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ladybird/Userland/Libraries/LibJS/Bytecode/Op.cpp
davidot 830ea0414c LibJS: Make scoping follow the spec 
Before this we used an ad-hoc combination of references and 'variables'
stored in a hashmap. This worked in most cases but is not spec like.
Additionally hoisting, dynamically naming functions and scope analysis
was not done properly.

This patch fixes all of that by:
  - Implement BindingInitialization for destructuring assignment.
  - Implementing a new ScopePusher which tracks the lexical and var
    scoped declarations. This hoists functions to the top level if no
    lexical declaration name overlaps. Furthermore we do checking of
    redeclarations in the ScopePusher now requiring less checks all over
    the place.
  - Add methods for parsing the directives and statement lists instead
    of having that code duplicated in multiple places. This allows
    declarations to pushed to the appropriate scope more easily.
  - Remove the non spec way of storing 'variables' in
    DeclarativeEnvironment and make Reference follow the spec instead of
    checking both the bindings and 'variables'.
  - Remove all scoping related things from the Interpreter. And instead
    use environments as specified by the spec. This also includes fixing
    that NativeFunctions did not produce a valid FunctionEnvironment
    which could cause issues with callbacks and eval. All
    FunctionObjects now have a valid NewFunctionEnvironment
    implementation.
  - Remove execute_statements from Interpreter and instead use
    ASTNode::execute everywhere this simplifies AST.cpp as you no longer
    need to worry about which method to call.
  - Make ScopeNodes setup their own environment. This uses four
    different methods specified by the spec
    {Block, Function, Eval, Global}DeclarationInstantiation with the
    annexB extensions.
  - Implement and use NamedEvaluation where specified.

Additionally there are fixes to things exposed by these changes to eval,
{for, for-in, for-of} loops and assignment.

Finally it also fixes some tests in test-js which where passing before
but not now that we have correct behavior :^).
2021-09-30 08:16:32 +01:00

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/*
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2021, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2021, Gunnar Beutner <gbeutner@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/HashTable.h>
#include <LibJS/Bytecode/Interpreter.h>
#include <LibJS/Bytecode/Op.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/BigInt.h>
#include <LibJS/Runtime/DeclarativeEnvironment.h>
#include <LibJS/Runtime/ECMAScriptFunctionObject.h>
#include <LibJS/Runtime/Environment.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/IteratorOperations.h>
#include <LibJS/Runtime/RegExpObject.h>
#include <LibJS/Runtime/Value.h>
namespace JS::Bytecode {
String Instruction::to_string(Bytecode::Executable const& executable) const
{
#define __BYTECODE_OP(op) \
case Instruction::Type::op: \
return static_cast<Bytecode::Op::op const&>(*this).to_string_impl(executable);
switch (type()) {
ENUMERATE_BYTECODE_OPS(__BYTECODE_OP)
default:
VERIFY_NOT_REACHED();
}
#undef __BYTECODE_OP
}
}
namespace JS::Bytecode::Op {
void Load::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = interpreter.reg(m_src);
}
void LoadImmediate::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = m_value;
}
void Store::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.reg(m_dst) = interpreter.accumulator();
}
static Value abstract_inequals(GlobalObject& global_object, Value src1, Value src2)
{
return Value(!is_loosely_equal(global_object, src1, src2));
}
static Value abstract_equals(GlobalObject& global_object, Value src1, Value src2)
{
return Value(is_loosely_equal(global_object, src1, src2));
}
static Value typed_inequals(GlobalObject&, Value src1, Value src2)
{
return Value(!is_strictly_equal(src1, src2));
}
static Value typed_equals(GlobalObject&, Value src1, Value src2)
{
return Value(is_strictly_equal(src1, src2));
}
#define JS_DEFINE_COMMON_BINARY_OP(OpTitleCase, op_snake_case) \
void OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto lhs = interpreter.reg(m_lhs_reg); \
auto rhs = interpreter.accumulator(); \
interpreter.accumulator() = op_snake_case(interpreter.global_object(), lhs, rhs); \
} \
String OpTitleCase::to_string_impl(Bytecode::Executable const&) const \
{ \
return String::formatted(#OpTitleCase " {}", m_lhs_reg); \
}
JS_ENUMERATE_COMMON_BINARY_OPS(JS_DEFINE_COMMON_BINARY_OP)
static Value not_(GlobalObject&, Value value)
{
return Value(!value.to_boolean());
}
static Value typeof_(GlobalObject& global_object, Value value)
{
return js_string(global_object.vm(), value.typeof());
}
#define JS_DEFINE_COMMON_UNARY_OP(OpTitleCase, op_snake_case) \
void OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
interpreter.accumulator() = op_snake_case(interpreter.global_object(), interpreter.accumulator()); \
} \
String OpTitleCase::to_string_impl(Bytecode::Executable const&) const \
{ \
return #OpTitleCase; \
}
JS_ENUMERATE_COMMON_UNARY_OPS(JS_DEFINE_COMMON_UNARY_OP)
void NewBigInt::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = js_bigint(interpreter.vm().heap(), m_bigint);
}
void NewArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
Vector<Value> elements;
elements.ensure_capacity(m_element_count);
for (size_t i = 0; i < m_element_count; i++)
elements.append(interpreter.reg(m_elements[i]));
interpreter.accumulator() = Array::create_from(interpreter.global_object(), elements);
}
void IteratorToArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& global_object = interpreter.global_object();
auto& vm = interpreter.vm();
auto iterator = interpreter.accumulator().to_object(global_object);
if (vm.exception())
return;
auto array = Array::create(global_object, 0);
size_t index = 0;
while (true) {
auto iterator_result = iterator_next(*iterator);
if (!iterator_result)
return;
auto complete = iterator_complete(global_object, *iterator_result);
if (vm.exception())
return;
if (complete) {
interpreter.accumulator() = array;
return;
}
auto value = iterator_value(global_object, *iterator_result);
if (vm.exception())
return;
array->create_data_property_or_throw(index, value);
index++;
}
}
void NewString::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = js_string(interpreter.vm(), interpreter.current_executable().get_string(m_string));
}
void NewObject::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = Object::create(interpreter.global_object(), interpreter.global_object().object_prototype());
}
void NewRegExp::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto source = interpreter.current_executable().get_string(m_source_index);
auto flags = interpreter.current_executable().get_string(m_flags_index);
interpreter.accumulator() = regexp_create(interpreter.global_object(), js_string(interpreter.vm(), source), js_string(interpreter.vm(), flags));
}
void CopyObjectExcludingProperties::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto* from_object = interpreter.reg(m_from_object).to_object(interpreter.global_object());
if (interpreter.vm().exception())
return;
auto* to_object = Object::create(interpreter.global_object(), interpreter.global_object().object_prototype());
HashTable<Value, ValueTraits> excluded_names;
for (size_t i = 0; i < m_excluded_names_count; ++i) {
excluded_names.set(interpreter.reg(m_excluded_names[i]));
if (interpreter.vm().exception())
return;
}
auto own_keys_or_error = from_object->internal_own_property_keys();
if (own_keys_or_error.is_error())
return;
auto own_keys = own_keys_or_error.release_value();
for (auto& key : own_keys) {
if (!excluded_names.contains(key)) {
auto property_name = PropertyName(key.to_property_key(interpreter.global_object()));
auto property_value = from_object->get(property_name);
if (interpreter.vm().exception())
return;
to_object->define_direct_property(property_name, property_value, JS::default_attributes);
}
}
interpreter.accumulator() = to_object;
}
void ConcatString::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.reg(m_lhs) = add(interpreter.global_object(), interpreter.reg(m_lhs), interpreter.accumulator());
}
void GetVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto reference = vm.resolve_binding(interpreter.current_executable().get_string(m_identifier));
if (vm.exception())
return;
interpreter.accumulator() = reference.get_value(interpreter.global_object());
}
void SetVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto reference = vm.resolve_binding(interpreter.current_executable().get_string(m_identifier));
if (vm.exception())
return;
reference.put_value(interpreter.global_object(), interpreter.accumulator());
}
void GetById::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* object = interpreter.accumulator().to_object(interpreter.global_object()))
interpreter.accumulator() = object->get(interpreter.current_executable().get_string(m_property));
}
void PutById::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* object = interpreter.reg(m_base).to_object(interpreter.global_object()))
object->set(interpreter.current_executable().get_string(m_property), interpreter.accumulator(), Object::ShouldThrowExceptions::Yes);
}
void Jump::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.jump(*m_true_target);
}
void Jump::replace_references_impl(BasicBlock const& from, BasicBlock const& to)
{
if (m_true_target.has_value() && &m_true_target->block() == &from)
m_true_target = Label { to };
if (m_false_target.has_value() && &m_false_target->block() == &from)
m_false_target = Label { to };
}
void JumpConditional::execute_impl(Bytecode::Interpreter& interpreter) const
{
VERIFY(m_true_target.has_value());
VERIFY(m_false_target.has_value());
auto result = interpreter.accumulator();
if (result.to_boolean())
interpreter.jump(m_true_target.value());
else
interpreter.jump(m_false_target.value());
}
void JumpNullish::execute_impl(Bytecode::Interpreter& interpreter) const
{
VERIFY(m_true_target.has_value());
VERIFY(m_false_target.has_value());
auto result = interpreter.accumulator();
if (result.is_nullish())
interpreter.jump(m_true_target.value());
else
interpreter.jump(m_false_target.value());
}
void JumpUndefined::execute_impl(Bytecode::Interpreter& interpreter) const
{
VERIFY(m_true_target.has_value());
VERIFY(m_false_target.has_value());
auto result = interpreter.accumulator();
if (result.is_undefined())
interpreter.jump(m_true_target.value());
else
interpreter.jump(m_false_target.value());
}
void Call::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto callee = interpreter.reg(m_callee);
if (!callee.is_function()) {
TODO();
}
auto& function = callee.as_function();
auto this_value = interpreter.reg(m_this_value);
Value return_value;
if (m_argument_count == 0 && m_type == CallType::Call) {
auto return_value_or_error = interpreter.vm().call(function, this_value);
if (!return_value_or_error.is_error())
return_value = return_value_or_error.release_value();
} else {
MarkedValueList argument_values { interpreter.vm().heap() };
for (size_t i = 0; i < m_argument_count; ++i) {
argument_values.append(interpreter.reg(m_arguments[i]));
}
if (m_type == CallType::Call) {
auto return_value_or_error = interpreter.vm().call(function, this_value, move(argument_values));
if (!return_value_or_error.is_error())
return_value = return_value_or_error.release_value();
} else {
return_value = interpreter.vm().construct(function, function, move(argument_values));
}
}
interpreter.accumulator() = return_value;
}
void NewFunction::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
interpreter.accumulator() = ECMAScriptFunctionObject::create(interpreter.global_object(), m_function_node.name(), m_function_node.body(), m_function_node.parameters(), m_function_node.function_length(), vm.lexical_environment(), m_function_node.kind(), m_function_node.is_strict_mode(), m_function_node.is_arrow_function());
}
void Return::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.do_return(interpreter.accumulator().value_or(js_undefined()));
}
void Increment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto old_value = interpreter.accumulator().to_numeric(interpreter.global_object());
if (interpreter.vm().exception())
return;
if (old_value.is_number())
interpreter.accumulator() = Value(old_value.as_double() + 1);
else
interpreter.accumulator() = js_bigint(interpreter.vm().heap(), old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 }));
}
void Decrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto old_value = interpreter.accumulator().to_numeric(interpreter.global_object());
if (interpreter.vm().exception())
return;
if (old_value.is_number())
interpreter.accumulator() = Value(old_value.as_double() - 1);
else
interpreter.accumulator() = js_bigint(interpreter.vm().heap(), old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 }));
}
void Throw::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.vm().throw_exception(interpreter.global_object(), interpreter.accumulator());
}
void EnterUnwindContext::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.enter_unwind_context(m_handler_target, m_finalizer_target);
interpreter.jump(m_entry_point);
}
void EnterUnwindContext::replace_references_impl(BasicBlock const& from, BasicBlock const& to)
{
if (&m_entry_point.block() == &from)
m_entry_point = Label { to };
if (m_handler_target.has_value() && &m_handler_target->block() == &from)
m_handler_target = Label { to };
if (m_finalizer_target.has_value() && &m_finalizer_target->block() == &from)
m_finalizer_target = Label { to };
}
void LeaveUnwindContext::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.leave_unwind_context();
}
void ContinuePendingUnwind::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.continue_pending_unwind(m_resume_target);
}
void ContinuePendingUnwind::replace_references_impl(BasicBlock const& from, BasicBlock const& to)
{
if (&m_resume_target.block() == &from)
m_resume_target = Label { to };
}
void PushDeclarativeEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto* environment = interpreter.vm().heap().allocate<DeclarativeEnvironment>(interpreter.global_object(), interpreter.vm().lexical_environment());
interpreter.vm().running_execution_context().lexical_environment = environment;
interpreter.vm().running_execution_context().variable_environment = environment;
}
void Yield::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto yielded_value = interpreter.accumulator().value_or(js_undefined());
auto object = JS::Object::create(interpreter.global_object(), nullptr);
object->define_direct_property("result", yielded_value, JS::default_attributes);
if (m_continuation_label.has_value())
object->define_direct_property("continuation", Value(static_cast<double>(reinterpret_cast<u64>(&m_continuation_label->block()))), JS::default_attributes);
else
object->define_direct_property("continuation", Value(0), JS::default_attributes);
interpreter.do_return(object);
}
void Yield::replace_references_impl(BasicBlock const& from, BasicBlock const& to)
{
if (m_continuation_label.has_value() && &m_continuation_label->block() == &from)
m_continuation_label = Label { to };
}
void GetByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* object = interpreter.reg(m_base).to_object(interpreter.global_object())) {
auto property_key = interpreter.accumulator().to_property_key(interpreter.global_object());
if (interpreter.vm().exception())
return;
interpreter.accumulator() = object->get(property_key);
}
}
void PutByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* object = interpreter.reg(m_base).to_object(interpreter.global_object())) {
auto property_key = interpreter.reg(m_property).to_property_key(interpreter.global_object());
if (interpreter.vm().exception())
return;
object->set(property_key, interpreter.accumulator(), Object::ShouldThrowExceptions::Yes);
}
}
void GetIterator::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.accumulator() = get_iterator(interpreter.global_object(), interpreter.accumulator());
}
void IteratorNext::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* object = interpreter.accumulator().to_object(interpreter.global_object()))
interpreter.accumulator() = iterator_next(*object);
}
void IteratorResultDone::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* iterator_result = interpreter.accumulator().to_object(interpreter.global_object()))
interpreter.accumulator() = Value(iterator_complete(interpreter.global_object(), *iterator_result));
}
void IteratorResultValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (auto* iterator_result = interpreter.accumulator().to_object(interpreter.global_object()))
interpreter.accumulator() = iterator_value(interpreter.global_object(), *iterator_result);
}
void NewClass::execute_impl(Bytecode::Interpreter&) const
{
(void)m_class_expression;
TODO();
}
String Load::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("Load {}", m_src);
}
String LoadImmediate::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("LoadImmediate {}", m_value);
}
String Store::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("Store {}", m_dst);
}
String NewBigInt::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("NewBigInt \"{}\"", m_bigint.to_base(10));
}
String NewArray::to_string_impl(Bytecode::Executable const&) const
{
StringBuilder builder;
builder.append("NewArray");
if (m_element_count != 0) {
builder.append(" [");
for (size_t i = 0; i < m_element_count; ++i) {
builder.appendff("{}", m_elements[i]);
if (i != m_element_count - 1)
builder.append(',');
}
builder.append(']');
}
return builder.to_string();
}
String IteratorToArray::to_string_impl(const Bytecode::Executable&) const
{
return "IteratorToArray";
}
String NewString::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("NewString {} (\"{}\")", m_string, executable.string_table->get(m_string));
}
String NewObject::to_string_impl(Bytecode::Executable const&) const
{
return "NewObject";
}
String NewRegExp::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("NewRegExp source:{} (\"{}\") flags:{} (\"{}\")", m_source_index, executable.get_string(m_source_index), m_flags_index, executable.get_string(m_flags_index));
}
String CopyObjectExcludingProperties::to_string_impl(const Bytecode::Executable&) const
{
StringBuilder builder;
builder.appendff("CopyObjectExcludingProperties from:{}", m_from_object);
if (m_excluded_names_count != 0) {
builder.append(" excluding:[");
for (size_t i = 0; i < m_excluded_names_count; ++i) {
builder.appendff("{}", m_excluded_names[i]);
if (i != m_excluded_names_count - 1)
builder.append(',');
}
builder.append(']');
}
return builder.to_string();
}
String ConcatString::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("ConcatString {}", m_lhs);
}
String GetVariable::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("GetVariable {} ({})", m_identifier, executable.string_table->get(m_identifier));
}
String SetVariable::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("SetVariable {} ({})", m_identifier, executable.string_table->get(m_identifier));
}
String PutById::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("PutById base:{}, property:{} ({})", m_base, m_property, executable.string_table->get(m_property));
}
String GetById::to_string_impl(Bytecode::Executable const& executable) const
{
return String::formatted("GetById {} ({})", m_property, executable.string_table->get(m_property));
}
String Jump::to_string_impl(Bytecode::Executable const&) const
{
if (m_true_target.has_value())
return String::formatted("Jump {}", *m_true_target);
return String::formatted("Jump <empty>");
}
String JumpConditional::to_string_impl(Bytecode::Executable const&) const
{
auto true_string = m_true_target.has_value() ? String::formatted("{}", *m_true_target) : "<empty>";
auto false_string = m_false_target.has_value() ? String::formatted("{}", *m_false_target) : "<empty>";
return String::formatted("JumpConditional true:{} false:{}", true_string, false_string);
}
String JumpNullish::to_string_impl(Bytecode::Executable const&) const
{
auto true_string = m_true_target.has_value() ? String::formatted("{}", *m_true_target) : "<empty>";
auto false_string = m_false_target.has_value() ? String::formatted("{}", *m_false_target) : "<empty>";
return String::formatted("JumpNullish null:{} nonnull:{}", true_string, false_string);
}
String JumpUndefined::to_string_impl(Bytecode::Executable const&) const
{
auto true_string = m_true_target.has_value() ? String::formatted("{}", *m_true_target) : "<empty>";
auto false_string = m_false_target.has_value() ? String::formatted("{}", *m_false_target) : "<empty>";
return String::formatted("JumpUndefined undefined:{} not undefined:{}", true_string, false_string);
}
String Call::to_string_impl(Bytecode::Executable const&) const
{
StringBuilder builder;
builder.appendff("Call callee:{}, this:{}", m_callee, m_this_value);
if (m_argument_count != 0) {
builder.append(", arguments:[");
for (size_t i = 0; i < m_argument_count; ++i) {
builder.appendff("{}", m_arguments[i]);
if (i != m_argument_count - 1)
builder.append(',');
}
builder.append(']');
}
return builder.to_string();
}
String NewFunction::to_string_impl(Bytecode::Executable const&) const
{
return "NewFunction";
}
String NewClass::to_string_impl(Bytecode::Executable const&) const
{
return "NewClass";
}
String Return::to_string_impl(Bytecode::Executable const&) const
{
return "Return";
}
String Increment::to_string_impl(Bytecode::Executable const&) const
{
return "Increment";
}
String Decrement::to_string_impl(Bytecode::Executable const&) const
{
return "Decrement";
}
String Throw::to_string_impl(Bytecode::Executable const&) const
{
return "Throw";
}
String EnterUnwindContext::to_string_impl(Bytecode::Executable const&) const
{
auto handler_string = m_handler_target.has_value() ? String::formatted("{}", *m_handler_target) : "<empty>";
auto finalizer_string = m_finalizer_target.has_value() ? String::formatted("{}", *m_finalizer_target) : "<empty>";
return String::formatted("EnterUnwindContext handler:{} finalizer:{} entry:{}", handler_string, finalizer_string, m_entry_point);
}
String LeaveUnwindContext::to_string_impl(Bytecode::Executable const&) const
{
return "LeaveUnwindContext";
}
String ContinuePendingUnwind::to_string_impl(Bytecode::Executable const&) const
{
return String::formatted("ContinuePendingUnwind resume:{}", m_resume_target);
}
String PushDeclarativeEnvironment::to_string_impl(const Bytecode::Executable& executable) const
{
StringBuilder builder;
builder.append("PushDeclarativeEnvironment");
if (!m_variables.is_empty()) {
builder.append(" {");
Vector<String> names;
for (auto& it : m_variables)
names.append(executable.get_string(it.key));
builder.join(", ", names);
builder.append("}");
}
return builder.to_string();
}
String Yield::to_string_impl(Bytecode::Executable const&) const
{
if (m_continuation_label.has_value())
return String::formatted("Yield continuation:@{}", m_continuation_label->block().name());
return String::formatted("Yield return");
}
String GetByValue::to_string_impl(const Bytecode::Executable&) const
{
return String::formatted("GetByValue base:{}", m_base);
}
String PutByValue::to_string_impl(const Bytecode::Executable&) const
{
return String::formatted("PutByValue base:{}, property:{}", m_base, m_property);
}
String GetIterator::to_string_impl(Executable const&) const
{
return "GetIterator";
}
String IteratorNext::to_string_impl(Executable const&) const
{
return "IteratorNext";
}
String IteratorResultDone::to_string_impl(Executable const&) const
{
return "IteratorResultDone";
}
String IteratorResultValue::to_string_impl(Executable const&) const
{
return "IteratorResultValue";
}
}
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