjectVariableInitialization() {
DCHECK(IsResumableFunction(info()->literal()->kind()));
Variable* generator_object_var = closure_scope()->generator_object_var();
RegisterAllocationScope register_scope(this);
RegisterList args = register_allocator()->NewRegisterList(2);
Runtime::FunctionId function_id =
((IsAsyncFunction(info()->literal()->kind()) &&
!IsAsyncGeneratorFunction(info()->literal()->kind())) ||
IsAsyncModule(info()->literal()->kind()))
? Runtime::kInlineAsyncFunctionEnter
: Runtime::kInlineCreateJSGeneratorObject;
builder()
->MoveRegister(Register::function_closure(), args[0])
.MoveRegister(builder()->Receiver(), args[1])
.CallRuntime(function_id, args)
.StoreAccumulatorInRegister(generator_object());
if (generator_object_var->location() == VariableLocation::LOCAL) {
// The generator object register is already set to the variable's local
// register.
DCHECK_EQ(generator_object().index(),
GetRegisterForLocalVariable(generator_object_var).index());
} else {
BuildVariableAssignment(generator_object_var, Token::INIT,
HoleCheckMode::kElided);
}
}
void BytecodeGenerator::BuildPushUndefinedIntoRegisterList(
RegisterList* reg_list) {
Register reg = register_allocator()->GrowRegisterList(reg_list);
builder()->LoadUndefined().StoreAccumulatorInRegister(reg);
}
void BytecodeGenerator::BuildLoadPropertyKey(LiteralProperty* property,
Register out_reg) {
if (property->key()->IsStringLiteral()) {
builder()
->LoadLiteral(property->key()->AsLiteral()->AsRawString())
.StoreAccumulatorInRegister(out_reg);
} else {
VisitForAccumulatorValue(property->key());
builder()->ToName(out_reg);
}
}
int BytecodeGenerator::AllocateBlockCoverageSlotIfEnabled(
AstNode* node, SourceRangeKind kind) {
return (block_coverage_builder_ == nullptr)
? BlockCoverageBuilder::kNoCoverageArraySlot
: block_coverage_builder_->AllocateBlockCoverageSlot(node, kind);
}
int BytecodeGenerator::AllocateNaryBlockCoverageSlotIfEnabled(
NaryOperation* node, size_t index) {
return (block_coverage_builder_ == nullptr)
? BlockCoverageBuilder::kNoCoverageArraySlot
: block_coverage_builder_->AllocateNaryBlockCoverageSlot(node,
index);
}
void BytecodeGenerator::BuildIncrementBlockCoverageCounterIfEnabled(
AstNode* node, SourceRangeKind kind) {
if (block_coverage_builder_ == nullptr) return;
block_coverage_builder_->IncrementBlockCounter(node, kind);
}
void BytecodeGenerator::BuildIncrementBlockCoverageCounterIfEnabled(
int coverage_array_slot) {
if (block_coverage_builder_ != nullptr) {
block_coverage_builder_->IncrementBlockCounter(coverage_array_slot);
}
}
// Visits the expression |expr| and places the result in the accumulator.
BytecodeGenerator::TypeHint BytecodeGenerator::VisitForAccumulatorValue(
Expression* expr) {
ValueResultScope accumulator_scope(this);
Visit(expr);
return accumulator_scope.type_hint();
}
void BytecodeGenerator::VisitForAccumulatorValueOrTheHole(Expression* expr) {
if (expr == nullptr) {
builder()->LoadTheHole();
} else {
VisitForAccumulatorValue(expr);
}
}
// Visits the expression |expr| and discards the result.
void BytecodeGenerator::VisitForEffect(Expression* expr) {
EffectResultScope effect_scope(this);
Visit(expr);
}
// Visits the expression |expr| and returns the register containing
// the expression result.
Register BytecodeGenerator::VisitForRegisterValue(Expression* expr) {
VisitForAccumulatorValue(expr);
Register result = register_allocator()->NewRegister();
builder()->StoreAccumulatorInRegister(result);
return result;
}
// Visits the expression |expr| and stores the expression result in
// |destination|.
void BytecodeGenerator::VisitForRegisterValue(Expression* expr,
Register destination) {
ValueResultScope register_scope(this);
Visit(expr);
builder()->StoreAccumulatorInRegister(destination);
}
// Visits the expression |expr| and pushes the result into a new register
// added to the end of |reg_list|.
void BytecodeGenerator::VisitAndPushIntoRegisterList(Expression* expr,
RegisterList* reg_list) {
{
ValueResultScope register_scope(this);
Visit(expr);
}
// Grow the register list after visiting the expression to avoid reserving
// the register across the expression evaluation, which could cause memory
// leaks for deep expressions due to dead objects being kept alive by pointers
// in registers.
Register destination = register_allocator()->GrowRegisterList(reg_list);
builder()->StoreAccumulatorInRegister(destination);
}
void BytecodeGenerator::BuildTest(ToBooleanMode mode,
BytecodeLabels* then_labels,
BytecodeLabels* else_labels,
TestFallthrough fallthrough) {
switch (fallthrough) {
case TestFallthrough::kThen:
builder()->JumpIfFalse(mode, else_labels->New());
break;
case TestFallthrough::kElse:
builder()->JumpIfTrue(mode, then_labels->New());
break;
case TestFallthrough::kNone:
builder()->JumpIfTrue(mode, then_labels->New());
builder()->Jump(else_labels->New());
break;
}
}
// Visits the expression |expr| for testing its boolean value and jumping to the
// |then| or |other| label depending on value and short-circuit semantics
void BytecodeGenerator::VisitForTest(Expression* expr,
BytecodeLabels* then_labels,
BytecodeLabels* else_labels,
TestFallthrough fallthrough) {
bool result_consumed;
TypeHint type_hint;
{
// To make sure that all temporary registers are returned before generating
// jumps below, we ensure that the result scope is deleted before doing so.
// Dead registers might be materialized otherwise.
TestResultScope test_result(this, then_labels, else_labels, fallthrough);
Visit(expr);
result_consumed = test_result.result_consumed_by_test();
type_hint = test_result.type_hint();
// Labels and fallthrough might have been mutated, so update based on
// TestResultScope.
then_labels = test_result.then_labels();
else_labels = test_result.else_labels();
fallthrough = test_result.fallthrough();
}
if (!result_consumed) {
BuildTest(ToBooleanModeFromTypeHint(type_hint), then_labels, else_labels,
fallthrough);
}
}
// Visits the expression |expr| for testing its nullish value and jumping to the
// |then| or |other| label depending on value and short-circuit semantics
void BytecodeGenerator::VisitForNullishTest(Expression* expr,
BytecodeLabels* then_labels,
BytecodeLabels* test_next_labels,
BytecodeLabels* else_labels) {
// Nullish short circuits on undefined or null, otherwise we fall back to
// BuildTest with no fallthrough.
// TODO(joshualitt): We should do this in a TestResultScope.
TypeHint type_hint = VisitForAccumulatorValue(expr);
ToBooleanMode mode = ToBooleanModeFromTypeHint(type_hint);
// Skip the nullish shortcircuit if we already have a boolean.
if (mode != ToBooleanMode::kAlreadyBoolean) {
builder()->JumpIfUndefinedOrNull(test_next_labels->New());
}
BuildTest(mode, then_labels, else_labels, TestFallthrough::kNone);
}
void BytecodeGenerator::VisitInSameTestExecutionScope(Expression* expr) {
DCHECK(execution_result()->IsTest());
{
RegisterAllocationScope reg_scope(this);
Visit(expr);
}
if (!execution_result()->AsTest()->result_consumed_by_test()) {
TestResultScope* result_scope = execution_result()->AsTest();
BuildTest(ToBooleanModeFromTypeHint(result_scope->type_hint()),
result_scope->then_labels(), result_scope->else_labels(),
result_scope->fallthrough());
result_scope->SetResultConsumedByTest();
}
}
void BytecodeGenerator::VisitInScope(Statement* stmt, Scope* scope) {
DCHECK(scope->declarations()->is_empty());
CurrentScope current_scope(this, scope);
ContextScope context_scope(this, scope);
Visit(stmt);
}
Register BytecodeGenerator::GetRegisterForLocalVariable(Variable* variable) {
DCHECK_EQ(VariableLocation::LOCAL, variable->location());
return builder()->Local(variable->index());
}
FunctionKind BytecodeGenerator::function_kind() const {
return info()->literal()->kind();
}
LanguageMode BytecodeGenerator::language_mode() const {
return current_scope()->language_mode();
}
Register BytecodeGenerator::generator_object() const {
DCHECK(IsResumableFunction(info()->literal()->kind()));
return incoming_new_target_or_generator_;
}
FeedbackVectorSpec* BytecodeGenerator::feedback_spec() {
return info()->feedback_vector_spec();
}
int BytecodeGenerator::feedback_index(FeedbackSlot slot) const {
DCHECK(!slot.IsInvalid());
return FeedbackVector::GetIndex(slot);
}
FeedbackSlot BytecodeGenerator::GetCachedLoadGlobalICSlot(
TypeofMode typeof_mode, Variable* variable) {
FeedbackSlotCache::SlotKind slot_kind =
typeof_mode == INSIDE_TYPEOF
? FeedbackSlotCache::SlotKind::kLoadGlobalInsideTypeof
: FeedbackSlotCache::SlotKind::kLoadGlobalNotInsideTypeof;
FeedbackSlot slot(feedback_slot_cache()->Get(slot_kind, variable));
if (!slot.IsInvalid()) {
return slot;
}
slot = feedback_spec()->AddLoadGlobalICSlot(typeof_mode);
feedback_slot_cache()->Put(slot_kind, variable, feedback_index(slot));
return slot;
}
FeedbackSlot BytecodeGenerator::GetCachedStoreGlobalICSlot(
LanguageMode language_mode, Variable* variable) {
FeedbackSlotCache::SlotKind slot_kind =
is_strict(language_mode)
? FeedbackSlotCache::SlotKind::kStoreGlobalStrict
: FeedbackSlotCache::SlotKind::kStoreGlobalSloppy;
FeedbackSlot slot(feedback_slot_cache()->Get(slot_kind, variable));
if (!slot.IsInvalid()) {
return slot;
}
slot = feedback_spec()->AddStoreGlobalICSlot(language_mode);
feedback_slot_cache()->Put(slot_kind, variable, feedback_index(slot));
return slot;
}
FeedbackSlot BytecodeGenerator::GetCachedLoadICSlot(const Expression* expr,
const AstRawString* name) {
DCHECK(!expr->IsSuperPropertyReference());
if (!FLAG_ignition_share_named_property_feedback) {
return feedback_spec()->AddLoadICSlot();
}
FeedbackSlotCache::SlotKind slot_kind =
FeedbackSlotCache::SlotKind::kLoadProperty;
if (!expr->IsVariableProxy()) {
return feedback_spec()->AddLoadICSlot();
}
const VariableProxy* proxy = expr->AsVariableProxy();
FeedbackSlot slot(
feedback_slot_cache()->Get(slot_kind, proxy->var()->index(), name));
if (!slot.IsInvalid()) {
return slot;
}
slot = feedback_spec()->AddLoadICSlot();
feedback_slot_cache()->Put(slot_kind, proxy->var()->index(), name,
feedback_index(slot));
return slot;
}
FeedbackSlot BytecodeGenerator::GetCachedLoadSuperICSlot(
const AstRawString* name) {
if (!FLAG_ignition_share_named_property_feedback) {
return feedback_spec()->AddLoadICSlot();
}
FeedbackSlotCache::SlotKind slot_kind =
FeedbackSlotCache::SlotKind::kLoadSuperProperty;
FeedbackSlot slot(feedback_slot_cache()->Get(slot_kind, name));
if (!slot.IsInvalid()) {
return slot;
}
slot = feedback_spec()->AddLoadICSlot();
feedback_slot_cache()->Put(slot_kind, name, feedback_index(slot));
return slot;
}
FeedbackSlot BytecodeGenerator::GetCachedStoreICSlot(const Expression* expr,
const AstRawString* name) {
if (!FLAG_ignition_share_named_property_feedback) {
return feedback_spec()->AddStoreICSlot(language_mode());
}
FeedbackSlotCache::SlotKind slot_kind =
is_strict(language_mode())
? FeedbackSlotCache::SlotKind::kStoreNamedStrict
: FeedbackSlotCache::SlotKind::kStoreNamedSloppy;
if (!expr->IsVariableProxy()) {
return feedback_spec()->AddStoreICSlot(language_mode());
}
const VariableProxy* proxy = expr->AsVariableProxy();
FeedbackSlot slot(
feedback_slot_cache()->Get(slot_kind, proxy->var()->index(), name));
if (!slot.IsInvalid()) {
return slot;
}
slot = feedback_spec()->AddStoreICSlot(language_mode());
feedback_slot_cache()->Put(slot_kind, proxy->var()->index(), name,
feedback_index(slot));
return slot;
}
int BytecodeGenerator::GetCachedCreateClosureSlot(FunctionLiteral* literal) {
FeedbackSlotCache::SlotKind slot_kind =
FeedbackSlotCache::SlotKind::kClosureFeedbackCell;
int index = feedback_slot_cache()->Get(slot_kind, literal);
if (index != -1) {
return index;
}
index = feedback_spec()->AddCreateClosureSlot();
feedback_slot_cache()->Put(slot_kind, literal, index);
return index;
}
FeedbackSlot BytecodeGenerator::GetDummyCompareICSlot() {
return dummy_feedback_slot_.Get();
}
} // namespace interpreter
} // namespace internal
} // namespace v8