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fb05063dde
ladybird/Libraries/LibJS/Bytecode/Generator.cpp
Andreas Kling fb05063dde LibJS: Let bytecode instructions know whether they are in strict mode 
This commits puts the strict mode flag in the header of every bytecode
instruction. This allows us to check for strict mode without looking at
the currently running execution context.
2025-10-29 21:20:10 +01:00

1463 lines
62 KiB
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/*
* Copyright (c) 2021-2025, Andreas Kling <andreas@ladybird.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/QuickSort.h>
#include <AK/TemporaryChange.h>
#include <LibJS/AST.h>
#include <LibJS/Bytecode/BasicBlock.h>
#include <LibJS/Bytecode/Generator.h>
#include <LibJS/Bytecode/Instruction.h>
#include <LibJS/Bytecode/Op.h>
#include <LibJS/Bytecode/Register.h>
#include <LibJS/Runtime/ECMAScriptFunctionObject.h>
#include <LibJS/Runtime/VM.h>
namespace JS::Bytecode {
Generator::Generator(VM& vm, GC::Ptr<ECMAScriptFunctionObject const> function, MustPropagateCompletion must_propagate_completion)
: m_vm(vm)
, m_string_table(make<StringTable>())
, m_identifier_table(make<IdentifierTable>())
, m_regex_table(make<RegexTable>())
, m_constants(vm.heap())
, m_accumulator(*this, Operand(Register::accumulator()))
, m_this_value(*this, Operand(Register::this_value()))
, m_must_propagate_completion(must_propagate_completion == MustPropagateCompletion::Yes)
, m_function(function)
{
}
CodeGenerationErrorOr<void> Generator::emit_function_declaration_instantiation(ECMAScriptFunctionObject const& function)
{
if (function.shared_data().m_has_parameter_expressions) {
bool has_non_local_parameters = false;
for (auto const& parameter_name : function.shared_data().m_parameter_names) {
if (parameter_name.value == SharedFunctionInstanceData::ParameterIsLocal::No) {
has_non_local_parameters = true;
break;
}
}
if (has_non_local_parameters)
emit<Op::CreateLexicalEnvironment>();
}
for (auto const& parameter_name : function.shared_data().m_parameter_names) {
if (parameter_name.value == SharedFunctionInstanceData::ParameterIsLocal::No) {
auto id = intern_identifier(parameter_name.key);
emit<Op::CreateVariable>(id, Op::EnvironmentMode::Lexical, false);
if (function.shared_data().m_has_duplicates) {
emit<Op::InitializeLexicalBinding>(id, add_constant(js_undefined()));
}
}
}
if (function.shared_data().m_arguments_object_needed) {
Optional<Operand> dst;
auto local_var_index = function.shared_data().m_local_variables_names.find_first_index_if([](auto const& local) { return local.declaration_kind == LocalVariable::DeclarationKind::ArgumentsObject; });
if (local_var_index.has_value())
dst = local(Identifier::Local::variable(local_var_index.value()));
if (function.is_strict_mode() || !function.has_simple_parameter_list()) {
emit<Op::CreateArguments>(dst, Op::CreateArguments::Kind::Unmapped, function.is_strict_mode());
} else {
emit<Op::CreateArguments>(dst, Op::CreateArguments::Kind::Mapped, function.is_strict_mode());
}
if (local_var_index.has_value())
set_local_initialized(Identifier::Local::variable(local_var_index.value()));
}
auto const& formal_parameters = function.formal_parameters();
for (u32 param_index = 0; param_index < formal_parameters.size(); ++param_index) {
auto const& parameter = formal_parameters.parameters()[param_index];
if (parameter.is_rest) {
emit<Op::CreateRestParams>(Operand { Operand::Type::Argument, param_index }, param_index);
} else if (parameter.default_value) {
auto& if_undefined_block = make_block();
auto& if_not_undefined_block = make_block();
emit<Op::JumpUndefined>(
Operand { Operand::Type::Argument, param_index },
Label { if_undefined_block },
Label { if_not_undefined_block });
switch_to_basic_block(if_undefined_block);
auto operand = TRY(parameter.default_value->generate_bytecode(*this));
emit<Op::Mov>(Operand { Operand::Type::Argument, param_index }, *operand);
emit<Op::Jump>(Label { if_not_undefined_block });
switch_to_basic_block(if_not_undefined_block);
}
if (auto const* identifier = parameter.binding.get_pointer<NonnullRefPtr<Identifier const>>(); identifier) {
if ((*identifier)->is_local()) {
set_local_initialized((*identifier)->local_index());
} else {
auto id = intern_identifier((*identifier)->string());
if (function.shared_data().m_has_duplicates) {
emit<Op::SetLexicalBinding>(id, Operand { Operand::Type::Argument, param_index });
} else {
emit<Op::InitializeLexicalBinding>(id, Operand { Operand::Type::Argument, param_index });
}
}
} else if (auto const* binding_pattern = parameter.binding.get_pointer<NonnullRefPtr<BindingPattern const>>(); binding_pattern) {
ScopedOperand argument { *this, Operand { Operand::Type::Argument, param_index } };
auto init_mode = function.shared_data().m_has_duplicates ? Op::BindingInitializationMode::Set : Bytecode::Op::BindingInitializationMode::Initialize;
TRY((*binding_pattern)->generate_bytecode(*this, init_mode, argument));
}
}
ScopeNode const* scope_body = nullptr;
if (is<ScopeNode>(function.ecmascript_code()))
scope_body = &static_cast<ScopeNode const&>(function.ecmascript_code());
if (!function.shared_data().m_has_parameter_expressions) {
if (scope_body) {
for (auto const& variable_to_initialize : function.shared_data().m_var_names_to_initialize_binding) {
auto const& id = variable_to_initialize.identifier;
if (id.is_local()) {
emit<Op::Mov>(local(id.local_index()), add_constant(js_undefined()));
} else {
auto intern_id = intern_identifier(id.string());
emit<Op::CreateVariable>(intern_id, Op::EnvironmentMode::Var, false);
emit<Op::InitializeVariableBinding>(intern_id, add_constant(js_undefined()));
}
}
}
} else {
bool has_non_local_parameters = false;
if (scope_body) {
for (auto const& variable_to_initialize : function.shared_data().m_var_names_to_initialize_binding) {
auto const& id = variable_to_initialize.identifier;
if (!id.is_local()) {
has_non_local_parameters = true;
break;
}
}
}
if (has_non_local_parameters)
emit<Op::CreateVariableEnvironment>(function.shared_data().m_var_environment_bindings_count);
if (scope_body) {
for (auto const& variable_to_initialize : function.shared_data().m_var_names_to_initialize_binding) {
auto const& id = variable_to_initialize.identifier;
auto initial_value = allocate_register();
if (!variable_to_initialize.parameter_binding || variable_to_initialize.function_name) {
emit<Op::Mov>(initial_value, add_constant(js_undefined()));
} else {
if (id.is_local()) {
emit<Op::Mov>(initial_value, local(id.local_index()));
} else {
emit<Op::GetBinding>(initial_value, intern_identifier(id.string()));
}
}
if (id.is_local()) {
emit<Op::Mov>(local(id.local_index()), initial_value);
} else {
auto intern_id = intern_identifier(id.string());
emit<Op::CreateVariable>(intern_id, Op::EnvironmentMode::Var, false);
emit<Op::InitializeVariableBinding>(intern_id, initial_value);
}
}
}
}
if (!function.is_strict_mode() && scope_body) {
for (auto const& function_name : function.shared_data().m_function_names_to_initialize_binding) {
auto intern_id = intern_identifier(function_name);
emit<Op::CreateVariable>(intern_id, Op::EnvironmentMode::Var, false);
emit<Op::InitializeVariableBinding>(intern_id, add_constant(js_undefined()));
}
}
if (!function.is_strict_mode()) {
bool can_elide_lexical_environment = !scope_body || !scope_body->has_non_local_lexical_declarations();
if (!can_elide_lexical_environment) {
emit<Op::CreateLexicalEnvironment>(OptionalNone {}, function.shared_data().m_lex_environment_bindings_count);
}
}
if (scope_body) {
MUST(scope_body->for_each_lexically_scoped_declaration([&](Declaration const& declaration) {
MUST(declaration.for_each_bound_identifier([&](auto const& id) {
if (id.is_local()) {
return;
}
emit<Op::CreateVariable>(intern_identifier(id.string()),
Op::EnvironmentMode::Lexical,
declaration.is_constant_declaration(),
false,
declaration.is_constant_declaration());
}));
}));
}
for (auto const& declaration : function.shared_data().m_functions_to_initialize) {
auto const& identifier = *declaration.name_identifier();
if (identifier.is_local()) {
auto local_index = identifier.local_index();
emit<Op::NewFunction>(local(local_index), declaration, OptionalNone {});
set_local_initialized(local_index);
} else {
auto function = allocate_register();
emit<Op::NewFunction>(function, declaration, OptionalNone {});
emit<Op::SetVariableBinding>(intern_identifier(declaration.name()), function);
}
}
return {};
}
CodeGenerationErrorOr<GC::Ref<Executable>> Generator::compile(VM& vm, ASTNode const& node, FunctionKind enclosing_function_kind, GC::Ptr<ECMAScriptFunctionObject const> function, MustPropagateCompletion must_propagate_completion, Vector<LocalVariable> local_variable_names)
{
Generator generator(vm, function, must_propagate_completion);
if (is<Program>(node))
generator.m_strict = static_cast<Program const&>(node).is_strict_mode() ? Strict::Yes : Strict::No;
else if (is<FunctionBody>(node))
generator.m_strict = static_cast<FunctionBody const&>(node).in_strict_mode() ? Strict::Yes : Strict::No;
else if (is<FunctionDeclaration>(node))
generator.m_strict = static_cast<FunctionDeclaration const&>(node).is_strict_mode() ? Strict::Yes : Strict::No;
generator.m_local_variables = local_variable_names;
generator.switch_to_basic_block(generator.make_block());
SourceLocationScope scope(generator, node);
generator.m_enclosing_function_kind = enclosing_function_kind;
if (generator.is_in_async_function() && !generator.is_in_generator_function()) {
// Immediately yield with no value.
auto& start_block = generator.make_block();
generator.emit<Bytecode::Op::Yield>(Label { start_block }, generator.add_constant(js_undefined()));
generator.switch_to_basic_block(start_block);
// NOTE: This doesn't have to handle received throw/return completions, as GeneratorObject::resume_abrupt
// will not enter the generator from the SuspendedStart state and immediately completes the generator.
}
if (function)
TRY(generator.emit_function_declaration_instantiation(*function));
if (generator.is_in_generator_function()) {
// Immediately yield with no value.
auto& start_block = generator.make_block();
generator.emit<Bytecode::Op::Yield>(Label { start_block }, generator.add_constant(js_undefined()));
generator.switch_to_basic_block(start_block);
// NOTE: This doesn't have to handle received throw/return completions, as GeneratorObject::resume_abrupt
// will not enter the generator from the SuspendedStart state and immediately completes the generator.
}
auto last_value = TRY(node.generate_bytecode(generator));
if (!generator.current_block().is_terminated() && last_value.has_value()) {
generator.emit<Bytecode::Op::End>(last_value.value());
}
if (generator.is_in_generator_or_async_function()) {
// Terminate all unterminated blocks with yield return
for (auto& block : generator.m_root_basic_blocks) {
if (block->is_terminated())
continue;
generator.switch_to_basic_block(*block);
generator.emit_return<Bytecode::Op::Yield>(generator.add_constant(js_undefined()));
}
}
size_t size_needed = 0;
for (auto& block : generator.m_root_basic_blocks) {
size_needed += block->size();
}
Vector<u8> bytecode;
bytecode.ensure_capacity(size_needed);
Vector<size_t> basic_block_start_offsets;
basic_block_start_offsets.ensure_capacity(generator.m_root_basic_blocks.size());
HashMap<BasicBlock const*, size_t> block_offsets;
Vector<size_t> label_offsets;
struct UnlinkedExceptionHandlers {
size_t start_offset;
size_t end_offset;
BasicBlock const* handler;
BasicBlock const* finalizer;
};
Vector<UnlinkedExceptionHandlers> unlinked_exception_handlers;
HashMap<size_t, SourceRecord> source_map;
Optional<ScopedOperand> undefined_constant;
for (auto& block : generator.m_root_basic_blocks) {
if (!block->is_terminated()) {
// NOTE: We must ensure that the "undefined" constant, which will be used by the not yet
// emitted End instruction, is taken into account while shifting local operands by the
// number of constants.
undefined_constant = generator.add_constant(js_undefined());
break;
}
}
auto number_of_registers = generator.m_next_register;
auto number_of_constants = generator.m_constants.size();
auto number_of_locals = function ? function->local_variables_names().size() : 0;
// Pass: Rewrite the bytecode to use the correct register and constant indices.
for (auto& block : generator.m_root_basic_blocks) {
Bytecode::InstructionStreamIterator it(block->instruction_stream());
while (!it.at_end()) {
auto& instruction = const_cast<Instruction&>(*it);
instruction.visit_operands([number_of_registers, number_of_constants, number_of_locals](Operand& operand) {
switch (operand.type()) {
case Operand::Type::Register:
break;
case Operand::Type::Local:
operand.offset_index_by(number_of_registers + number_of_constants);
break;
case Operand::Type::Constant:
operand.offset_index_by(number_of_registers);
break;
case Operand::Type::Argument:
operand.offset_index_by(number_of_registers + number_of_constants + number_of_locals);
break;
default:
VERIFY_NOT_REACHED();
}
});
++it;
}
}
// Also rewrite the `undefined` constant if we have one for inserting End.
if (undefined_constant.has_value())
undefined_constant.value().operand().offset_index_by(number_of_registers);
for (auto& block : generator.m_root_basic_blocks) {
basic_block_start_offsets.append(bytecode.size());
if (block->handler() || block->finalizer()) {
unlinked_exception_handlers.append({
.start_offset = bytecode.size(),
.end_offset = 0,
.handler = block->handler(),
.finalizer = block->finalizer(),
});
}
block_offsets.set(block.ptr(), bytecode.size());
for (auto& [offset, source_record] : block->source_map()) {
source_map.set(bytecode.size() + offset, source_record);
}
Bytecode::InstructionStreamIterator it(block->instruction_stream());
while (!it.at_end()) {
auto& instruction = const_cast<Instruction&>(*it);
if (instruction.type() == Instruction::Type::Jump) {
auto& jump = static_cast<Bytecode::Op::Jump&>(instruction);
// OPTIMIZATION: Don't emit jumps that just jump to the next block.
if (jump.target().basic_block_index() == block->index() + 1) {
if (basic_block_start_offsets.last() == bytecode.size()) {
// This block is empty, just skip it.
basic_block_start_offsets.take_last();
}
++it;
continue;
}
// OPTIMIZATION: For jumps to a return-or-end-only block, we can emit a `Return` or `End` directly instead.
auto& target_block = *generator.m_root_basic_blocks[jump.target().basic_block_index()];
if (target_block.is_terminated()) {
auto target_instruction_iterator = InstructionStreamIterator { target_block.instruction_stream() };
auto& target_instruction = *target_instruction_iterator;
if (target_instruction.type() == Instruction::Type::Return) {
auto& return_instruction = static_cast<Bytecode::Op::Return const&>(target_instruction);
Op::Return return_op(return_instruction.value());
bytecode.append(reinterpret_cast<u8 const*>(&return_op), return_op.length());
++it;
continue;
}
if (target_instruction.type() == Instruction::Type::End) {
auto& return_instruction = static_cast<Bytecode::Op::End const&>(target_instruction);
Op::End end_op(return_instruction.value());
bytecode.append(reinterpret_cast<u8 const*>(&end_op), end_op.length());
++it;
continue;
}
}
}
// OPTIMIZATION: For `JumpIf` where one of the targets is the very next block,
// we can emit a `JumpTrue` or `JumpFalse` (to the other block) instead.
if (instruction.type() == Instruction::Type::JumpIf) {
auto& jump = static_cast<Bytecode::Op::JumpIf&>(instruction);
if (jump.true_target().basic_block_index() == block->index() + 1) {
Op::JumpFalse jump_false(jump.condition(), Label { jump.false_target() });
auto& label = jump_false.target();
size_t label_offset = bytecode.size() + (bit_cast<FlatPtr>(&label) - bit_cast<FlatPtr>(&jump_false));
label_offsets.append(label_offset);
bytecode.append(reinterpret_cast<u8 const*>(&jump_false), jump_false.length());
++it;
continue;
}
if (jump.false_target().basic_block_index() == block->index() + 1) {
Op::JumpTrue jump_true(jump.condition(), Label { jump.true_target() });
auto& label = jump_true.target();
size_t label_offset = bytecode.size() + (bit_cast<FlatPtr>(&label) - bit_cast<FlatPtr>(&jump_true));
label_offsets.append(label_offset);
bytecode.append(reinterpret_cast<u8 const*>(&jump_true), jump_true.length());
++it;
continue;
}
}
instruction.visit_labels([&](Label& label) {
size_t label_offset = bytecode.size() + (bit_cast<FlatPtr>(&label) - bit_cast<FlatPtr>(&instruction));
label_offsets.append(label_offset);
});
bytecode.append(reinterpret_cast<u8 const*>(&instruction), instruction.length());
++it;
}
if (!block->is_terminated()) {
Op::End end(*undefined_constant);
bytecode.append(reinterpret_cast<u8 const*>(&end), end.length());
}
if (block->handler() || block->finalizer()) {
unlinked_exception_handlers.last().end_offset = bytecode.size();
}
}
for (auto label_offset : label_offsets) {
auto& label = *reinterpret_cast<Label*>(bytecode.data() + label_offset);
auto* block = generator.m_root_basic_blocks[label.basic_block_index()].ptr();
label.set_address(block_offsets.get(block).value());
}
auto executable = vm.heap().allocate<Executable>(
move(bytecode),
move(generator.m_identifier_table),
move(generator.m_string_table),
move(generator.m_regex_table),
move(generator.m_constants),
node.source_code(),
generator.m_next_property_lookup_cache,
generator.m_next_global_variable_cache,
generator.m_next_register,
generator.m_strict);
Vector<Executable::ExceptionHandlers> linked_exception_handlers;
for (auto& unlinked_handler : unlinked_exception_handlers) {
auto start_offset = unlinked_handler.start_offset;
auto end_offset = unlinked_handler.end_offset;
auto handler_offset = unlinked_handler.handler ? block_offsets.get(unlinked_handler.handler).value() : Optional<size_t> {};
auto finalizer_offset = unlinked_handler.finalizer ? block_offsets.get(unlinked_handler.finalizer).value() : Optional<size_t> {};
linked_exception_handlers.append({ start_offset, end_offset, handler_offset, finalizer_offset });
}
quick_sort(linked_exception_handlers, [](auto const& a, auto const& b) {
return a.start_offset < b.start_offset;
});
executable->exception_handlers = move(linked_exception_handlers);
executable->basic_block_start_offsets = move(basic_block_start_offsets);
executable->source_map = move(source_map);
executable->local_variable_names = move(local_variable_names);
executable->local_index_base = number_of_registers + number_of_constants;
executable->argument_index_base = number_of_registers + number_of_constants + number_of_locals;
executable->length_identifier = generator.m_length_identifier;
generator.m_finished = true;
return executable;
}
CodeGenerationErrorOr<GC::Ref<Executable>> Generator::generate_from_ast_node(VM& vm, ASTNode const& node, FunctionKind enclosing_function_kind)
{
Vector<LocalVariable> local_variable_names;
if (is<ScopeNode>(node))
local_variable_names = static_cast<ScopeNode const&>(node).local_variables_names();
return compile(vm, node, enclosing_function_kind, {}, MustPropagateCompletion::Yes, move(local_variable_names));
}
CodeGenerationErrorOr<GC::Ref<Executable>> Generator::generate_from_function(VM& vm, ECMAScriptFunctionObject const& function)
{
return compile(vm, function.ecmascript_code(), function.kind(), &function, MustPropagateCompletion::No, function.local_variables_names());
}
void Generator::grow(size_t additional_size)
{
VERIFY(m_current_basic_block);
m_current_basic_block->grow(additional_size);
}
ScopedOperand Generator::allocate_register()
{
if (!m_free_registers.is_empty()) {
return ScopedOperand { *this, Operand { m_free_registers.take_last() } };
}
VERIFY(m_next_register != NumericLimits<u32>::max());
return ScopedOperand { *this, Operand { Register { m_next_register++ } } };
}
void Generator::free_register(Register reg)
{
m_free_registers.append(reg);
}
ScopedOperand Generator::local(Identifier::Local const& local)
{
if (local.is_variable())
return ScopedOperand { *this, Operand { Operand::Type::Local, static_cast<u32>(local.index) } };
return ScopedOperand { *this, Operand { Operand::Type::Argument, static_cast<u32>(local.index) } };
}
Generator::SourceLocationScope::SourceLocationScope(Generator& generator, ASTNode const& node)
: m_generator(generator)
, m_previous_node(m_generator.m_current_ast_node)
{
m_generator.m_current_ast_node = &node;
}
Generator::SourceLocationScope::~SourceLocationScope()
{
m_generator.m_current_ast_node = m_previous_node;
}
Generator::UnwindContext::UnwindContext(Generator& generator, Optional<Label> finalizer)
: m_generator(generator)
, m_finalizer(finalizer)
, m_previous_context(m_generator.m_current_unwind_context)
{
m_generator.m_current_unwind_context = this;
}
Generator::UnwindContext::~UnwindContext()
{
VERIFY(m_generator.m_current_unwind_context == this);
m_generator.m_current_unwind_context = m_previous_context;
}
Label Generator::nearest_continuable_scope() const
{
return m_continuable_scopes.last().bytecode_target;
}
bool Generator::emit_block_declaration_instantiation(ScopeNode const& scope_node)
{
bool needs_block_declaration_instantiation = false;
MUST(scope_node.for_each_lexically_scoped_declaration([&](Declaration const& declaration) {
if (declaration.is_function_declaration()) {
needs_block_declaration_instantiation = true;
return;
}
MUST(declaration.for_each_bound_identifier([&](auto const& id) {
if (!id.is_local())
needs_block_declaration_instantiation = true;
}));
}));
if (!needs_block_declaration_instantiation)
return false;
auto environment = allocate_register();
emit<Bytecode::Op::CreateLexicalEnvironment>(environment);
start_boundary(BlockBoundaryType::LeaveLexicalEnvironment);
MUST(scope_node.for_each_lexically_scoped_declaration([&](Declaration const& declaration) {
auto is_constant_declaration = declaration.is_constant_declaration();
// NOTE: Due to the use of MUST with `create_immutable_binding` and `create_mutable_binding` below,
// an exception should not result from `for_each_bound_name`.
// a. For each element dn of the BoundNames of d, do
MUST(declaration.for_each_bound_identifier([&](Identifier const& identifier) {
if (identifier.is_local()) {
// NOTE: No need to create bindings for local variables as their values are not stored in an environment.
return;
}
auto const& name = identifier.string();
// i. If IsConstantDeclaration of d is true, then
if (is_constant_declaration) {
// 1. Perform ! env.CreateImmutableBinding(dn, true).
emit<Bytecode::Op::CreateImmutableBinding>(environment, intern_identifier(name), true);
}
// ii. Else,
else {
// 1. Perform ! env.CreateMutableBinding(dn, false). NOTE: This step is replaced in section B.3.2.6.
emit<Bytecode::Op::CreateMutableBinding>(environment, intern_identifier(name), false);
}
}));
// b. If d is either a FunctionDeclaration, a GeneratorDeclaration, an AsyncFunctionDeclaration, or an AsyncGeneratorDeclaration, then
if (is<FunctionDeclaration>(declaration)) {
// i. Let fn be the sole element of the BoundNames of d.
auto& function_declaration = static_cast<FunctionDeclaration const&>(declaration);
// ii. Let fo be InstantiateFunctionObject of d with arguments env and privateEnv.
auto fo = allocate_register();
emit<Bytecode::Op::NewFunction>(fo, function_declaration, OptionalNone {});
// iii. Perform ! env.InitializeBinding(fn, fo). NOTE: This step is replaced in section B.3.2.6.
if (function_declaration.name_identifier()->is_local()) {
auto local_index = function_declaration.name_identifier()->local_index();
if (local_index.is_variable()) {
emit<Bytecode::Op::Mov>(local(local_index), fo);
} else {
VERIFY_NOT_REACHED();
}
} else {
emit<Bytecode::Op::InitializeLexicalBinding>(intern_identifier(function_declaration.name()), fo);
}
}
}));
return true;
}
void Generator::begin_variable_scope()
{
start_boundary(BlockBoundaryType::LeaveLexicalEnvironment);
emit<Bytecode::Op::CreateLexicalEnvironment>();
}
void Generator::end_variable_scope()
{
end_boundary(BlockBoundaryType::LeaveLexicalEnvironment);
if (!m_current_basic_block->is_terminated()) {
emit<Bytecode::Op::LeaveLexicalEnvironment>();
}
}
void Generator::begin_continuable_scope(Label continue_target, Vector<FlyString> const& language_label_set)
{
m_continuable_scopes.append({ continue_target, language_label_set });
start_boundary(BlockBoundaryType::Continue);
}
void Generator::end_continuable_scope()
{
m_continuable_scopes.take_last();
end_boundary(BlockBoundaryType::Continue);
}
Label Generator::nearest_breakable_scope() const
{
return m_breakable_scopes.last().bytecode_target;
}
void Generator::begin_breakable_scope(Label breakable_target, Vector<FlyString> const& language_label_set)
{
m_breakable_scopes.append({ breakable_target, language_label_set });
start_boundary(BlockBoundaryType::Break);
}
void Generator::end_breakable_scope()
{
m_breakable_scopes.take_last();
end_boundary(BlockBoundaryType::Break);
}
CodeGenerationErrorOr<Generator::ReferenceOperands> Generator::emit_super_reference(MemberExpression const& expression)
{
VERIFY(is<SuperExpression>(expression.object()));
// https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
// 1. Let env be GetThisEnvironment().
// 2. Let actualThis be ? env.GetThisBinding().
auto actual_this = get_this();
Optional<ScopedOperand> computed_property_value;
Optional<IdentifierTableIndex> property_key_id;
if (expression.is_computed()) {
// SuperProperty : super [ Expression ]
// 3. Let propertyNameReference be ? Evaluation of Expression.
// 4. Let propertyNameValue be ? GetValue(propertyNameReference).
computed_property_value = TRY(expression.property().generate_bytecode(*this)).value();
} else {
// SuperProperty : super . IdentifierName
// 3. Let propertyKey be the StringValue of IdentifierName.
auto const identifier_name = as<Identifier>(expression.property()).string();
property_key_id = intern_identifier(identifier_name);
}
// 5/7. Return ? MakeSuperPropertyReference(actualThis, propertyKey, strict).
// https://tc39.es/ecma262/#sec-makesuperpropertyreference
// 1. Let env be GetThisEnvironment().
// 2. Assert: env.HasSuperBinding() is true.
// 3. Let baseValue be ? env.GetSuperBase().
auto base_value = allocate_register();
emit<Bytecode::Op::ResolveSuperBase>(base_value);
// 4. Return the Reference Record { [[Base]]: baseValue, [[ReferencedName]]: propertyKey, [[Strict]]: strict, [[ThisValue]]: actualThis }.
return ReferenceOperands {
.base = base_value,
.referenced_name = computed_property_value,
.referenced_identifier = property_key_id,
.this_value = actual_this,
};
}
CodeGenerationErrorOr<Generator::ReferenceOperands> Generator::emit_load_from_reference(JS::ASTNode const& node, Optional<ScopedOperand> preferred_dst)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
auto loaded_value = TRY(identifier.generate_bytecode(*this, preferred_dst)).value();
return ReferenceOperands {
.loaded_value = loaded_value,
};
}
if (!is<MemberExpression>(node)) {
return CodeGenerationError {
&node,
"Unimplemented/invalid node used as a reference"sv
};
}
auto& expression = static_cast<MemberExpression const&>(node);
// https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
if (is<SuperExpression>(expression.object())) {
auto super_reference = TRY(emit_super_reference(expression));
auto dst = preferred_dst.has_value() ? preferred_dst.value() : allocate_register();
if (super_reference.referenced_name.has_value()) {
// 5. Let propertyKey be ? ToPropertyKey(propertyNameValue).
// FIXME: This does ToPropertyKey out of order, which is observable by Symbol.toPrimitive!
emit_get_by_value_with_this(dst, *super_reference.base, *super_reference.referenced_name, *super_reference.this_value);
} else {
// 3. Let propertyKey be StringValue of IdentifierName.
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
emit_get_by_id_with_this(dst, *super_reference.base, identifier_table_ref, *super_reference.this_value);
}
super_reference.loaded_value = dst;
return super_reference;
}
auto base = TRY(expression.object().generate_bytecode(*this)).value();
auto base_identifier = intern_identifier_for_expression(expression.object());
if (expression.is_computed()) {
auto property = TRY(expression.property().generate_bytecode(*this)).value();
auto saved_property = allocate_register();
emit<Bytecode::Op::Mov>(saved_property, property);
auto dst = preferred_dst.has_value() ? preferred_dst.value() : allocate_register();
emit_get_by_value(dst, base, property, move(base_identifier));
return ReferenceOperands {
.base = base,
.referenced_name = saved_property,
.this_value = base,
.loaded_value = dst,
};
}
if (expression.property().is_identifier()) {
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
auto dst = preferred_dst.has_value() ? preferred_dst.value() : allocate_register();
emit_get_by_id(dst, base, identifier_table_ref, move(base_identifier));
return ReferenceOperands {
.base = base,
.referenced_identifier = identifier_table_ref,
.this_value = base,
.loaded_value = dst,
};
}
if (expression.property().is_private_identifier()) {
auto identifier_table_ref = intern_identifier(as<PrivateIdentifier>(expression.property()).string());
auto dst = preferred_dst.has_value() ? preferred_dst.value() : allocate_register();
emit<Bytecode::Op::GetPrivateById>(dst, base, identifier_table_ref);
return ReferenceOperands {
.base = base,
.referenced_private_identifier = identifier_table_ref,
.this_value = base,
.loaded_value = dst,
};
}
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
CodeGenerationErrorOr<void> Generator::emit_store_to_reference(JS::ASTNode const& node, ScopedOperand value)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
emit_set_variable(identifier, value);
return {};
}
if (is<MemberExpression>(node)) {
auto& expression = static_cast<MemberExpression const&>(node);
// https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
if (is<SuperExpression>(expression.object())) {
auto super_reference = TRY(emit_super_reference(expression));
// 4. Return the Reference Record { [[Base]]: baseValue, [[ReferencedName]]: propertyKey, [[Strict]]: strict, [[ThisValue]]: actualThis }.
if (super_reference.referenced_name.has_value()) {
// 5. Let propertyKey be ? ToPropertyKey(propertyNameValue).
// FIXME: This does ToPropertyKey out of order, which is observable by Symbol.toPrimitive!
emit_put_by_value_with_this(*super_reference.base, *super_reference.referenced_name, *super_reference.this_value, value, PutKind::Normal);
} else {
// 3. Let propertyKey be StringValue of IdentifierName.
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
emit<Bytecode::Op::PutNormalByIdWithThis>(*super_reference.base, *super_reference.this_value, identifier_table_ref, value, next_property_lookup_cache());
}
} else {
auto object = TRY(expression.object().generate_bytecode(*this)).value();
if (expression.is_computed()) {
auto property = TRY(expression.property().generate_bytecode(*this)).value();
emit_put_by_value(object, property, value, PutKind::Normal, {});
} else if (expression.property().is_identifier()) {
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
emit_put_by_id(object, identifier_table_ref, value, Bytecode::PutKind::Normal, next_property_lookup_cache());
} else if (expression.property().is_private_identifier()) {
auto identifier_table_ref = intern_identifier(as<PrivateIdentifier>(expression.property()).string());
emit<Bytecode::Op::PutPrivateById>(object, identifier_table_ref, value);
} else {
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
}
return {};
}
return CodeGenerationError {
&node,
"Unimplemented/invalid node used a reference"sv
};
}
CodeGenerationErrorOr<void> Generator::emit_store_to_reference(ReferenceOperands const& reference, ScopedOperand value)
{
if (reference.referenced_private_identifier.has_value()) {
emit<Bytecode::Op::PutPrivateById>(*reference.base, *reference.referenced_private_identifier, value);
return {};
}
if (reference.referenced_identifier.has_value()) {
if (reference.base == reference.this_value)
emit_put_by_id(*reference.base, *reference.referenced_identifier, value, Bytecode::PutKind::Normal, next_property_lookup_cache());
else
emit<Bytecode::Op::PutNormalByIdWithThis>(*reference.base, *reference.this_value, *reference.referenced_identifier, value, next_property_lookup_cache());
return {};
}
if (reference.base == reference.this_value)
emit_put_by_value(*reference.base, *reference.referenced_name, value, PutKind::Normal, {});
else
emit_put_by_value_with_this(*reference.base, *reference.referenced_name, *reference.this_value, value, PutKind::Normal);
return {};
}
CodeGenerationErrorOr<Optional<ScopedOperand>> Generator::emit_delete_reference(JS::ASTNode const& node)
{
if (is<Identifier>(node)) {
auto& identifier = static_cast<Identifier const&>(node);
if (identifier.is_local()) {
return add_constant(Value(false));
}
auto dst = allocate_register();
emit<Bytecode::Op::DeleteVariable>(dst, intern_identifier(identifier.string()));
return dst;
}
if (is<MemberExpression>(node)) {
auto& expression = static_cast<MemberExpression const&>(node);
// https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
if (is<SuperExpression>(expression.object())) {
auto super_reference = TRY(emit_super_reference(expression));
auto dst = allocate_register();
if (super_reference.referenced_name.has_value()) {
emit<Bytecode::Op::DeleteByValueWithThis>(dst, *super_reference.base, *super_reference.this_value, *super_reference.referenced_name);
} else {
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
emit<Bytecode::Op::DeleteByIdWithThis>(dst, *super_reference.base, *super_reference.this_value, identifier_table_ref);
}
return dst;
}
auto object = TRY(expression.object().generate_bytecode(*this)).value();
auto dst = allocate_register();
if (expression.is_computed()) {
auto property = TRY(expression.property().generate_bytecode(*this)).value();
emit<Bytecode::Op::DeleteByValue>(dst, object, property);
} else if (expression.property().is_identifier()) {
auto identifier_table_ref = intern_identifier(as<Identifier>(expression.property()).string());
emit<Bytecode::Op::DeleteById>(dst, object, identifier_table_ref);
} else {
// NOTE: Trying to delete a private field generates a SyntaxError in the parser.
return CodeGenerationError {
&expression,
"Unimplemented non-computed member expression"sv
};
}
return dst;
}
// Though this will have no deletion effect, we still have to evaluate the node as it can have side effects.
// For example: delete a(); delete ++c.b; etc.
// 13.5.1.2 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-delete-operator-runtime-semantics-evaluation
// 1. Let ref be the result of evaluating UnaryExpression.
// 2. ReturnIfAbrupt(ref).
(void)TRY(node.generate_bytecode(*this));
// 3. If ref is not a Reference Record, return true.
// NOTE: The rest of the steps are handled by Delete{Variable,ByValue,Id}.
return add_constant(Value(true));
}
void Generator::emit_set_variable(JS::Identifier const& identifier, ScopedOperand value, Bytecode::Op::BindingInitializationMode initialization_mode, Bytecode::Op::EnvironmentMode environment_mode)
{
if (identifier.is_local()) {
auto local_index = identifier.local_index();
if (value.operand().is_local() && local_index.is_variable() && value.operand().index() == local_index.index) {
// Moving a local to itself is a no-op.
return;
}
emit<Bytecode::Op::Mov>(local(local_index), value);
} else {
auto identifier_index = intern_identifier(identifier.string());
if (environment_mode == Bytecode::Op::EnvironmentMode::Lexical) {
if (initialization_mode == Bytecode::Op::BindingInitializationMode::Initialize) {
emit<Bytecode::Op::InitializeLexicalBinding>(identifier_index, value);
} else if (initialization_mode == Bytecode::Op::BindingInitializationMode::Set) {
if (identifier.is_global()) {
emit<Bytecode::Op::SetGlobal>(identifier_index, value, next_global_variable_cache());
} else {
emit<Bytecode::Op::SetLexicalBinding>(identifier_index, value);
}
}
} else if (environment_mode == Bytecode::Op::EnvironmentMode::Var) {
if (initialization_mode == Bytecode::Op::BindingInitializationMode::Initialize) {
emit<Bytecode::Op::InitializeVariableBinding>(identifier_index, value);
} else if (initialization_mode == Bytecode::Op::BindingInitializationMode::Set) {
emit<Bytecode::Op::SetVariableBinding>(identifier_index, value);
}
} else {
VERIFY_NOT_REACHED();
}
}
}
static Optional<Utf16String> expression_identifier(Expression const& expression)
{
if (expression.is_identifier()) {
auto const& identifier = static_cast<Identifier const&>(expression);
return identifier.string().to_utf16_string();
}
if (expression.is_numeric_literal()) {
auto const& literal = static_cast<NumericLiteral const&>(expression);
return literal.value().to_utf16_string_without_side_effects();
}
if (expression.is_string_literal()) {
auto const& literal = static_cast<StringLiteral const&>(expression);
return Utf16String::formatted("'{}'", literal.value());
}
if (expression.is_member_expression()) {
auto const& member_expression = static_cast<MemberExpression const&>(expression);
StringBuilder builder(StringBuilder::Mode::UTF16);
if (auto identifier = expression_identifier(member_expression.object()); identifier.has_value())
builder.append(*identifier);
if (auto identifier = expression_identifier(member_expression.property()); identifier.has_value()) {
if (member_expression.is_computed())
builder.appendff("[{}]", *identifier);
else
builder.appendff(".{}", *identifier);
}
return builder.to_utf16_string();
}
return {};
}
Optional<IdentifierTableIndex> Generator::intern_identifier_for_expression(Expression const& expression)
{
if (auto identifier = expression_identifier(expression); identifier.has_value())
return intern_identifier(identifier.release_value());
return {};
}
void Generator::generate_scoped_jump(JumpType type)
{
TemporaryChange temp { m_current_unwind_context, m_current_unwind_context };
bool last_was_finally = false;
for (size_t i = m_boundaries.size(); i > 0; --i) {
auto boundary = m_boundaries[i - 1];
using enum BlockBoundaryType;
switch (boundary) {
case Break:
if (type == JumpType::Break) {
emit<Op::Jump>(nearest_breakable_scope());
return;
}
break;
case Continue:
if (type == JumpType::Continue) {
emit<Op::Jump>(nearest_continuable_scope());
return;
}
break;
case Unwind:
if (!last_was_finally) {
VERIFY(m_current_unwind_context && m_current_unwind_context->handler().has_value());
emit<Bytecode::Op::LeaveUnwindContext>();
m_current_unwind_context = m_current_unwind_context->previous();
}
last_was_finally = false;
break;
case LeaveLexicalEnvironment:
emit<Bytecode::Op::LeaveLexicalEnvironment>();
break;
case ReturnToFinally: {
VERIFY(m_current_unwind_context->finalizer().has_value());
m_current_unwind_context = m_current_unwind_context->previous();
auto jump_type_name = type == JumpType::Break ? "break"sv : "continue"sv;
auto block_name = MUST(String::formatted("{}.{}", current_block().name(), jump_type_name));
auto& block = make_block(block_name);
emit<Op::ScheduleJump>(Label { block });
switch_to_basic_block(block);
last_was_finally = true;
break;
}
case LeaveFinally:
emit<Op::LeaveFinally>();
break;
}
}
VERIFY_NOT_REACHED();
}
void Generator::generate_labelled_jump(JumpType type, FlyString const& label)
{
TemporaryChange temp { m_current_unwind_context, m_current_unwind_context };
size_t current_boundary = m_boundaries.size();
bool last_was_finally = false;
auto const& jumpable_scopes = type == JumpType::Continue ? m_continuable_scopes : m_breakable_scopes;
for (auto const& jumpable_scope : jumpable_scopes.in_reverse()) {
for (; current_boundary > 0; --current_boundary) {
auto boundary = m_boundaries[current_boundary - 1];
if (boundary == BlockBoundaryType::Unwind) {
if (!last_was_finally) {
VERIFY(m_current_unwind_context && m_current_unwind_context->handler().has_value());
emit<Bytecode::Op::LeaveUnwindContext>();
m_current_unwind_context = m_current_unwind_context->previous();
}
last_was_finally = false;
} else if (boundary == BlockBoundaryType::LeaveLexicalEnvironment) {
emit<Bytecode::Op::LeaveLexicalEnvironment>();
} else if (boundary == BlockBoundaryType::ReturnToFinally) {
VERIFY(m_current_unwind_context->finalizer().has_value());
m_current_unwind_context = m_current_unwind_context->previous();
auto jump_type_name = type == JumpType::Break ? "break"sv : "continue"sv;
auto block_name = MUST(String::formatted("{}.{}", current_block().name(), jump_type_name));
auto& block = make_block(block_name);
emit<Op::ScheduleJump>(Label { block });
switch_to_basic_block(block);
last_was_finally = true;
} else if ((type == JumpType::Continue && boundary == BlockBoundaryType::Continue) || (type == JumpType::Break && boundary == BlockBoundaryType::Break)) {
// Make sure we don't process this boundary twice if the current jumpable scope doesn't contain the target label.
--current_boundary;
break;
}
}
if (jumpable_scope.language_label_set.contains_slow(label)) {
emit<Op::Jump>(jumpable_scope.bytecode_target);
return;
}
}
// We must have a jumpable scope available that contains the label, as this should be enforced by the parser.
VERIFY_NOT_REACHED();
}
void Generator::generate_break()
{
generate_scoped_jump(JumpType::Break);
}
void Generator::generate_break(FlyString const& break_label)
{
generate_labelled_jump(JumpType::Break, break_label);
}
void Generator::generate_continue()
{
generate_scoped_jump(JumpType::Continue);
}
void Generator::generate_continue(FlyString const& continue_label)
{
generate_labelled_jump(JumpType::Continue, continue_label);
}
void Generator::push_home_object(ScopedOperand object)
{
m_home_objects.append(object);
}
void Generator::pop_home_object()
{
m_home_objects.take_last();
}
void Generator::emit_new_function(ScopedOperand dst, FunctionExpression const& function_node, Optional<IdentifierTableIndex> lhs_name)
{
if (m_home_objects.is_empty()) {
emit<Op::NewFunction>(dst, function_node, lhs_name);
} else {
emit<Op::NewFunction>(dst, function_node, lhs_name, m_home_objects.last());
}
}
CodeGenerationErrorOr<ScopedOperand> Generator::emit_named_evaluation_if_anonymous_function(Expression const& expression, Optional<IdentifierTableIndex> lhs_name, Optional<ScopedOperand> preferred_dst)
{
if (is<FunctionExpression>(expression)) {
auto const& function_expression = static_cast<FunctionExpression const&>(expression);
if (!function_expression.has_name()) {
return TRY(function_expression.generate_bytecode_with_lhs_name(*this, move(lhs_name), preferred_dst)).value();
}
}
if (is<ClassExpression>(expression)) {
auto const& class_expression = static_cast<ClassExpression const&>(expression);
if (!class_expression.has_name()) {
return TRY(class_expression.generate_bytecode_with_lhs_name(*this, move(lhs_name), preferred_dst)).value();
}
}
return TRY(expression.generate_bytecode(*this, preferred_dst)).value();
}
void Generator::emit_get_by_id(ScopedOperand dst, ScopedOperand base, IdentifierTableIndex property_identifier, Optional<IdentifierTableIndex> base_identifier)
{
if (m_identifier_table->get(property_identifier) == "length"sv) {
m_length_identifier = property_identifier;
emit<Op::GetLength>(dst, base, move(base_identifier), m_next_property_lookup_cache++);
return;
}
emit<Op::GetById>(dst, base, property_identifier, move(base_identifier), m_next_property_lookup_cache++);
}
void Generator::emit_get_by_id_with_this(ScopedOperand dst, ScopedOperand base, IdentifierTableIndex id, ScopedOperand this_value)
{
if (m_identifier_table->get(id) == "length"sv) {
m_length_identifier = id;
emit<Op::GetLengthWithThis>(dst, base, this_value, m_next_property_lookup_cache++);
return;
}
emit<Op::GetByIdWithThis>(dst, base, id, this_value, m_next_property_lookup_cache++);
}
void Generator::emit_get_by_value(ScopedOperand dst, ScopedOperand base, ScopedOperand property, Optional<IdentifierTableIndex> base_identifier)
{
if (property.operand().is_constant() && get_constant(property).is_string()) {
auto property_key = MUST(get_constant(property).to_property_key(vm()));
if (property_key.is_string()) {
emit_get_by_id(dst, base, intern_identifier(property_key.as_string()), base_identifier);
return;
}
}
emit<Op::GetByValue>(dst, base, property, base_identifier);
}
void Generator::emit_get_by_value_with_this(ScopedOperand dst, ScopedOperand base, ScopedOperand property, ScopedOperand this_value)
{
if (property.operand().is_constant() && get_constant(property).is_string()) {
auto property_key = MUST(get_constant(property).to_property_key(vm()));
if (property_key.is_string()) {
emit_get_by_id_with_this(dst, base, intern_identifier(property_key.as_string()), this_value);
return;
}
}
emit<Op::GetByValueWithThis>(dst, base, property, this_value);
}
void Generator::emit_put_by_id(Operand base, IdentifierTableIndex property, Operand src, PutKind kind, u32 cache_index, Optional<IdentifierTableIndex> base_identifier)
{
auto string = m_identifier_table->get(property);
if (!string.is_empty() && !(string.code_unit_at(0) == '0' && string.length_in_code_units() > 1)) {
auto property_index = string.to_number<u32>(TrimWhitespace::No);
if (property_index.has_value() && property_index.value() < NumericLimits<u32>::max()) {
#define EMIT_PUT_BY_NUMERIC_ID(kind) \
case PutKind::kind: \
emit<Op::Put##kind##ByNumericId>(base, property_index.release_value(), src, cache_index, move(base_identifier)); \
break;
switch (kind) {
JS_ENUMERATE_PUT_KINDS(EMIT_PUT_BY_NUMERIC_ID)
default:
VERIFY_NOT_REACHED();
}
#undef EMIT_PUT_BY_NUMERIC_ID
return;
}
}
#define EMIT_PUT_BY_ID(kind) \
case PutKind::kind: \
emit<Op::Put##kind##ById>(base, property, src, cache_index, move(base_identifier)); \
break;
switch (kind) {
JS_ENUMERATE_PUT_KINDS(EMIT_PUT_BY_ID)
default:
VERIFY_NOT_REACHED();
}
#undef EMIT_PUT_BY_ID
}
void Generator::emit_put_by_value(ScopedOperand base, ScopedOperand property, ScopedOperand src, Bytecode::PutKind kind, Optional<IdentifierTableIndex> base_identifier)
{
if (property.operand().is_constant() && get_constant(property).is_string()) {
auto property_key = MUST(get_constant(property).to_property_key(vm()));
if (property_key.is_string()) {
emit_put_by_id(base, intern_identifier(property_key.as_string()), src, kind, m_next_property_lookup_cache++, base_identifier);
return;
}
}
#define EMIT_PUT_BY_VALUE(kind) \
case PutKind::kind: \
emit<Op::Put##kind##ByValue>(base, property, src, move(base_identifier)); \
break;
switch (kind) {
JS_ENUMERATE_PUT_KINDS(EMIT_PUT_BY_VALUE)
default:
VERIFY_NOT_REACHED();
}
#undef EMIT_PUT_BY_VALUE
}
void Generator::emit_put_by_value_with_this(ScopedOperand base, ScopedOperand property, ScopedOperand this_value, ScopedOperand src, Bytecode::PutKind kind)
{
if (property.operand().is_constant() && get_constant(property).is_string()) {
auto property_key = MUST(get_constant(property).to_property_key(vm()));
if (property_key.is_string()) {
#define EMIT_PUT_BY_ID_WITH_THIS(kind) \
case PutKind::kind: \
emit<Op::Put##kind##ByIdWithThis>(base, this_value, intern_identifier(property_key.as_string()), src, m_next_property_lookup_cache++); \
break;
switch (kind) {
JS_ENUMERATE_PUT_KINDS(EMIT_PUT_BY_ID_WITH_THIS)
default:
VERIFY_NOT_REACHED();
}
#undef EMIT_PUT_BY_ID_WITH_THIS
return;
}
}
#define EMIT_PUT_BY_VALUE_WITH_THIS(kind) \
case PutKind::kind: \
emit<Op::Put##kind##ByValueWithThis>(base, property, this_value, src); \
break;
switch (kind) {
JS_ENUMERATE_PUT_KINDS(EMIT_PUT_BY_VALUE_WITH_THIS)
default:
VERIFY_NOT_REACHED();
}
#undef EMIT_PUT_BY_VALUE_WITH_THIS
}
void Generator::emit_iterator_value(ScopedOperand dst, ScopedOperand result)
{
emit_get_by_id(dst, result, intern_identifier("value"_utf16_fly_string));
}
void Generator::emit_iterator_complete(ScopedOperand dst, ScopedOperand result)
{
emit_get_by_id(dst, result, intern_identifier("done"_utf16_fly_string));
}
bool Generator::is_local_initialized(u32 local_index) const
{
return m_initialized_locals.find(local_index) != m_initialized_locals.end();
}
bool Generator::is_local_initialized(Identifier::Local const& local) const
{
if (local.is_variable())
return m_initialized_locals.find(local.index) != m_initialized_locals.end();
if (local.is_argument())
return m_initialized_arguments.find(local.index) != m_initialized_arguments.end();
return true;
}
void Generator::set_local_initialized(Identifier::Local const& local)
{
if (local.is_variable()) {
m_initialized_locals.set(local.index);
} else if (local.is_argument()) {
m_initialized_arguments.set(local.index);
} else {
VERIFY_NOT_REACHED();
}
}
bool Generator::is_local_lexically_declared(Identifier::Local const& local) const
{
if (local.is_argument())
return false;
return m_local_variables[local.index].declaration_kind == LocalVariable::DeclarationKind::LetOrConst;
}
ScopedOperand Generator::get_this(Optional<ScopedOperand> preferred_dst)
{
if (m_current_basic_block->has_resolved_this())
return this_value();
if (m_root_basic_blocks[0]->has_resolved_this()) {
m_current_basic_block->set_has_resolved_this();
return this_value();
}
// OPTIMIZATION: If we're compiling a function that doesn't allocate a FunctionEnvironment,
// it will always have the same `this` value as the outer function,
// and so the `this` value is already in the `this` register!
if (m_function && !m_function->allocates_function_environment())
return this_value();
auto dst = preferred_dst.has_value() ? preferred_dst.value() : allocate_register();
emit<Bytecode::Op::ResolveThisBinding>();
m_current_basic_block->set_has_resolved_this();
return this_value();
}
ScopedOperand Generator::accumulator()
{
return m_accumulator;
}
ScopedOperand Generator::this_value()
{
return m_this_value;
}
bool Generator::fuse_compare_and_jump(ScopedOperand const& condition, Label true_target, Label false_target)
{
auto& last_instruction = *reinterpret_cast<Instruction const*>(m_current_basic_block->data() + m_current_basic_block->last_instruction_start_offset());
#define HANDLE_COMPARISON_OP(op_TitleCase, op_snake_case, numeric_operator) \
if (last_instruction.type() == Instruction::Type::op_TitleCase) { \
auto& comparison = static_cast<Op::op_TitleCase const&>(last_instruction); \
VERIFY(comparison.dst() == condition); \
auto lhs = comparison.lhs(); \
auto rhs = comparison.rhs(); \
m_current_basic_block->rewind(); \
emit<Op::Jump##op_TitleCase>(lhs, rhs, true_target, false_target); \
return true; \
}
JS_ENUMERATE_COMPARISON_OPS(HANDLE_COMPARISON_OP);
#undef HANDLE_COMPARISON_OP
return false;
}
void Generator::emit_jump_if(ScopedOperand const& condition, Label true_target, Label false_target)
{
if (condition.operand().is_constant()) {
auto value = m_constants[condition.operand().index()];
if (value.is_boolean()) {
if (value.as_bool()) {
emit<Op::Jump>(true_target);
} else {
emit<Op::Jump>(false_target);
}
return;
}
}
// NOTE: It's only safe to fuse compare-and-jump if the condition is a temporary with no other dependents.
if (condition.operand().is_register()
&& condition.ref_count() == 1
&& m_current_basic_block->size() > 0) {
if (fuse_compare_and_jump(condition, true_target, false_target))
return;
}
emit<Op::JumpIf>(condition, true_target, false_target);
}
ScopedOperand Generator::copy_if_needed_to_preserve_evaluation_order(ScopedOperand const& operand)
{
if (!operand.operand().is_local())
return operand;
auto new_register = allocate_register();
emit<Bytecode::Op::Mov>(new_register, operand);
return new_register;
}
ScopedOperand Generator::add_constant(Value value)
{
auto append_new_constant = [&] {
m_constants.append(value);
return ScopedOperand { *this, Operand(Operand::Type::Constant, m_constants.size() - 1) };
};
if (value.is_boolean()) {
if (value.as_bool()) {
if (!m_true_constant.has_value())
m_true_constant = append_new_constant();
return m_true_constant.value();
} else {
if (!m_false_constant.has_value())
m_false_constant = append_new_constant();
return m_false_constant.value();
}
}
if (value.is_undefined()) {
if (!m_undefined_constant.has_value())
m_undefined_constant = append_new_constant();
return m_undefined_constant.value();
}
if (value.is_null()) {
if (!m_null_constant.has_value())
m_null_constant = append_new_constant();
return m_null_constant.value();
}
if (value.is_special_empty_value()) {
if (!m_empty_constant.has_value())
m_empty_constant = append_new_constant();
return m_empty_constant.value();
}
if (value.is_int32()) {
auto as_int32 = value.as_i32();
return m_int32_constants.ensure(as_int32, [&] {
return append_new_constant();
});
}
if (value.is_string()) {
auto as_string = value.as_string().utf16_string();
return m_string_constants.ensure(as_string, [&] {
return append_new_constant();
});
}
return append_new_constant();
}
}
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