Stowage/ladybird
2
0
Fork 0
mirror of https://github.com/LadybirdBrowser/ladybird.git synced 2025-10-31 21:30:58 +00:00
Code Issues Projects Releases Packages Wiki Activity
ladybird/Userland/Libraries/LibJS/Bytecode/Interpreter.cpp
Andreas Kling 509c10d14d LibJS: Make GetById and GetByValue avoid get_identifier() in common case 
We now defer looking up the various identifiers by IdentifierTableIndex
until the last moment. This allows us to avoid the retrieval in common
cases like when a property access is cached.

Knocks a ~12% item off the profile on https://ventrella.com/Clusters/
2024-07-09 14:16:11 +02:00

3664 lines
158 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2021-2024, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Debug.h>
#include <AK/HashTable.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/Interpreter.h>
#include <LibJS/Bytecode/Label.h>
#include <LibJS/Bytecode/Op.h>
#include <LibJS/Runtime/AbstractOperations.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/FunctionEnvironment.h>
#include <LibJS/Runtime/GlobalEnvironment.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/Iterator.h>
#include <LibJS/Runtime/MathObject.h>
#include <LibJS/Runtime/NativeFunction.h>
#include <LibJS/Runtime/ObjectEnvironment.h>
#include <LibJS/Runtime/Realm.h>
#include <LibJS/Runtime/Reference.h>
#include <LibJS/Runtime/RegExpObject.h>
#include <LibJS/Runtime/TypedArray.h>
#include <LibJS/Runtime/Value.h>
#include <LibJS/Runtime/ValueInlines.h>
#include <LibJS/SourceTextModule.h>
namespace JS::Bytecode {
bool g_dump_bytecode = false;
static ByteString format_operand(StringView name, Operand operand, Bytecode::Executable const& executable)
{
StringBuilder builder;
if (!name.is_empty())
builder.appendff("\033[32m{}\033[0m:", name);
switch (operand.type()) {
case Operand::Type::Register:
if (operand.index() == Register::this_value().index()) {
builder.appendff("\033[33mthis\033[0m");
} else {
builder.appendff("\033[33mreg{}\033[0m", operand.index());
}
break;
case Operand::Type::Local:
builder.appendff("\033[34m{}~{}\033[0m", executable.local_variable_names[operand.index() - executable.local_index_base], operand.index() - executable.local_index_base);
break;
case Operand::Type::Constant: {
builder.append("\033[36m"sv);
auto value = executable.constants[operand.index() - executable.number_of_registers];
if (value.is_empty())
builder.append("<Empty>"sv);
else if (value.is_boolean())
builder.appendff("Bool({})", value.as_bool() ? "true"sv : "false"sv);
else if (value.is_int32())
builder.appendff("Int32({})", value.as_i32());
else if (value.is_double())
builder.appendff("Double({})", value.as_double());
else if (value.is_bigint())
builder.appendff("BigInt({})", value.as_bigint().to_byte_string());
else if (value.is_string())
builder.appendff("String(\"{}\")", value.as_string().utf8_string_view());
else if (value.is_undefined())
builder.append("Undefined"sv);
else if (value.is_null())
builder.append("Null"sv);
else
builder.appendff("Value: {}", value);
builder.append("\033[0m"sv);
break;
}
default:
VERIFY_NOT_REACHED();
}
return builder.to_byte_string();
}
static ByteString format_operand_list(StringView name, ReadonlySpan<Operand> operands, Bytecode::Executable const& executable)
{
StringBuilder builder;
if (!name.is_empty())
builder.appendff("\033[32m{}\033[0m:[", name);
for (size_t i = 0; i < operands.size(); ++i) {
if (i != 0)
builder.append(", "sv);
builder.appendff("{}", format_operand(""sv, operands[i], executable));
}
builder.append("]"sv);
return builder.to_byte_string();
}
static ByteString format_value_list(StringView name, ReadonlySpan<Value> values)
{
StringBuilder builder;
if (!name.is_empty())
builder.appendff("\033[32m{}\033[0m:[", name);
builder.join(", "sv, values);
builder.append("]"sv);
return builder.to_byte_string();
}
ALWAYS_INLINE static ThrowCompletionOr<Value> loosely_inequals(VM& vm, Value src1, Value src2)
{
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() != src2.encoded());
}
return Value(!TRY(is_loosely_equal(vm, src1, src2)));
}
ALWAYS_INLINE static ThrowCompletionOr<Value> loosely_equals(VM& vm, Value src1, Value src2)
{
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() == src2.encoded());
}
return Value(TRY(is_loosely_equal(vm, src1, src2)));
}
ALWAYS_INLINE static ThrowCompletionOr<Value> strict_inequals(VM&, Value src1, Value src2)
{
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() != src2.encoded());
}
return Value(!is_strictly_equal(src1, src2));
}
ALWAYS_INLINE static ThrowCompletionOr<Value> strict_equals(VM&, Value src1, Value src2)
{
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() == src2.encoded());
}
return Value(is_strictly_equal(src1, src2));
}
Interpreter::Interpreter(VM& vm)
: m_vm(vm)
{
}
Interpreter::~Interpreter()
{
}
ALWAYS_INLINE Value Interpreter::get(Operand op) const
{
return m_registers_and_constants_and_locals.data()[op.index()];
}
ALWAYS_INLINE void Interpreter::set(Operand op, Value value)
{
m_registers_and_constants_and_locals.data()[op.index()] = value;
}
ALWAYS_INLINE Value Interpreter::do_yield(Value value, Optional<Label> continuation)
{
auto object = Object::create(realm(), nullptr);
object->define_direct_property("result", value, JS::default_attributes);
if (continuation.has_value())
// FIXME: If we get a pointer, which is not accurately representable as a double
// will cause this to explode
object->define_direct_property("continuation", Value(continuation->address()), JS::default_attributes);
else
object->define_direct_property("continuation", js_null(), JS::default_attributes);
object->define_direct_property("isAwait", Value(false), JS::default_attributes);
return object;
}
// 16.1.6 ScriptEvaluation ( scriptRecord ), https://tc39.es/ecma262/#sec-runtime-semantics-scriptevaluation
ThrowCompletionOr<Value> Interpreter::run(Script& script_record, JS::GCPtr<Environment> lexical_environment_override)
{
auto& vm = this->vm();
// 1. Let globalEnv be scriptRecord.[[Realm]].[[GlobalEnv]].
auto& global_environment = script_record.realm().global_environment();
// 2. Let scriptContext be a new ECMAScript code execution context.
auto script_context = ExecutionContext::create();
// 3. Set the Function of scriptContext to null.
// NOTE: This was done during execution context construction.
// 4. Set the Realm of scriptContext to scriptRecord.[[Realm]].
script_context->realm = &script_record.realm();
// 5. Set the ScriptOrModule of scriptContext to scriptRecord.
script_context->script_or_module = NonnullGCPtr<Script>(script_record);
// 6. Set the VariableEnvironment of scriptContext to globalEnv.
script_context->variable_environment = &global_environment;
// 7. Set the LexicalEnvironment of scriptContext to globalEnv.
script_context->lexical_environment = &global_environment;
// Non-standard: Override the lexical environment if requested.
if (lexical_environment_override)
script_context->lexical_environment = lexical_environment_override;
// 8. Set the PrivateEnvironment of scriptContext to null.
// NOTE: This isn't in the spec, but we require it.
script_context->is_strict_mode = script_record.parse_node().is_strict_mode();
// FIXME: 9. Suspend the currently running execution context.
// 10. Push scriptContext onto the execution context stack; scriptContext is now the running execution context.
TRY(vm.push_execution_context(*script_context, {}));
// 11. Let script be scriptRecord.[[ECMAScriptCode]].
auto& script = script_record.parse_node();
// 12. Let result be Completion(GlobalDeclarationInstantiation(script, globalEnv)).
auto instantiation_result = script.global_declaration_instantiation(vm, global_environment);
Completion result = instantiation_result.is_throw_completion() ? instantiation_result.throw_completion() : normal_completion({});
// 13. If result.[[Type]] is normal, then
if (result.type() == Completion::Type::Normal) {
auto executable_result = JS::Bytecode::Generator::generate_from_ast_node(vm, script, {});
if (executable_result.is_error()) {
if (auto error_string = executable_result.error().to_string(); error_string.is_error())
result = vm.template throw_completion<JS::InternalError>(vm.error_message(JS::VM::ErrorMessage::OutOfMemory));
else if (error_string = String::formatted("TODO({})", error_string.value()); error_string.is_error())
result = vm.template throw_completion<JS::InternalError>(vm.error_message(JS::VM::ErrorMessage::OutOfMemory));
else
result = JS::throw_completion(JS::InternalError::create(realm(), error_string.release_value()));
} else {
auto executable = executable_result.release_value();
if (g_dump_bytecode)
executable->dump();
// a. Set result to the result of evaluating script.
auto result_or_error = run_executable(*executable, {}, {});
if (result_or_error.value.is_error())
result = result_or_error.value.release_error();
else
result = result_or_error.return_register_value;
}
}
// 14. If result.[[Type]] is normal and result.[[Value]] is empty, then
if (result.type() == Completion::Type::Normal && !result.value().has_value()) {
// a. Set result to NormalCompletion(undefined).
result = normal_completion(js_undefined());
}
// FIXME: 15. Suspend scriptContext and remove it from the execution context stack.
vm.pop_execution_context();
// 16. Assert: The execution context stack is not empty.
VERIFY(!vm.execution_context_stack().is_empty());
// FIXME: 17. Resume the context that is now on the top of the execution context stack as the running execution context.
// At this point we may have already run any queued promise jobs via on_call_stack_emptied,
// in which case this is a no-op.
// FIXME: These three should be moved out of Interpreter::run and give the host an option to run these, as it's up to the host when these get run.
// https://tc39.es/ecma262/#sec-jobs for jobs and https://tc39.es/ecma262/#_ref_3508 for ClearKeptObjects
// finish_execution_generation is particularly an issue for LibWeb, as the HTML spec wants to run it specifically after performing a microtask checkpoint.
// The promise and registry cleanup queues don't cause LibWeb an issue, as LibWeb overrides the hooks that push onto these queues.
vm.run_queued_promise_jobs();
vm.run_queued_finalization_registry_cleanup_jobs();
vm.finish_execution_generation();
// 18. Return ? result.
if (result.is_abrupt()) {
VERIFY(result.type() == Completion::Type::Throw);
return result.release_error();
}
VERIFY(result.value().has_value());
return *result.value();
}
ThrowCompletionOr<Value> Interpreter::run(SourceTextModule& module)
{
// FIXME: This is not a entry point as defined in the spec, but is convenient.
// To avoid work we use link_and_eval_module however that can already be
// dangerous if the vm loaded other modules.
auto& vm = this->vm();
TRY(vm.link_and_eval_module(Badge<Bytecode::Interpreter> {}, module));
vm.run_queued_promise_jobs();
vm.run_queued_finalization_registry_cleanup_jobs();
return js_undefined();
}
Interpreter::HandleExceptionResponse Interpreter::handle_exception(size_t& program_counter, Value exception)
{
reg(Register::exception()) = exception;
m_scheduled_jump = {};
auto handlers = current_executable().exception_handlers_for_offset(program_counter);
if (!handlers.has_value()) {
return HandleExceptionResponse::ExitFromExecutable;
}
auto& handler = handlers->handler_offset;
auto& finalizer = handlers->finalizer_offset;
VERIFY(!running_execution_context().unwind_contexts.is_empty());
auto& unwind_context = running_execution_context().unwind_contexts.last();
VERIFY(unwind_context.executable == m_current_executable);
if (handler.has_value()) {
program_counter = handler.value();
return HandleExceptionResponse::ContinueInThisExecutable;
}
if (finalizer.has_value()) {
program_counter = finalizer.value();
return HandleExceptionResponse::ContinueInThisExecutable;
}
VERIFY_NOT_REACHED();
}
// FIXME: GCC takes a *long* time to compile with flattening, and it will time out our CI. :|
#if defined(AK_COMPILER_CLANG)
# define FLATTEN_ON_CLANG FLATTEN
#else
# define FLATTEN_ON_CLANG
#endif
FLATTEN_ON_CLANG void Interpreter::run_bytecode(size_t entry_point)
{
if (vm().did_reach_stack_space_limit()) {
reg(Register::exception()) = vm().throw_completion<InternalError>(ErrorType::CallStackSizeExceeded).release_value().value();
return;
}
auto& running_execution_context = this->running_execution_context();
auto* arguments = running_execution_context.arguments.data();
auto& accumulator = this->accumulator();
auto& executable = current_executable();
auto const* bytecode = executable.bytecode.data();
size_t program_counter = entry_point;
TemporaryChange change(m_program_counter, Optional<size_t&>(program_counter));
// Declare a lookup table for computed goto with each of the `handle_*` labels
// to avoid the overhead of a switch statement.
// This is a GCC extension, but it's also supported by Clang.
static void* const bytecode_dispatch_table[] = {
#define SET_UP_LABEL(name) &&handle_##name,
ENUMERATE_BYTECODE_OPS(SET_UP_LABEL)
};
#undef SET_UP_LABEL
#define DISPATCH_NEXT(name) \
do { \
if constexpr (Op::name::IsVariableLength) \
program_counter += instruction.length(); \
else \
program_counter += sizeof(Op::name); \
auto& next_instruction = *reinterpret_cast<Instruction const*>(&bytecode[program_counter]); \
goto* bytecode_dispatch_table[static_cast<size_t>(next_instruction.type())]; \
} while (0)
for (;;) {
start:
for (;;) {
goto* bytecode_dispatch_table[static_cast<size_t>((*reinterpret_cast<Instruction const*>(&bytecode[program_counter])).type())];
handle_GetArgument: {
auto const& instruction = *reinterpret_cast<Op::GetArgument const*>(&bytecode[program_counter]);
set(instruction.dst(), arguments[instruction.index()]);
DISPATCH_NEXT(GetArgument);
}
handle_SetArgument: {
auto const& instruction = *reinterpret_cast<Op::SetArgument const*>(&bytecode[program_counter]);
arguments[instruction.index()] = get(instruction.src());
DISPATCH_NEXT(SetArgument);
}
handle_Mov: {
auto& instruction = *reinterpret_cast<Op::Mov const*>(&bytecode[program_counter]);
set(instruction.dst(), get(instruction.src()));
DISPATCH_NEXT(Mov);
}
handle_End: {
auto& instruction = *reinterpret_cast<Op::End const*>(&bytecode[program_counter]);
accumulator = get(instruction.value());
return;
}
handle_Jump: {
auto& instruction = *reinterpret_cast<Op::Jump const*>(&bytecode[program_counter]);
program_counter = instruction.target().address();
goto start;
}
handle_JumpIf: {
auto& instruction = *reinterpret_cast<Op::JumpIf const*>(&bytecode[program_counter]);
if (get(instruction.condition()).to_boolean())
program_counter = instruction.true_target().address();
else
program_counter = instruction.false_target().address();
goto start;
}
handle_JumpTrue: {
auto& instruction = *reinterpret_cast<Op::JumpTrue const*>(&bytecode[program_counter]);
if (get(instruction.condition()).to_boolean()) {
program_counter = instruction.target().address();
goto start;
}
DISPATCH_NEXT(JumpTrue);
}
handle_JumpFalse: {
auto& instruction = *reinterpret_cast<Op::JumpFalse const*>(&bytecode[program_counter]);
if (!get(instruction.condition()).to_boolean()) {
program_counter = instruction.target().address();
goto start;
}
DISPATCH_NEXT(JumpFalse);
}
handle_JumpNullish: {
auto& instruction = *reinterpret_cast<Op::JumpNullish const*>(&bytecode[program_counter]);
if (get(instruction.condition()).is_nullish())
program_counter = instruction.true_target().address();
else
program_counter = instruction.false_target().address();
goto start;
}
#define HANDLE_COMPARISON_OP(op_TitleCase, op_snake_case, numeric_operator) \
handle_Jump##op_TitleCase: \
{ \
auto& instruction = *reinterpret_cast<Op::Jump##op_TitleCase const*>(&bytecode[program_counter]); \
auto lhs = get(instruction.lhs()); \
auto rhs = get(instruction.rhs()); \
if (lhs.is_number() && rhs.is_number()) { \
bool result; \
if (lhs.is_int32() && rhs.is_int32()) { \
result = lhs.as_i32() numeric_operator rhs.as_i32(); \
} else { \
result = lhs.as_double() numeric_operator rhs.as_double(); \
} \
program_counter = result ? instruction.true_target().address() : instruction.false_target().address(); \
goto start; \
} \
auto result = op_snake_case(vm(), get(instruction.lhs()), get(instruction.rhs())); \
if (result.is_error()) { \
if (handle_exception(program_counter, result.error_value()) == HandleExceptionResponse::ExitFromExecutable) \
return; \
goto start; \
} \
if (result.value().to_boolean()) \
program_counter = instruction.true_target().address(); \
else \
program_counter = instruction.false_target().address(); \
goto start; \
}
JS_ENUMERATE_COMPARISON_OPS(HANDLE_COMPARISON_OP)
#undef HANDLE_COMPARISON_OP
handle_JumpUndefined: {
auto& instruction = *reinterpret_cast<Op::JumpUndefined const*>(&bytecode[program_counter]);
if (get(instruction.condition()).is_undefined())
program_counter = instruction.true_target().address();
else
program_counter = instruction.false_target().address();
goto start;
}
handle_EnterUnwindContext: {
auto& instruction = *reinterpret_cast<Op::EnterUnwindContext const*>(&bytecode[program_counter]);
enter_unwind_context();
program_counter = instruction.entry_point().address();
goto start;
}
handle_ContinuePendingUnwind: {
auto& instruction = *reinterpret_cast<Op::ContinuePendingUnwind const*>(&bytecode[program_counter]);
if (auto exception = reg(Register::exception()); !exception.is_empty()) {
if (handle_exception(program_counter, exception) == HandleExceptionResponse::ExitFromExecutable)
return;
goto start;
}
if (!saved_return_value().is_empty()) {
do_return(saved_return_value());
if (auto handlers = executable.exception_handlers_for_offset(program_counter); handlers.has_value()) {
if (auto finalizer = handlers.value().finalizer_offset; finalizer.has_value()) {
VERIFY(!running_execution_context.unwind_contexts.is_empty());
auto& unwind_context = running_execution_context.unwind_contexts.last();
VERIFY(unwind_context.executable == m_current_executable);
reg(Register::saved_return_value()) = reg(Register::return_value());
reg(Register::return_value()) = {};
program_counter = finalizer.value();
// the unwind_context will be pop'ed when entering the finally block
goto start;
}
}
return;
}
auto const old_scheduled_jump = running_execution_context.previously_scheduled_jumps.take_last();
if (m_scheduled_jump.has_value()) {
program_counter = m_scheduled_jump.value();
m_scheduled_jump = {};
} else {
program_counter = instruction.resume_target().address();
// set the scheduled jump to the old value if we continue
// where we left it
m_scheduled_jump = old_scheduled_jump;
}
goto start;
}
handle_ScheduleJump: {
auto& instruction = *reinterpret_cast<Op::ScheduleJump const*>(&bytecode[program_counter]);
m_scheduled_jump = instruction.target().address();
auto finalizer = executable.exception_handlers_for_offset(program_counter).value().finalizer_offset;
VERIFY(finalizer.has_value());
program_counter = finalizer.value();
goto start;
}
#define HANDLE_INSTRUCTION(name) \
handle_##name: \
{ \
auto& instruction = *reinterpret_cast<Op::name const*>(&bytecode[program_counter]); \
{ \
auto result = instruction.execute_impl(*this); \
if (result.is_error()) { \
if (handle_exception(program_counter, result.error_value()) == HandleExceptionResponse::ExitFromExecutable) \
return; \
goto start; \
} \
} \
DISPATCH_NEXT(name); \
}
#define HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(name) \
handle_##name: \
{ \
auto& instruction = *reinterpret_cast<Op::name const*>(&bytecode[program_counter]); \
instruction.execute_impl(*this); \
DISPATCH_NEXT(name); \
}
HANDLE_INSTRUCTION(Add);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(AddPrivateName);
HANDLE_INSTRUCTION(ArrayAppend);
HANDLE_INSTRUCTION(AsyncIteratorClose);
HANDLE_INSTRUCTION(BitwiseAnd);
HANDLE_INSTRUCTION(BitwiseNot);
HANDLE_INSTRUCTION(BitwiseOr);
HANDLE_INSTRUCTION(BitwiseXor);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(BlockDeclarationInstantiation);
HANDLE_INSTRUCTION(Call);
HANDLE_INSTRUCTION(CallWithArgumentArray);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(Catch);
HANDLE_INSTRUCTION(ConcatString);
HANDLE_INSTRUCTION(CopyObjectExcludingProperties);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(CreateLexicalEnvironment);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(CreateVariableEnvironment);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(CreatePrivateEnvironment);
HANDLE_INSTRUCTION(CreateVariable);
HANDLE_INSTRUCTION(CreateRestParams);
HANDLE_INSTRUCTION(CreateArguments);
HANDLE_INSTRUCTION(Decrement);
HANDLE_INSTRUCTION(DeleteById);
HANDLE_INSTRUCTION(DeleteByIdWithThis);
HANDLE_INSTRUCTION(DeleteByValue);
HANDLE_INSTRUCTION(DeleteByValueWithThis);
HANDLE_INSTRUCTION(DeleteVariable);
HANDLE_INSTRUCTION(Div);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(Dump);
HANDLE_INSTRUCTION(EnterObjectEnvironment);
HANDLE_INSTRUCTION(Exp);
HANDLE_INSTRUCTION(GetById);
HANDLE_INSTRUCTION(GetByIdWithThis);
HANDLE_INSTRUCTION(GetByValue);
HANDLE_INSTRUCTION(GetByValueWithThis);
HANDLE_INSTRUCTION(GetCalleeAndThisFromEnvironment);
HANDLE_INSTRUCTION(GetGlobal);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(GetImportMeta);
HANDLE_INSTRUCTION(GetIterator);
HANDLE_INSTRUCTION(GetLength);
HANDLE_INSTRUCTION(GetLengthWithThis);
HANDLE_INSTRUCTION(GetMethod);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(GetNewTarget);
HANDLE_INSTRUCTION(GetNextMethodFromIteratorRecord);
HANDLE_INSTRUCTION(GetObjectFromIteratorRecord);
HANDLE_INSTRUCTION(GetObjectPropertyIterator);
HANDLE_INSTRUCTION(GetPrivateById);
HANDLE_INSTRUCTION(GetBinding);
HANDLE_INSTRUCTION(GreaterThan);
HANDLE_INSTRUCTION(GreaterThanEquals);
HANDLE_INSTRUCTION(HasPrivateId);
HANDLE_INSTRUCTION(ImportCall);
HANDLE_INSTRUCTION(In);
HANDLE_INSTRUCTION(Increment);
HANDLE_INSTRUCTION(InitializeLexicalBinding);
HANDLE_INSTRUCTION(InitializeVariableBinding);
HANDLE_INSTRUCTION(InstanceOf);
HANDLE_INSTRUCTION(IteratorClose);
HANDLE_INSTRUCTION(IteratorNext);
HANDLE_INSTRUCTION(IteratorToArray);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(LeaveFinally);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(LeaveLexicalEnvironment);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(LeavePrivateEnvironment);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(LeaveUnwindContext);
HANDLE_INSTRUCTION(LeftShift);
HANDLE_INSTRUCTION(LessThan);
HANDLE_INSTRUCTION(LessThanEquals);
HANDLE_INSTRUCTION(LooselyEquals);
HANDLE_INSTRUCTION(LooselyInequals);
HANDLE_INSTRUCTION(Mod);
HANDLE_INSTRUCTION(Mul);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewArray);
HANDLE_INSTRUCTION(NewClass);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewFunction);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewObject);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewPrimitiveArray);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewRegExp);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(NewTypeError);
HANDLE_INSTRUCTION(Not);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(PrepareYield);
HANDLE_INSTRUCTION(PostfixDecrement);
HANDLE_INSTRUCTION(PostfixIncrement);
HANDLE_INSTRUCTION(PutById);
HANDLE_INSTRUCTION(PutByIdWithThis);
HANDLE_INSTRUCTION(PutByValue);
HANDLE_INSTRUCTION(PutByValueWithThis);
HANDLE_INSTRUCTION(PutPrivateById);
HANDLE_INSTRUCTION(ResolveSuperBase);
HANDLE_INSTRUCTION(ResolveThisBinding);
HANDLE_INSTRUCTION_WITHOUT_EXCEPTION_CHECK(RestoreScheduledJump);
HANDLE_INSTRUCTION(RightShift);
HANDLE_INSTRUCTION(SetLexicalBinding);
HANDLE_INSTRUCTION(SetVariableBinding);
HANDLE_INSTRUCTION(StrictlyEquals);
HANDLE_INSTRUCTION(StrictlyInequals);
HANDLE_INSTRUCTION(Sub);
HANDLE_INSTRUCTION(SuperCallWithArgumentArray);
HANDLE_INSTRUCTION(Throw);
HANDLE_INSTRUCTION(ThrowIfNotObject);
HANDLE_INSTRUCTION(ThrowIfNullish);
HANDLE_INSTRUCTION(ThrowIfTDZ);
HANDLE_INSTRUCTION(Typeof);
HANDLE_INSTRUCTION(TypeofBinding);
HANDLE_INSTRUCTION(UnaryMinus);
HANDLE_INSTRUCTION(UnaryPlus);
HANDLE_INSTRUCTION(UnsignedRightShift);
handle_Await: {
auto& instruction = *reinterpret_cast<Op::Await const*>(&bytecode[program_counter]);
instruction.execute_impl(*this);
return;
}
handle_Return: {
auto& instruction = *reinterpret_cast<Op::Return const*>(&bytecode[program_counter]);
instruction.execute_impl(*this);
return;
}
handle_Yield: {
auto& instruction = *reinterpret_cast<Op::Yield const*>(&bytecode[program_counter]);
instruction.execute_impl(*this);
// Note: A `yield` statement will not go through a finally statement,
// hence we need to set a flag to not do so,
// but we generate a Yield Operation in the case of returns in
// generators as well, so we need to check if it will actually
// continue or is a `return` in disguise
return;
}
}
}
}
Interpreter::ResultAndReturnRegister Interpreter::run_executable(Executable& executable, Optional<size_t> entry_point, Value initial_accumulator_value)
{
dbgln_if(JS_BYTECODE_DEBUG, "Bytecode::Interpreter will run unit {:p}", &executable);
TemporaryChange restore_executable { m_current_executable, GCPtr { executable } };
TemporaryChange restore_saved_jump { m_scheduled_jump, Optional<size_t> {} };
TemporaryChange restore_realm { m_realm, GCPtr { vm().current_realm() } };
TemporaryChange restore_global_object { m_global_object, GCPtr { m_realm->global_object() } };
TemporaryChange restore_global_declarative_environment { m_global_declarative_environment, GCPtr { m_realm->global_environment().declarative_record() } };
VERIFY(!vm().execution_context_stack().is_empty());
auto& running_execution_context = vm().running_execution_context();
u32 registers_and_constants_and_locals_count = executable.number_of_registers + executable.constants.size() + executable.local_variable_names.size();
if (running_execution_context.registers_and_constants_and_locals.size() < registers_and_constants_and_locals_count)
running_execution_context.registers_and_constants_and_locals.resize(registers_and_constants_and_locals_count);
TemporaryChange restore_running_execution_context { m_running_execution_context, &running_execution_context };
TemporaryChange restore_arguments { m_arguments, running_execution_context.arguments.span() };
TemporaryChange restore_registers_and_constants_and_locals { m_registers_and_constants_and_locals, running_execution_context.registers_and_constants_and_locals.span() };
reg(Register::accumulator()) = initial_accumulator_value;
reg(Register::return_value()) = {};
// NOTE: We only copy the `this` value from ExecutionContext if it's not already set.
// If we are re-entering an async/generator context, the `this` value
// may have already been cached by a ResolveThisBinding instruction,
// and subsequent instructions expect this value to be set.
if (reg(Register::this_value()).is_empty())
reg(Register::this_value()) = running_execution_context.this_value;
running_execution_context.executable = &executable;
for (size_t i = 0; i < executable.constants.size(); ++i) {
running_execution_context.registers_and_constants_and_locals[executable.number_of_registers + i] = executable.constants[i];
}
run_bytecode(entry_point.value_or(0));
dbgln_if(JS_BYTECODE_DEBUG, "Bytecode::Interpreter did run unit {:p}", &executable);
if constexpr (JS_BYTECODE_DEBUG) {
auto const& registers_and_constants_and_locals = running_execution_context.registers_and_constants_and_locals;
for (size_t i = 0; i < executable.number_of_registers; ++i) {
String value_string;
if (registers_and_constants_and_locals[i].is_empty())
value_string = "(empty)"_string;
else
value_string = registers_and_constants_and_locals[i].to_string_without_side_effects();
dbgln("[{:3}] {}", i, value_string);
}
}
auto return_value = js_undefined();
if (!reg(Register::return_value()).is_empty())
return_value = reg(Register::return_value());
else if (!reg(Register::saved_return_value()).is_empty())
return_value = reg(Register::saved_return_value());
auto exception = reg(Register::exception());
// At this point we may have already run any queued promise jobs via on_call_stack_emptied,
// in which case this is a no-op.
vm().run_queued_promise_jobs();
vm().finish_execution_generation();
if (!exception.is_empty())
return { throw_completion(exception), running_execution_context.registers_and_constants_and_locals[0] };
return { return_value, running_execution_context.registers_and_constants_and_locals[0] };
}
void Interpreter::enter_unwind_context()
{
running_execution_context().unwind_contexts.empend(
m_current_executable,
running_execution_context().lexical_environment);
running_execution_context().previously_scheduled_jumps.append(m_scheduled_jump);
m_scheduled_jump = {};
}
void Interpreter::leave_unwind_context()
{
running_execution_context().unwind_contexts.take_last();
}
void Interpreter::catch_exception(Operand dst)
{
set(dst, reg(Register::exception()));
reg(Register::exception()) = {};
auto& context = running_execution_context().unwind_contexts.last();
VERIFY(!context.handler_called);
VERIFY(context.executable == &current_executable());
context.handler_called = true;
running_execution_context().lexical_environment = context.lexical_environment;
}
void Interpreter::restore_scheduled_jump()
{
m_scheduled_jump = running_execution_context().previously_scheduled_jumps.take_last();
}
void Interpreter::leave_finally()
{
reg(Register::exception()) = {};
m_scheduled_jump = running_execution_context().previously_scheduled_jumps.take_last();
}
void Interpreter::enter_object_environment(Object& object)
{
auto& old_environment = running_execution_context().lexical_environment;
running_execution_context().saved_lexical_environments.append(old_environment);
running_execution_context().lexical_environment = new_object_environment(object, true, old_environment);
}
ThrowCompletionOr<NonnullGCPtr<Bytecode::Executable>> compile(VM& vm, ASTNode const& node, FunctionKind kind, DeprecatedFlyString const& name)
{
auto executable_result = Bytecode::Generator::generate_from_ast_node(vm, node, kind);
if (executable_result.is_error())
return vm.throw_completion<InternalError>(ErrorType::NotImplemented, TRY_OR_THROW_OOM(vm, executable_result.error().to_string()));
auto bytecode_executable = executable_result.release_value();
bytecode_executable->name = name;
if (Bytecode::g_dump_bytecode)
bytecode_executable->dump();
return bytecode_executable;
}
ThrowCompletionOr<NonnullGCPtr<Bytecode::Executable>> compile(VM& vm, ECMAScriptFunctionObject const& function)
{
auto const& name = function.name();
auto executable_result = Bytecode::Generator::generate_from_function(vm, function);
if (executable_result.is_error())
return vm.throw_completion<InternalError>(ErrorType::NotImplemented, TRY_OR_THROW_OOM(vm, executable_result.error().to_string()));
auto bytecode_executable = executable_result.release_value();
bytecode_executable->name = name;
if (Bytecode::g_dump_bytecode)
bytecode_executable->dump();
return bytecode_executable;
}
// NOTE: This function assumes that the index is valid within the TypedArray,
// and that the TypedArray is not detached.
template<typename T>
inline Value fast_typed_array_get_element(TypedArrayBase& typed_array, u32 index)
{
Checked<u32> offset_into_array_buffer = index;
offset_into_array_buffer *= sizeof(T);
offset_into_array_buffer += typed_array.byte_offset();
if (offset_into_array_buffer.has_overflow()) [[unlikely]] {
return js_undefined();
}
auto const& array_buffer = *typed_array.viewed_array_buffer();
auto const* slot = reinterpret_cast<T const*>(array_buffer.buffer().offset_pointer(offset_into_array_buffer.value()));
return Value { *slot };
}
// NOTE: This function assumes that the index is valid within the TypedArray,
// and that the TypedArray is not detached.
template<typename T>
inline void fast_typed_array_set_element(TypedArrayBase& typed_array, u32 index, T value)
{
Checked<u32> offset_into_array_buffer = index;
offset_into_array_buffer *= sizeof(T);
offset_into_array_buffer += typed_array.byte_offset();
if (offset_into_array_buffer.has_overflow()) [[unlikely]] {
return;
}
auto& array_buffer = *typed_array.viewed_array_buffer();
auto* slot = reinterpret_cast<T*>(array_buffer.buffer().offset_pointer(offset_into_array_buffer.value()));
*slot = value;
}
Completion throw_null_or_undefined_property_get(VM& vm, Value base_value, Optional<IdentifierTableIndex> base_identifier, IdentifierTableIndex property_identifier, Executable const& executable)
{
VERIFY(base_value.is_nullish());
if (base_identifier.has_value())
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithPropertyAndName, executable.get_identifier(property_identifier), base_value, executable.get_identifier(base_identifier.value()));
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithProperty, executable.get_identifier(property_identifier), base_value);
}
Completion throw_null_or_undefined_property_get(VM& vm, Value base_value, Optional<IdentifierTableIndex> base_identifier, Value property, Executable const& executable)
{
VERIFY(base_value.is_nullish());
if (base_identifier.has_value())
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithPropertyAndName, property, base_value, executable.get_identifier(base_identifier.value()));
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithProperty, property, base_value);
}
template<typename BaseType, typename PropertyType>
ALWAYS_INLINE Completion throw_null_or_undefined_property_access(VM& vm, Value base_value, BaseType const& base_identifier, PropertyType const& property_identifier)
{
VERIFY(base_value.is_nullish());
bool has_base_identifier = true;
bool has_property_identifier = true;
if constexpr (requires { base_identifier.has_value(); })
has_base_identifier = base_identifier.has_value();
if constexpr (requires { property_identifier.has_value(); })
has_property_identifier = property_identifier.has_value();
if (has_base_identifier && has_property_identifier)
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithPropertyAndName, property_identifier, base_value, base_identifier);
if (has_property_identifier)
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithProperty, property_identifier, base_value);
if (has_base_identifier)
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefinedWithName, base_identifier, base_value);
return vm.throw_completion<TypeError>(ErrorType::ToObjectNullOrUndefined);
}
ALWAYS_INLINE GCPtr<Object> base_object_for_get_impl(VM& vm, Value base_value)
{
if (base_value.is_object()) [[likely]]
return base_value.as_object();
// OPTIMIZATION: For various primitives we can avoid actually creating a new object for them.
auto& realm = *vm.current_realm();
if (base_value.is_string())
return realm.intrinsics().string_prototype();
if (base_value.is_number())
return realm.intrinsics().number_prototype();
if (base_value.is_boolean())
return realm.intrinsics().boolean_prototype();
if (base_value.is_bigint())
return realm.intrinsics().bigint_prototype();
if (base_value.is_symbol())
return realm.intrinsics().symbol_prototype();
return nullptr;
}
ALWAYS_INLINE ThrowCompletionOr<NonnullGCPtr<Object>> base_object_for_get(VM& vm, Value base_value, Optional<IdentifierTableIndex> base_identifier, IdentifierTableIndex property_identifier, Executable const& executable)
{
if (auto base_object = base_object_for_get_impl(vm, base_value))
return NonnullGCPtr { *base_object };
// NOTE: At this point this is guaranteed to throw (null or undefined).
return throw_null_or_undefined_property_get(vm, base_value, base_identifier, property_identifier, executable);
}
ALWAYS_INLINE ThrowCompletionOr<NonnullGCPtr<Object>> base_object_for_get(VM& vm, Value base_value, Optional<IdentifierTableIndex> base_identifier, Value property, Executable const& executable)
{
if (auto base_object = base_object_for_get_impl(vm, base_value))
return NonnullGCPtr { *base_object };
// NOTE: At this point this is guaranteed to throw (null or undefined).
return throw_null_or_undefined_property_get(vm, base_value, base_identifier, property, executable);
}
enum class GetByIdMode {
Normal,
Length,
};
template<GetByIdMode mode = GetByIdMode::Normal>
inline ThrowCompletionOr<Value> get_by_id(VM& vm, Optional<IdentifierTableIndex> base_identifier, IdentifierTableIndex property, Value base_value, Value this_value, PropertyLookupCache& cache, Executable const& executable)
{
if constexpr (mode == GetByIdMode::Length) {
if (base_value.is_string()) {
return Value(base_value.as_string().utf16_string().length_in_code_units());
}
}
auto base_obj = TRY(base_object_for_get(vm, base_value, base_identifier, property, executable));
if constexpr (mode == GetByIdMode::Length) {
// OPTIMIZATION: Fast path for the magical "length" property on Array objects.
if (base_obj->has_magical_length_property()) {
return Value { base_obj->indexed_properties().array_like_size() };
}
}
auto& shape = base_obj->shape();
if (cache.prototype) {
// OPTIMIZATION: If the prototype chain hasn't been mutated in a way that would invalidate the cache, we can use it.
bool can_use_cache = [&]() -> bool {
if (&shape != cache.shape)
return false;
if (!cache.prototype_chain_validity)
return false;
if (!cache.prototype_chain_validity->is_valid())
return false;
return true;
}();
if (can_use_cache)
return cache.prototype->get_direct(cache.property_offset.value());
} else if (&shape == cache.shape) {
// OPTIMIZATION: If the shape of the object hasn't changed, we can use the cached property offset.
return base_obj->get_direct(cache.property_offset.value());
}
CacheablePropertyMetadata cacheable_metadata;
auto value = TRY(base_obj->internal_get(executable.get_identifier(property), this_value, &cacheable_metadata));
if (cacheable_metadata.type == CacheablePropertyMetadata::Type::OwnProperty) {
cache = {};
cache.shape = shape;
cache.property_offset = cacheable_metadata.property_offset.value();
} else if (cacheable_metadata.type == CacheablePropertyMetadata::Type::InPrototypeChain) {
cache = {};
cache.shape = &base_obj->shape();
cache.property_offset = cacheable_metadata.property_offset.value();
cache.prototype = *cacheable_metadata.prototype;
cache.prototype_chain_validity = *cacheable_metadata.prototype->shape().prototype_chain_validity();
}
return value;
}
inline ThrowCompletionOr<Value> get_by_value(VM& vm, Optional<IdentifierTableIndex> base_identifier, Value base_value, Value property_key_value, Executable const& executable)
{
// OPTIMIZATION: Fast path for simple Int32 indexes in array-like objects.
if (base_value.is_object() && property_key_value.is_int32() && property_key_value.as_i32() >= 0) {
auto& object = base_value.as_object();
auto index = static_cast<u32>(property_key_value.as_i32());
auto const* object_storage = object.indexed_properties().storage();
// For "non-typed arrays":
if (!object.may_interfere_with_indexed_property_access()
&& object_storage) {
auto maybe_value = [&] {
if (object_storage->is_simple_storage())
return static_cast<SimpleIndexedPropertyStorage const*>(object_storage)->inline_get(index);
else
return static_cast<GenericIndexedPropertyStorage const*>(object_storage)->get(index);
}();
if (maybe_value.has_value()) {
auto value = maybe_value->value;
if (!value.is_accessor())
return value;
}
}
// For typed arrays:
if (object.is_typed_array()) {
auto& typed_array = static_cast<TypedArrayBase&>(object);
auto canonical_index = CanonicalIndex { CanonicalIndex::Type::Index, index };
if (is_valid_integer_index(typed_array, canonical_index)) {
switch (typed_array.kind()) {
case TypedArrayBase::Kind::Uint8Array:
return fast_typed_array_get_element<u8>(typed_array, index);
case TypedArrayBase::Kind::Uint16Array:
return fast_typed_array_get_element<u16>(typed_array, index);
case TypedArrayBase::Kind::Uint32Array:
return fast_typed_array_get_element<u32>(typed_array, index);
case TypedArrayBase::Kind::Int8Array:
return fast_typed_array_get_element<i8>(typed_array, index);
case TypedArrayBase::Kind::Int16Array:
return fast_typed_array_get_element<i16>(typed_array, index);
case TypedArrayBase::Kind::Int32Array:
return fast_typed_array_get_element<i32>(typed_array, index);
case TypedArrayBase::Kind::Uint8ClampedArray:
return fast_typed_array_get_element<u8>(typed_array, index);
default:
// FIXME: Support more TypedArray kinds.
break;
}
}
switch (typed_array.kind()) {
#define __JS_ENUMERATE(ClassName, snake_name, PrototypeName, ConstructorName, Type) \
case TypedArrayBase::Kind::ClassName: \
return typed_array_get_element<Type>(typed_array, canonical_index);
JS_ENUMERATE_TYPED_ARRAYS
#undef __JS_ENUMERATE
}
}
}
auto object = TRY(base_object_for_get(vm, base_value, base_identifier, property_key_value, executable));
auto property_key = TRY(property_key_value.to_property_key(vm));
if (base_value.is_string()) {
auto string_value = TRY(base_value.as_string().get(vm, property_key));
if (string_value.has_value())
return *string_value;
}
return TRY(object->internal_get(property_key, base_value));
}
inline ThrowCompletionOr<Value> get_global(Interpreter& interpreter, IdentifierTableIndex identifier_index, GlobalVariableCache& cache)
{
auto& vm = interpreter.vm();
auto& binding_object = interpreter.global_object();
auto& declarative_record = interpreter.global_declarative_environment();
auto& shape = binding_object.shape();
if (cache.environment_serial_number == declarative_record.environment_serial_number()) {
// OPTIMIZATION: For global var bindings, if the shape of the global object hasn't changed,
// we can use the cached property offset.
if (&shape == cache.shape) {
return binding_object.get_direct(cache.property_offset.value());
}
// OPTIMIZATION: For global lexical bindings, if the global declarative environment hasn't changed,
// we can use the cached environment binding index.
if (cache.environment_binding_index.has_value())
return declarative_record.get_binding_value_direct(vm, cache.environment_binding_index.value());
}
cache.environment_serial_number = declarative_record.environment_serial_number();
auto& identifier = interpreter.current_executable().get_identifier(identifier_index);
if (vm.running_execution_context().script_or_module.has<NonnullGCPtr<Module>>()) {
// NOTE: GetGlobal is used to access variables stored in the module environment and global environment.
// The module environment is checked first since it precedes the global environment in the environment chain.
auto& module_environment = *vm.running_execution_context().script_or_module.get<NonnullGCPtr<Module>>()->environment();
if (TRY(module_environment.has_binding(identifier))) {
// TODO: Cache offset of binding value
return TRY(module_environment.get_binding_value(vm, identifier, vm.in_strict_mode()));
}
}
Optional<size_t> offset;
if (TRY(declarative_record.has_binding(identifier, &offset))) {
cache.environment_binding_index = static_cast<u32>(offset.value());
return TRY(declarative_record.get_binding_value(vm, identifier, vm.in_strict_mode()));
}
if (TRY(binding_object.has_property(identifier))) {
CacheablePropertyMetadata cacheable_metadata;
auto value = TRY(binding_object.internal_get(identifier, js_undefined(), &cacheable_metadata));
if (cacheable_metadata.type == CacheablePropertyMetadata::Type::OwnProperty) {
cache.shape = shape;
cache.property_offset = cacheable_metadata.property_offset.value();
}
return value;
}
return vm.throw_completion<ReferenceError>(ErrorType::UnknownIdentifier, identifier);
}
inline ThrowCompletionOr<void> put_by_property_key(VM& vm, Value base, Value this_value, Value value, Optional<DeprecatedFlyString const&> const& base_identifier, PropertyKey name, Op::PropertyKind kind, PropertyLookupCache* cache = nullptr)
{
// Better error message than to_object would give
if (vm.in_strict_mode() && base.is_nullish())
return vm.throw_completion<TypeError>(ErrorType::ReferenceNullishSetProperty, name, base.to_string_without_side_effects());
// a. Let baseObj be ? ToObject(V.[[Base]]).
auto maybe_object = base.to_object(vm);
if (maybe_object.is_error())
return throw_null_or_undefined_property_access(vm, base, base_identifier, name);
auto object = maybe_object.release_value();
if (kind == Op::PropertyKind::Getter || kind == Op::PropertyKind::Setter) {
// The generator should only pass us functions for getters and setters.
VERIFY(value.is_function());
}
switch (kind) {
case Op::PropertyKind::Getter: {
auto& function = value.as_function();
if (function.name().is_empty() && is<ECMAScriptFunctionObject>(function))
static_cast<ECMAScriptFunctionObject*>(&function)->set_name(ByteString::formatted("get {}", name));
object->define_direct_accessor(name, &function, nullptr, Attribute::Configurable | Attribute::Enumerable);
break;
}
case Op::PropertyKind::Setter: {
auto& function = value.as_function();
if (function.name().is_empty() && is<ECMAScriptFunctionObject>(function))
static_cast<ECMAScriptFunctionObject*>(&function)->set_name(ByteString::formatted("set {}", name));
object->define_direct_accessor(name, nullptr, &function, Attribute::Configurable | Attribute::Enumerable);
break;
}
case Op::PropertyKind::KeyValue: {
if (cache && cache->shape == &object->shape()) {
object->put_direct(*cache->property_offset, value);
return {};
}
CacheablePropertyMetadata cacheable_metadata;
bool succeeded = TRY(object->internal_set(name, value, this_value, &cacheable_metadata));
if (succeeded && cache && cacheable_metadata.type == CacheablePropertyMetadata::Type::OwnProperty) {
cache->shape = object->shape();
cache->property_offset = cacheable_metadata.property_offset.value();
}
if (!succeeded && vm.in_strict_mode()) {
if (base.is_object())
return vm.throw_completion<TypeError>(ErrorType::ReferenceNullishSetProperty, name, base.to_string_without_side_effects());
return vm.throw_completion<TypeError>(ErrorType::ReferencePrimitiveSetProperty, name, base.typeof(), base.to_string_without_side_effects());
}
break;
}
case Op::PropertyKind::DirectKeyValue:
object->define_direct_property(name, value, Attribute::Enumerable | Attribute::Writable | Attribute::Configurable);
break;
case Op::PropertyKind::Spread:
TRY(object->copy_data_properties(vm, value, {}));
break;
case Op::PropertyKind::ProtoSetter:
if (value.is_object() || value.is_null())
MUST(object->internal_set_prototype_of(value.is_object() ? &value.as_object() : nullptr));
break;
}
return {};
}
inline ThrowCompletionOr<Value> perform_call(Interpreter& interpreter, Value this_value, Op::CallType call_type, Value callee, ReadonlySpan<Value> argument_values)
{
auto& vm = interpreter.vm();
auto& function = callee.as_function();
Value return_value;
if (call_type == Op::CallType::DirectEval) {
if (callee == interpreter.realm().intrinsics().eval_function())
return_value = TRY(perform_eval(vm, !argument_values.is_empty() ? argument_values[0].value_or(JS::js_undefined()) : js_undefined(), vm.in_strict_mode() ? CallerMode::Strict : CallerMode::NonStrict, EvalMode::Direct));
else
return_value = TRY(JS::call(vm, function, this_value, argument_values));
} else if (call_type == Op::CallType::Call)
return_value = TRY(JS::call(vm, function, this_value, argument_values));
else
return_value = TRY(construct(vm, function, argument_values));
return return_value;
}
static inline Completion throw_type_error_for_callee(Bytecode::Interpreter& interpreter, Value callee, StringView callee_type, Optional<StringTableIndex> const& expression_string)
{
auto& vm = interpreter.vm();
if (expression_string.has_value())
return vm.throw_completion<TypeError>(ErrorType::IsNotAEvaluatedFrom, callee.to_string_without_side_effects(), callee_type, interpreter.current_executable().get_string(expression_string->value()));
return vm.throw_completion<TypeError>(ErrorType::IsNotA, callee.to_string_without_side_effects(), callee_type);
}
inline ThrowCompletionOr<void> throw_if_needed_for_call(Interpreter& interpreter, Value callee, Op::CallType call_type, Optional<StringTableIndex> const& expression_string)
{
if ((call_type == Op::CallType::Call || call_type == Op::CallType::DirectEval)
&& !callee.is_function())
return throw_type_error_for_callee(interpreter, callee, "function"sv, expression_string);
if (call_type == Op::CallType::Construct && !callee.is_constructor())
return throw_type_error_for_callee(interpreter, callee, "constructor"sv, expression_string);
return {};
}
inline Value new_function(VM& vm, FunctionNode const& function_node, Optional<IdentifierTableIndex> const& lhs_name, Optional<Operand> const& home_object)
{
Value value;
if (!function_node.has_name()) {
DeprecatedFlyString name = {};
if (lhs_name.has_value())
name = vm.bytecode_interpreter().current_executable().get_identifier(lhs_name.value());
value = function_node.instantiate_ordinary_function_expression(vm, name);
} else {
value = ECMAScriptFunctionObject::create(*vm.current_realm(), function_node.name(), function_node.source_text(), function_node.body(), function_node.parameters(), function_node.function_length(), function_node.local_variables_names(), vm.lexical_environment(), vm.running_execution_context().private_environment, function_node.kind(), function_node.is_strict_mode(),
function_node.parsing_insights(), function_node.is_arrow_function());
}
if (home_object.has_value()) {
auto home_object_value = vm.bytecode_interpreter().get(home_object.value());
static_cast<ECMAScriptFunctionObject&>(value.as_function()).set_home_object(&home_object_value.as_object());
}
return value;
}
inline ThrowCompletionOr<void> put_by_value(VM& vm, Value base, Optional<DeprecatedFlyString const&> const& base_identifier, Value property_key_value, Value value, Op::PropertyKind kind)
{
// OPTIMIZATION: Fast path for simple Int32 indexes in array-like objects.
if ((kind == Op::PropertyKind::KeyValue || kind == Op::PropertyKind::DirectKeyValue)
&& base.is_object() && property_key_value.is_int32() && property_key_value.as_i32() >= 0) {
auto& object = base.as_object();
auto* storage = object.indexed_properties().storage();
auto index = static_cast<u32>(property_key_value.as_i32());
// For "non-typed arrays":
if (storage
&& storage->is_simple_storage()
&& !object.may_interfere_with_indexed_property_access()) {
auto maybe_value = storage->get(index);
if (maybe_value.has_value()) {
auto existing_value = maybe_value->value;
if (!existing_value.is_accessor()) {
storage->put(index, value);
return {};
}
}
}
// For typed arrays:
if (object.is_typed_array()) {
auto& typed_array = static_cast<TypedArrayBase&>(object);
auto canonical_index = CanonicalIndex { CanonicalIndex::Type::Index, index };
if (value.is_int32() && is_valid_integer_index(typed_array, canonical_index)) {
switch (typed_array.kind()) {
case TypedArrayBase::Kind::Uint8Array:
fast_typed_array_set_element<u8>(typed_array, index, static_cast<u8>(value.as_i32()));
return {};
case TypedArrayBase::Kind::Uint16Array:
fast_typed_array_set_element<u16>(typed_array, index, static_cast<u16>(value.as_i32()));
return {};
case TypedArrayBase::Kind::Uint32Array:
fast_typed_array_set_element<u32>(typed_array, index, static_cast<u32>(value.as_i32()));
return {};
case TypedArrayBase::Kind::Int8Array:
fast_typed_array_set_element<i8>(typed_array, index, static_cast<i8>(value.as_i32()));
return {};
case TypedArrayBase::Kind::Int16Array:
fast_typed_array_set_element<i16>(typed_array, index, static_cast<i16>(value.as_i32()));
return {};
case TypedArrayBase::Kind::Int32Array:
fast_typed_array_set_element<i32>(typed_array, index, value.as_i32());
return {};
case TypedArrayBase::Kind::Uint8ClampedArray:
fast_typed_array_set_element<u8>(typed_array, index, clamp(value.as_i32(), 0, 255));
return {};
default:
// FIXME: Support more TypedArray kinds.
break;
}
}
if (typed_array.kind() == TypedArrayBase::Kind::Uint32Array && value.is_integral_number()) {
auto integer = value.as_double();
if (AK::is_within_range<u32>(integer) && is_valid_integer_index(typed_array, canonical_index)) {
fast_typed_array_set_element<u32>(typed_array, index, static_cast<u32>(integer));
return {};
}
}
switch (typed_array.kind()) {
#define __JS_ENUMERATE(ClassName, snake_name, PrototypeName, ConstructorName, Type) \
case TypedArrayBase::Kind::ClassName: \
return typed_array_set_element<Type>(typed_array, canonical_index, value);
JS_ENUMERATE_TYPED_ARRAYS
#undef __JS_ENUMERATE
}
return {};
}
}
auto property_key = kind != Op::PropertyKind::Spread ? TRY(property_key_value.to_property_key(vm)) : PropertyKey {};
TRY(put_by_property_key(vm, base, base, value, base_identifier, property_key, kind));
return {};
}
struct CalleeAndThis {
Value callee;
Value this_value;
};
inline ThrowCompletionOr<CalleeAndThis> get_callee_and_this_from_environment(Bytecode::Interpreter& interpreter, DeprecatedFlyString const& name, EnvironmentCoordinate& cache)
{
auto& vm = interpreter.vm();
Value callee = js_undefined();
Value this_value = js_undefined();
if (cache.is_valid()) {
auto const* environment = interpreter.running_execution_context().lexical_environment.ptr();
for (size_t i = 0; i < cache.hops; ++i)
environment = environment->outer_environment();
if (!environment->is_permanently_screwed_by_eval()) {
callee = TRY(static_cast<DeclarativeEnvironment const&>(*environment).get_binding_value_direct(vm, cache.index));
this_value = js_undefined();
if (auto base_object = environment->with_base_object())
this_value = base_object;
return CalleeAndThis {
.callee = callee,
.this_value = this_value,
};
}
cache = {};
}
auto reference = TRY(vm.resolve_binding(name));
if (reference.environment_coordinate().has_value())
cache = reference.environment_coordinate().value();
callee = TRY(reference.get_value(vm));
if (reference.is_property_reference()) {
this_value = reference.get_this_value();
} else {
if (reference.is_environment_reference()) {
if (auto base_object = reference.base_environment().with_base_object(); base_object != nullptr)
this_value = base_object;
}
}
return CalleeAndThis {
.callee = callee,
.this_value = this_value,
};
}
// 13.2.7.3 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-regular-expression-literals-runtime-semantics-evaluation
inline Value new_regexp(VM& vm, ParsedRegex const& parsed_regex, ByteString const& pattern, ByteString const& flags)
{
// 1. Let pattern be CodePointsToString(BodyText of RegularExpressionLiteral).
// 2. Let flags be CodePointsToString(FlagText of RegularExpressionLiteral).
// 3. Return ! RegExpCreate(pattern, flags).
auto& realm = *vm.current_realm();
Regex<ECMA262> regex(parsed_regex.regex, parsed_regex.pattern, parsed_regex.flags);
// NOTE: We bypass RegExpCreate and subsequently RegExpAlloc as an optimization to use the already parsed values.
auto regexp_object = RegExpObject::create(realm, move(regex), pattern, flags);
// RegExpAlloc has these two steps from the 'Legacy RegExp features' proposal.
regexp_object->set_realm(realm);
// We don't need to check 'If SameValue(newTarget, thisRealm.[[Intrinsics]].[[%RegExp%]]) is true'
// here as we know RegExpCreate calls RegExpAlloc with %RegExp% for newTarget.
regexp_object->set_legacy_features_enabled(true);
return regexp_object;
}
// 13.3.8.1 https://tc39.es/ecma262/#sec-runtime-semantics-argumentlistevaluation
inline MarkedVector<Value> argument_list_evaluation(VM& vm, Value arguments)
{
// Note: Any spreading and actual evaluation is handled in preceding opcodes
// Note: The spec uses the concept of a list, while we create a temporary array
// in the preceding opcodes, so we have to convert in a manner that is not
// visible to the user
MarkedVector<Value> argument_values { vm.heap() };
auto& argument_array = arguments.as_array();
auto array_length = argument_array.indexed_properties().array_like_size();
argument_values.ensure_capacity(array_length);
for (size_t i = 0; i < array_length; ++i) {
if (auto maybe_value = argument_array.indexed_properties().get(i); maybe_value.has_value())
argument_values.append(maybe_value.release_value().value);
else
argument_values.append(js_undefined());
}
return argument_values;
}
inline ThrowCompletionOr<void> create_variable(VM& vm, DeprecatedFlyString const& name, Op::EnvironmentMode mode, bool is_global, bool is_immutable, bool is_strict)
{
if (mode == Op::EnvironmentMode::Lexical) {
VERIFY(!is_global);
// Note: This is papering over an issue where "FunctionDeclarationInstantiation" creates these bindings for us.
// Instead of crashing in there, we'll just raise an exception here.
if (TRY(vm.lexical_environment()->has_binding(name)))
return vm.throw_completion<InternalError>(TRY_OR_THROW_OOM(vm, String::formatted("Lexical environment already has binding '{}'", name)));
if (is_immutable)
return vm.lexical_environment()->create_immutable_binding(vm, name, is_strict);
return vm.lexical_environment()->create_mutable_binding(vm, name, is_strict);
}
if (!is_global) {
if (is_immutable)
return vm.variable_environment()->create_immutable_binding(vm, name, is_strict);
return vm.variable_environment()->create_mutable_binding(vm, name, is_strict);
}
// NOTE: CreateVariable with m_is_global set to true is expected to only be used in GlobalDeclarationInstantiation currently, which only uses "false" for "can_be_deleted".
// The only area that sets "can_be_deleted" to true is EvalDeclarationInstantiation, which is currently fully implemented in C++ and not in Bytecode.
return verify_cast<GlobalEnvironment>(vm.variable_environment())->create_global_var_binding(name, false);
}
inline ThrowCompletionOr<ECMAScriptFunctionObject*> new_class(VM& vm, Value super_class, ClassExpression const& class_expression, Optional<IdentifierTableIndex> const& lhs_name, ReadonlySpan<Value> element_keys)
{
auto& interpreter = vm.bytecode_interpreter();
auto name = class_expression.name();
// NOTE: NewClass expects classEnv to be active lexical environment
auto* class_environment = vm.lexical_environment();
vm.running_execution_context().lexical_environment = vm.running_execution_context().saved_lexical_environments.take_last();
Optional<DeprecatedFlyString> binding_name;
DeprecatedFlyString class_name;
if (!class_expression.has_name() && lhs_name.has_value()) {
class_name = interpreter.current_executable().get_identifier(lhs_name.value());
} else {
binding_name = name;
class_name = name.is_null() ? ""sv : name;
}
return TRY(class_expression.create_class_constructor(vm, class_environment, vm.lexical_environment(), super_class, element_keys, binding_name, class_name));
}
// 13.3.7.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
inline ThrowCompletionOr<NonnullGCPtr<Object>> super_call_with_argument_array(VM& vm, Value argument_array, bool is_synthetic)
{
// 1. Let newTarget be GetNewTarget().
auto new_target = vm.get_new_target();
// 2. Assert: Type(newTarget) is Object.
VERIFY(new_target.is_object());
// 3. Let func be GetSuperConstructor().
auto* func = get_super_constructor(vm);
// 4. Let argList be ? ArgumentListEvaluation of Arguments.
MarkedVector<Value> arg_list { vm.heap() };
if (is_synthetic) {
VERIFY(argument_array.is_object() && is<Array>(argument_array.as_object()));
auto const& array_value = static_cast<Array const&>(argument_array.as_object());
auto length = MUST(length_of_array_like(vm, array_value));
for (size_t i = 0; i < length; ++i)
arg_list.append(array_value.get_without_side_effects(PropertyKey { i }));
} else {
arg_list = argument_list_evaluation(vm, argument_array);
}
// 5. If IsConstructor(func) is false, throw a TypeError exception.
if (!Value(func).is_constructor())
return vm.throw_completion<TypeError>(ErrorType::NotAConstructor, "Super constructor");
// 6. Let result be ? Construct(func, argList, newTarget).
auto result = TRY(construct(vm, static_cast<FunctionObject&>(*func), arg_list.span(), &new_target.as_function()));
// 7. Let thisER be GetThisEnvironment().
auto& this_environment = verify_cast<FunctionEnvironment>(*get_this_environment(vm));
// 8. Perform ? thisER.BindThisValue(result).
TRY(this_environment.bind_this_value(vm, result));
// 9. Let F be thisER.[[FunctionObject]].
auto& f = this_environment.function_object();
// 10. Assert: F is an ECMAScript function object.
// NOTE: This is implied by the strong C++ type.
// 11. Perform ? InitializeInstanceElements(result, F).
TRY(result->initialize_instance_elements(f));
// 12. Return result.
return result;
}
inline ThrowCompletionOr<NonnullGCPtr<Array>> iterator_to_array(VM& vm, Value iterator)
{
auto& iterator_record = verify_cast<IteratorRecord>(iterator.as_object());
auto array = MUST(Array::create(*vm.current_realm(), 0));
size_t index = 0;
while (true) {
auto value = TRY(iterator_step_value(vm, iterator_record));
if (!value.has_value())
return array;
MUST(array->create_data_property_or_throw(index, value.release_value()));
index++;
}
}
inline ThrowCompletionOr<void> append(VM& vm, Value lhs, Value rhs, bool is_spread)
{
// Note: This OpCode is used to construct array literals and argument arrays for calls,
// containing at least one spread element,
// Iterating over such a spread element to unpack it has to be visible by
// the user courtesy of
// (1) https://tc39.es/ecma262/#sec-runtime-semantics-arrayaccumulation
// SpreadElement : ... AssignmentExpression
// 1. Let spreadRef be ? Evaluation of AssignmentExpression.
// 2. Let spreadObj be ? GetValue(spreadRef).
// 3. Let iteratorRecord be ? GetIterator(spreadObj).
// 4. Repeat,
// a. Let next be ? IteratorStep(iteratorRecord).
// b. If next is false, return nextIndex.
// c. Let nextValue be ? IteratorValue(next).
// d. Perform ! CreateDataPropertyOrThrow(array, ! ToString(𝔽(nextIndex)), nextValue).
// e. Set nextIndex to nextIndex + 1.
// (2) https://tc39.es/ecma262/#sec-runtime-semantics-argumentlistevaluation
// ArgumentList : ... AssignmentExpression
// 1. Let list be a new empty List.
// 2. Let spreadRef be ? Evaluation of AssignmentExpression.
// 3. Let spreadObj be ? GetValue(spreadRef).
// 4. Let iteratorRecord be ? GetIterator(spreadObj).
// 5. Repeat,
// a. Let next be ? IteratorStep(iteratorRecord).
// b. If next is false, return list.
// c. Let nextArg be ? IteratorValue(next).
// d. Append nextArg to list.
// ArgumentList : ArgumentList , ... AssignmentExpression
// 1. Let precedingArgs be ? ArgumentListEvaluation of ArgumentList.
// 2. Let spreadRef be ? Evaluation of AssignmentExpression.
// 3. Let iteratorRecord be ? GetIterator(? GetValue(spreadRef)).
// 4. Repeat,
// a. Let next be ? IteratorStep(iteratorRecord).
// b. If next is false, return precedingArgs.
// c. Let nextArg be ? IteratorValue(next).
// d. Append nextArg to precedingArgs.
// Note: We know from codegen, that lhs is a plain array with only indexed properties
auto& lhs_array = lhs.as_array();
auto lhs_size = lhs_array.indexed_properties().array_like_size();
if (is_spread) {
// ...rhs
size_t i = lhs_size;
TRY(get_iterator_values(vm, rhs, [&i, &lhs_array](Value iterator_value) -> Optional<Completion> {
lhs_array.indexed_properties().put(i, iterator_value, default_attributes);
++i;
return {};
}));
} else {
lhs_array.indexed_properties().put(lhs_size, rhs, default_attributes);
}
return {};
}
inline ThrowCompletionOr<Value> delete_by_id(Bytecode::Interpreter& interpreter, Value base, IdentifierTableIndex property)
{
auto& vm = interpreter.vm();
auto const& identifier = interpreter.current_executable().get_identifier(property);
bool strict = vm.in_strict_mode();
auto reference = Reference { base, identifier, {}, strict };
return TRY(reference.delete_(vm));
}
inline ThrowCompletionOr<Value> delete_by_value(Bytecode::Interpreter& interpreter, Value base, Value property_key_value)
{
auto& vm = interpreter.vm();
auto property_key = TRY(property_key_value.to_property_key(vm));
bool strict = vm.in_strict_mode();
auto reference = Reference { base, property_key, {}, strict };
return Value(TRY(reference.delete_(vm)));
}
inline ThrowCompletionOr<Value> delete_by_value_with_this(Bytecode::Interpreter& interpreter, Value base, Value property_key_value, Value this_value)
{
auto& vm = interpreter.vm();
auto property_key = TRY(property_key_value.to_property_key(vm));
bool strict = vm.in_strict_mode();
auto reference = Reference { base, property_key, this_value, strict };
return Value(TRY(reference.delete_(vm)));
}
// 14.7.5.9 EnumerateObjectProperties ( O ), https://tc39.es/ecma262/#sec-enumerate-object-properties
inline ThrowCompletionOr<Object*> get_object_property_iterator(VM& vm, Value value)
{
// While the spec does provide an algorithm, it allows us to implement it ourselves so long as we meet the following invariants:
// 1- Returned property keys do not include keys that are Symbols
// 2- Properties of the target object may be deleted during enumeration. A property that is deleted before it is processed by the iterator's next method is ignored
// 3- If new properties are added to the target object during enumeration, the newly added properties are not guaranteed to be processed in the active enumeration
// 4- A property name will be returned by the iterator's next method at most once in any enumeration.
// 5- Enumerating the properties of the target object includes enumerating properties of its prototype, and the prototype of the prototype, and so on, recursively;
// but a property of a prototype is not processed if it has the same name as a property that has already been processed by the iterator's next method.
// 6- The values of [[Enumerable]] attributes are not considered when determining if a property of a prototype object has already been processed.
// 7- The enumerable property names of prototype objects must be obtained by invoking EnumerateObjectProperties passing the prototype object as the argument.
// 8- EnumerateObjectProperties must obtain the own property keys of the target object by calling its [[OwnPropertyKeys]] internal method.
// 9- Property attributes of the target object must be obtained by calling its [[GetOwnProperty]] internal method
// Invariant 3 effectively allows the implementation to ignore newly added keys, and we do so (similar to other implementations).
auto object = TRY(value.to_object(vm));
// Note: While the spec doesn't explicitly require these to be ordered, it says that the values should be retrieved via OwnPropertyKeys,
// so we just keep the order consistent anyway.
OrderedHashTable<PropertyKey> properties;
OrderedHashTable<PropertyKey> non_enumerable_properties;
HashTable<NonnullGCPtr<Object>> seen_objects;
// Collect all keys immediately (invariant no. 5)
for (auto object_to_check = GCPtr { object.ptr() }; object_to_check && !seen_objects.contains(*object_to_check); object_to_check = TRY(object_to_check->internal_get_prototype_of())) {
seen_objects.set(*object_to_check);
for (auto& key : TRY(object_to_check->internal_own_property_keys())) {
if (key.is_symbol())
continue;
auto property_key = TRY(PropertyKey::from_value(vm, key));
// If there is a non-enumerable property higher up the prototype chain with the same key,
// we mustn't include this property even if it's enumerable (invariant no. 5 and 6)
if (non_enumerable_properties.contains(property_key))
continue;
if (properties.contains(property_key))
continue;
auto descriptor = TRY(object_to_check->internal_get_own_property(property_key));
if (!*descriptor->enumerable)
non_enumerable_properties.set(move(property_key));
else
properties.set(move(property_key));
}
}
auto& realm = *vm.current_realm();
auto callback = NativeFunction::create(
*vm.current_realm(), [items = move(properties)](VM& vm) mutable -> ThrowCompletionOr<Value> {
auto& realm = *vm.current_realm();
auto iterated_object_value = vm.this_value();
if (!iterated_object_value.is_object())
return vm.throw_completion<InternalError>("Invalid state for GetObjectPropertyIterator.next"sv);
auto& iterated_object = iterated_object_value.as_object();
auto result_object = Object::create(realm, nullptr);
while (true) {
if (items.is_empty()) {
result_object->define_direct_property(vm.names.done, JS::Value(true), default_attributes);
return result_object;
}
auto key = items.take_first();
// If the property is deleted, don't include it (invariant no. 2)
if (!TRY(iterated_object.has_property(key)))
continue;
result_object->define_direct_property(vm.names.done, JS::Value(false), default_attributes);
if (key.is_number())
result_object->define_direct_property(vm.names.value, PrimitiveString::create(vm, TRY_OR_THROW_OOM(vm, String::number(key.as_number()))), default_attributes);
else if (key.is_string())
result_object->define_direct_property(vm.names.value, PrimitiveString::create(vm, key.as_string()), default_attributes);
else
VERIFY_NOT_REACHED(); // We should not have non-string/number keys.
return result_object;
}
},
1, vm.names.next);
return vm.heap().allocate<IteratorRecord>(realm, realm, object, callback, false).ptr();
}
ByteString Instruction::to_byte_string(Bytecode::Executable const& executable) const
{
#define __BYTECODE_OP(op) \
case Instruction::Type::op: \
return static_cast<Bytecode::Op::op const&>(*this).to_byte_string_impl(executable);
switch (type()) {
ENUMERATE_BYTECODE_OPS(__BYTECODE_OP)
default:
VERIFY_NOT_REACHED();
}
#undef __BYTECODE_OP
}
}
namespace JS::Bytecode::Op {
static void dump_object(Object& o, HashTable<Object const*>& seen, int indent = 0)
{
if (seen.contains(&o))
return;
seen.set(&o);
for (auto& it : o.shape().property_table()) {
auto value = o.get_direct(it.value.offset);
dbgln("{} {} -> {}", String::repeated(' ', indent).release_value(), it.key.to_display_string(), value);
if (value.is_object()) {
dump_object(value.as_object(), seen, indent + 2);
}
}
}
void Dump::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto value = interpreter.get(m_value);
dbgln("(DUMP) {}: {}", m_text, value);
if (value.is_object()) {
HashTable<Object const*> seen;
dump_object(value.as_object(), seen);
}
}
#define JS_DEFINE_EXECUTE_FOR_COMMON_BINARY_OP(OpTitleCase, op_snake_case) \
ThrowCompletionOr<void> OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
auto lhs = interpreter.get(m_lhs); \
auto rhs = interpreter.get(m_rhs); \
interpreter.set(m_dst, TRY(op_snake_case(vm, lhs, rhs))); \
return {}; \
}
#define JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP(OpTitleCase, op_snake_case) \
ByteString OpTitleCase::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted(#OpTitleCase " {}, {}, {}", \
format_operand("dst"sv, m_dst, executable), \
format_operand("lhs"sv, m_lhs, executable), \
format_operand("rhs"sv, m_rhs, executable)); \
}
JS_ENUMERATE_COMMON_BINARY_OPS_WITHOUT_FAST_PATH(JS_DEFINE_EXECUTE_FOR_COMMON_BINARY_OP)
JS_ENUMERATE_COMMON_BINARY_OPS_WITHOUT_FAST_PATH(JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP)
JS_ENUMERATE_COMMON_BINARY_OPS_WITH_FAST_PATH(JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP)
ThrowCompletionOr<void> Add::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::addition_would_overflow(lhs.as_i32(), rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() + rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() + rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(add(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> Mul::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::multiplication_would_overflow(lhs.as_i32(), rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() * rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() * rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(mul(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> Sub::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::subtraction_would_overflow(lhs.as_i32(), rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() - rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() - rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(sub(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseXor::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() ^ rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_xor(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseAnd::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() & rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_and(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseOr::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() | rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_or(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> UnsignedRightShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(static_cast<u32>(lhs.as_i32()) >> shift_count));
return {};
}
interpreter.set(m_dst, TRY(unsigned_right_shift(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> RightShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(lhs.as_i32() >> shift_count));
return {};
}
interpreter.set(m_dst, TRY(right_shift(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> LeftShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(lhs.as_i32() << shift_count));
return {};
}
interpreter.set(m_dst, TRY(left_shift(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> LessThan::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() < rhs.as_i32()));
return {};
}
interpreter.set(m_dst, Value(lhs.as_double() < rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(less_than(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> LessThanEquals::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() <= rhs.as_i32()));
return {};
}
interpreter.set(m_dst, Value(lhs.as_double() <= rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(less_than_equals(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> GreaterThan::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() > rhs.as_i32()));
return {};
}
interpreter.set(m_dst, Value(lhs.as_double() > rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(greater_than(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> GreaterThanEquals::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() >= rhs.as_i32()));
return {};
}
interpreter.set(m_dst, Value(lhs.as_double() >= rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(greater_than_equals(vm, lhs, rhs)));
return {};
}
static ThrowCompletionOr<Value> not_(VM&, Value value)
{
return Value(!value.to_boolean());
}
static ThrowCompletionOr<Value> typeof_(VM& vm, Value value)
{
return PrimitiveString::create(vm, value.typeof());
}
#define JS_DEFINE_COMMON_UNARY_OP(OpTitleCase, op_snake_case) \
ThrowCompletionOr<void> OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
interpreter.set(dst(), TRY(op_snake_case(vm, interpreter.get(src())))); \
return {}; \
} \
ByteString OpTitleCase::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted(#OpTitleCase " {}, {}", \
format_operand("dst"sv, dst(), executable), \
format_operand("src"sv, src(), executable)); \
}
JS_ENUMERATE_COMMON_UNARY_OPS(JS_DEFINE_COMMON_UNARY_OP)
void NewArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto array = MUST(Array::create(interpreter.realm(), 0));
for (size_t i = 0; i < m_element_count; i++) {
array->indexed_properties().put(i, interpreter.get(m_elements[i]), default_attributes);
}
interpreter.set(dst(), array);
}
void NewPrimitiveArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto array = MUST(Array::create(interpreter.realm(), 0));
for (size_t i = 0; i < m_element_count; i++)
array->indexed_properties().put(i, m_elements[i], default_attributes);
interpreter.set(dst(), array);
}
void AddPrivateName::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto const& name = interpreter.current_executable().get_identifier(m_name);
interpreter.vm().running_execution_context().private_environment->add_private_name(name);
}
ThrowCompletionOr<void> ArrayAppend::execute_impl(Bytecode::Interpreter& interpreter) const
{
return append(interpreter.vm(), interpreter.get(dst()), interpreter.get(src()), m_is_spread);
}
ThrowCompletionOr<void> ImportCall::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto specifier = interpreter.get(m_specifier);
auto options_value = interpreter.get(m_options);
interpreter.set(dst(), TRY(perform_import_call(vm, specifier, options_value)));
return {};
}
ThrowCompletionOr<void> IteratorToArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), TRY(iterator_to_array(interpreter.vm(), interpreter.get(iterator()))));
return {};
}
void NewObject::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& realm = *vm.current_realm();
interpreter.set(dst(), Object::create(realm, realm.intrinsics().object_prototype()));
}
void NewRegExp::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(),
new_regexp(
interpreter.vm(),
interpreter.current_executable().regex_table->get(m_regex_index),
interpreter.current_executable().get_string(m_source_index),
interpreter.current_executable().get_string(m_flags_index)));
}
#define JS_DEFINE_NEW_BUILTIN_ERROR_OP(ErrorName) \
void New##ErrorName::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
auto& realm = *vm.current_realm(); \
interpreter.set(dst(), ErrorName::create(realm, interpreter.current_executable().get_string(m_error_string))); \
} \
ByteString New##ErrorName::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted("New" #ErrorName " {}, {}", \
format_operand("dst"sv, m_dst, executable), \
executable.string_table->get(m_error_string)); \
}
JS_ENUMERATE_NEW_BUILTIN_ERROR_OPS(JS_DEFINE_NEW_BUILTIN_ERROR_OP)
ThrowCompletionOr<void> CopyObjectExcludingProperties::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& realm = *vm.current_realm();
auto from_object = interpreter.get(m_from_object);
auto to_object = Object::create(realm, realm.intrinsics().object_prototype());
HashTable<PropertyKey> excluded_names;
for (size_t i = 0; i < m_excluded_names_count; ++i) {
excluded_names.set(TRY(interpreter.get(m_excluded_names[i]).to_property_key(vm)));
}
TRY(to_object->copy_data_properties(vm, from_object, excluded_names));
interpreter.set(dst(), to_object);
return {};
}
ThrowCompletionOr<void> ConcatString::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto string = TRY(interpreter.get(src()).to_primitive_string(vm));
interpreter.set(dst(), PrimitiveString::create(vm, interpreter.get(dst()).as_string(), string));
return {};
}
ThrowCompletionOr<void> GetBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& executable = interpreter.current_executable();
if (m_cache.is_valid()) {
auto const* environment = interpreter.running_execution_context().lexical_environment.ptr();
for (size_t i = 0; i < m_cache.hops; ++i)
environment = environment->outer_environment();
if (!environment->is_permanently_screwed_by_eval()) {
interpreter.set(dst(), TRY(static_cast<DeclarativeEnvironment const&>(*environment).get_binding_value_direct(vm, m_cache.index)));
return {};
}
m_cache = {};
}
auto reference = TRY(vm.resolve_binding(executable.get_identifier(m_identifier)));
if (reference.environment_coordinate().has_value())
m_cache = reference.environment_coordinate().value();
interpreter.set(dst(), TRY(reference.get_value(vm)));
return {};
}
ThrowCompletionOr<void> GetCalleeAndThisFromEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto callee_and_this = TRY(get_callee_and_this_from_environment(
interpreter,
interpreter.current_executable().get_identifier(m_identifier),
m_cache));
interpreter.set(m_callee, callee_and_this.callee);
interpreter.set(m_this_value, callee_and_this.this_value);
return {};
}
ThrowCompletionOr<void> GetGlobal::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), TRY(get_global(interpreter, m_identifier, interpreter.current_executable().global_variable_caches[m_cache_index])));
return {};
}
ThrowCompletionOr<void> DeleteVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const& string = interpreter.current_executable().get_identifier(m_identifier);
auto reference = TRY(vm.resolve_binding(string));
interpreter.set(dst(), Value(TRY(reference.delete_(vm))));
return {};
}
void CreateLexicalEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto make_and_swap_envs = [&](auto& old_environment) {
auto declarative_environment = new_declarative_environment(*old_environment).ptr();
declarative_environment->ensure_capacity(m_capacity);
GCPtr<Environment> environment = declarative_environment;
swap(old_environment, environment);
return environment;
};
auto& running_execution_context = interpreter.running_execution_context();
running_execution_context.saved_lexical_environments.append(make_and_swap_envs(running_execution_context.lexical_environment));
}
void CreatePrivateEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& running_execution_context = interpreter.vm().running_execution_context();
auto outer_private_environment = running_execution_context.private_environment;
running_execution_context.private_environment = new_private_environment(interpreter.vm(), outer_private_environment);
}
void CreateVariableEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& running_execution_context = interpreter.running_execution_context();
auto var_environment = new_declarative_environment(*running_execution_context.lexical_environment);
var_environment->ensure_capacity(m_capacity);
running_execution_context.variable_environment = var_environment;
running_execution_context.lexical_environment = var_environment;
}
ThrowCompletionOr<void> EnterObjectEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto object = TRY(interpreter.get(m_object).to_object(interpreter.vm()));
interpreter.enter_object_environment(*object);
return {};
}
void Catch::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.catch_exception(dst());
}
void LeaveFinally::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.leave_finally();
}
void RestoreScheduledJump::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.restore_scheduled_jump();
}
ThrowCompletionOr<void> CreateVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto const& name = interpreter.current_executable().get_identifier(m_identifier);
return create_variable(interpreter.vm(), name, m_mode, m_is_global, m_is_immutable, m_is_strict);
}
ThrowCompletionOr<void> CreateRestParams::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto const& arguments = interpreter.running_execution_context().arguments;
auto arguments_count = interpreter.running_execution_context().passed_argument_count;
auto array = MUST(Array::create(interpreter.realm(), 0));
for (size_t rest_index = m_rest_index; rest_index < arguments_count; ++rest_index)
array->indexed_properties().append(arguments[rest_index]);
interpreter.set(m_dst, array);
return {};
}
ThrowCompletionOr<void> CreateArguments::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto const& function = interpreter.running_execution_context().function;
auto const& arguments = interpreter.running_execution_context().arguments;
auto const& environment = interpreter.running_execution_context().lexical_environment;
auto passed_arguments = ReadonlySpan<Value> { arguments.data(), interpreter.running_execution_context().passed_argument_count };
Object* arguments_object;
if (m_kind == Kind::Mapped) {
arguments_object = create_mapped_arguments_object(interpreter.vm(), *function, function->formal_parameters(), passed_arguments, *environment);
} else {
arguments_object = create_unmapped_arguments_object(interpreter.vm(), passed_arguments);
}
if (m_dst.has_value()) {
interpreter.set(*m_dst, arguments_object);
return {};
}
if (m_is_immutable) {
MUST(environment->create_immutable_binding(interpreter.vm(), interpreter.vm().names.arguments.as_string(), false));
} else {
MUST(environment->create_mutable_binding(interpreter.vm(), interpreter.vm().names.arguments.as_string(), false));
}
MUST(environment->initialize_binding(interpreter.vm(), interpreter.vm().names.arguments.as_string(), arguments_object, Environment::InitializeBindingHint::Normal));
return {};
}
template<EnvironmentMode environment_mode, BindingInitializationMode initialization_mode>
static ThrowCompletionOr<void> initialize_or_set_binding(Interpreter& interpreter, IdentifierTableIndex identifier_index, Value value, EnvironmentCoordinate& cache)
{
auto& vm = interpreter.vm();
auto* environment = environment_mode == EnvironmentMode::Lexical
? interpreter.running_execution_context().lexical_environment.ptr()
: interpreter.running_execution_context().variable_environment.ptr();
if (cache.is_valid()) {
for (size_t i = 0; i < cache.hops; ++i)
environment = environment->outer_environment();
if (!environment->is_permanently_screwed_by_eval()) {
if constexpr (initialization_mode == BindingInitializationMode::Initialize) {
TRY(static_cast<DeclarativeEnvironment&>(*environment).initialize_binding_direct(vm, cache.index, value, Environment::InitializeBindingHint::Normal));
} else {
TRY(static_cast<DeclarativeEnvironment&>(*environment).set_mutable_binding_direct(vm, cache.index, value, vm.in_strict_mode()));
}
return {};
}
cache = {};
}
auto reference = TRY(vm.resolve_binding(interpreter.current_executable().get_identifier(identifier_index), environment));
if (reference.environment_coordinate().has_value())
cache = reference.environment_coordinate().value();
if constexpr (initialization_mode == BindingInitializationMode::Initialize) {
TRY(reference.initialize_referenced_binding(vm, value));
} else if (initialization_mode == BindingInitializationMode::Set) {
TRY(reference.put_value(vm, value));
}
return {};
}
ThrowCompletionOr<void> InitializeLexicalBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
return initialize_or_set_binding<EnvironmentMode::Lexical, BindingInitializationMode::Initialize>(interpreter, m_identifier, interpreter.get(m_src), m_cache);
}
ThrowCompletionOr<void> InitializeVariableBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
return initialize_or_set_binding<EnvironmentMode::Var, BindingInitializationMode::Initialize>(interpreter, m_identifier, interpreter.get(m_src), m_cache);
}
ThrowCompletionOr<void> SetLexicalBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
return initialize_or_set_binding<EnvironmentMode::Lexical, BindingInitializationMode::Set>(interpreter, m_identifier, interpreter.get(m_src), m_cache);
}
ThrowCompletionOr<void> SetVariableBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
return initialize_or_set_binding<EnvironmentMode::Var, BindingInitializationMode::Set>(interpreter, m_identifier, interpreter.get(m_src), m_cache);
}
ThrowCompletionOr<void> GetById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(base());
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
interpreter.set(dst(), TRY(get_by_id(interpreter.vm(), m_base_identifier, m_property, base_value, base_value, cache, interpreter.current_executable())));
return {};
}
ThrowCompletionOr<void> GetByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(m_base);
auto this_value = interpreter.get(m_this_value);
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
interpreter.set(dst(), TRY(get_by_id(interpreter.vm(), {}, m_property, base_value, this_value, cache, interpreter.current_executable())));
return {};
}
ThrowCompletionOr<void> GetLength::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(base());
auto& executable = interpreter.current_executable();
auto& cache = executable.property_lookup_caches[m_cache_index];
interpreter.set(dst(), TRY(get_by_id<GetByIdMode::Length>(interpreter.vm(), m_base_identifier, *executable.length_identifier, base_value, base_value, cache, executable)));
return {};
}
ThrowCompletionOr<void> GetLengthWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(m_base);
auto this_value = interpreter.get(m_this_value);
auto& executable = interpreter.current_executable();
auto& cache = executable.property_lookup_caches[m_cache_index];
interpreter.set(dst(), TRY(get_by_id<GetByIdMode::Length>(interpreter.vm(), {}, *executable.length_identifier, base_value, this_value, cache, executable)));
return {};
}
ThrowCompletionOr<void> GetPrivateById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const& name = interpreter.current_executable().get_identifier(m_property);
auto base_value = interpreter.get(m_base);
auto private_reference = make_private_reference(vm, base_value, name);
interpreter.set(dst(), TRY(private_reference.get_value(vm)));
return {};
}
ThrowCompletionOr<void> HasPrivateId::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto base = interpreter.get(m_base);
if (!base.is_object())
return vm.throw_completion<TypeError>(ErrorType::InOperatorWithObject);
auto private_environment = interpreter.running_execution_context().private_environment;
VERIFY(private_environment);
auto private_name = private_environment->resolve_private_identifier(interpreter.current_executable().get_identifier(m_property));
interpreter.set(dst(), Value(base.as_object().private_element_find(private_name) != nullptr));
return {};
}
ThrowCompletionOr<void> PutById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
PropertyKey name = interpreter.current_executable().get_identifier(m_property);
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
TRY(put_by_property_key(vm, base, base, value, base_identifier, name, m_kind, &cache));
return {};
}
ThrowCompletionOr<void> PutByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
PropertyKey name = interpreter.current_executable().get_identifier(m_property);
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
TRY(put_by_property_key(vm, base, interpreter.get(m_this_value), value, {}, name, m_kind, &cache));
return {};
}
ThrowCompletionOr<void> PutPrivateById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
auto object = TRY(interpreter.get(m_base).to_object(vm));
auto name = interpreter.current_executable().get_identifier(m_property);
auto private_reference = make_private_reference(vm, object, name);
TRY(private_reference.put_value(vm, value));
return {};
}
ThrowCompletionOr<void> DeleteById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(m_base);
interpreter.set(dst(), TRY(Bytecode::delete_by_id(interpreter, base_value, m_property)));
return {};
}
ThrowCompletionOr<void> DeleteByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto base_value = interpreter.get(m_base);
auto const& identifier = interpreter.current_executable().get_identifier(m_property);
bool strict = vm.in_strict_mode();
auto reference = Reference { base_value, identifier, interpreter.get(m_this_value), strict };
interpreter.set(dst(), Value(TRY(reference.delete_(vm))));
return {};
}
ThrowCompletionOr<void> ResolveThisBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& cached_this_value = interpreter.reg(Register::this_value());
if (!cached_this_value.is_empty())
return {};
// OPTIMIZATION: Because the value of 'this' cannot be reassigned during a function execution, it's
// resolved once and then saved for subsequent use.
auto& running_execution_context = interpreter.running_execution_context();
if (auto function = running_execution_context.function; function && is<ECMAScriptFunctionObject>(*function) && !static_cast<ECMAScriptFunctionObject&>(*function).allocates_function_environment()) {
cached_this_value = running_execution_context.this_value;
} else {
auto& vm = interpreter.vm();
cached_this_value = TRY(vm.resolve_this_binding());
}
return {};
}
// https://tc39.es/ecma262/#sec-makesuperpropertyreference
ThrowCompletionOr<void> ResolveSuperBase::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
// 1. Let env be GetThisEnvironment().
auto& env = verify_cast<FunctionEnvironment>(*get_this_environment(vm));
// 2. Assert: env.HasSuperBinding() is true.
VERIFY(env.has_super_binding());
// 3. Let baseValue be ? env.GetSuperBase().
interpreter.set(dst(), TRY(env.get_super_base()));
return {};
}
void GetNewTarget::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), interpreter.vm().get_new_target());
}
void GetImportMeta::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), interpreter.vm().get_import_meta());
}
static ThrowCompletionOr<Value> dispatch_builtin_call(Bytecode::Interpreter& interpreter, Bytecode::Builtin builtin, ReadonlySpan<Operand> arguments)
{
switch (builtin) {
case Builtin::MathAbs:
return TRY(MathObject::abs_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathLog:
return TRY(MathObject::log_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathPow:
return TRY(MathObject::pow_impl(interpreter.vm(), interpreter.get(arguments[0]), interpreter.get(arguments[1])));
case Builtin::MathExp:
return TRY(MathObject::exp_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathCeil:
return TRY(MathObject::ceil_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathFloor:
return TRY(MathObject::floor_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathRound:
return TRY(MathObject::round_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathSqrt:
return TRY(MathObject::sqrt_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Bytecode::Builtin::__Count:
VERIFY_NOT_REACHED();
}
VERIFY_NOT_REACHED();
}
ThrowCompletionOr<void> Call::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto callee = interpreter.get(m_callee);
TRY(throw_if_needed_for_call(interpreter, callee, call_type(), expression_string()));
if (m_builtin.has_value()
&& m_argument_count == Bytecode::builtin_argument_count(m_builtin.value())
&& callee.is_object()
&& interpreter.realm().get_builtin_value(m_builtin.value()) == &callee.as_object()) {
interpreter.set(dst(), TRY(dispatch_builtin_call(interpreter, m_builtin.value(), { m_arguments, m_argument_count })));
return {};
}
Vector<Value> argument_values;
argument_values.ensure_capacity(m_argument_count);
for (size_t i = 0; i < m_argument_count; ++i)
argument_values.unchecked_append(interpreter.get(m_arguments[i]));
interpreter.set(dst(), TRY(perform_call(interpreter, interpreter.get(m_this_value), call_type(), callee, argument_values)));
return {};
}
ThrowCompletionOr<void> CallWithArgumentArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto callee = interpreter.get(m_callee);
TRY(throw_if_needed_for_call(interpreter, callee, call_type(), expression_string()));
auto argument_values = argument_list_evaluation(interpreter.vm(), interpreter.get(arguments()));
interpreter.set(dst(), TRY(perform_call(interpreter, interpreter.get(m_this_value), call_type(), callee, move(argument_values))));
return {};
}
// 13.3.7.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
ThrowCompletionOr<void> SuperCallWithArgumentArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), TRY(super_call_with_argument_array(interpreter.vm(), interpreter.get(arguments()), m_is_synthetic)));
return {};
}
void NewFunction::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
interpreter.set(dst(), new_function(vm, m_function_node, m_lhs_name, m_home_object));
}
void Return::execute_impl(Bytecode::Interpreter& interpreter) const
{
if (m_value.has_value())
interpreter.do_return(interpreter.get(*m_value));
else
interpreter.do_return(js_undefined());
}
ThrowCompletionOr<void> Increment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(dst());
// OPTIMIZATION: Fast path for Int32 values.
if (old_value.is_int32()) {
auto integer_value = old_value.as_i32();
if (integer_value != NumericLimits<i32>::max()) [[likely]] {
interpreter.set(dst(), Value { integer_value + 1 });
return {};
}
}
old_value = TRY(old_value.to_numeric(vm));
if (old_value.is_number())
interpreter.set(dst(), Value(old_value.as_double() + 1));
else
interpreter.set(dst(), BigInt::create(vm, old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 })));
return {};
}
ThrowCompletionOr<void> PostfixIncrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(m_src);
// OPTIMIZATION: Fast path for Int32 values.
if (old_value.is_int32()) {
auto integer_value = old_value.as_i32();
if (integer_value != NumericLimits<i32>::max()) [[likely]] {
interpreter.set(m_dst, old_value);
interpreter.set(m_src, Value { integer_value + 1 });
return {};
}
}
old_value = TRY(old_value.to_numeric(vm));
interpreter.set(m_dst, old_value);
if (old_value.is_number())
interpreter.set(m_src, Value(old_value.as_double() + 1));
else
interpreter.set(m_src, BigInt::create(vm, old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 })));
return {};
}
ThrowCompletionOr<void> Decrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(dst());
old_value = TRY(old_value.to_numeric(vm));
if (old_value.is_number())
interpreter.set(dst(), Value(old_value.as_double() - 1));
else
interpreter.set(dst(), BigInt::create(vm, old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 })));
return {};
}
ThrowCompletionOr<void> PostfixDecrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(m_src);
old_value = TRY(old_value.to_numeric(vm));
interpreter.set(m_dst, old_value);
if (old_value.is_number())
interpreter.set(m_src, Value(old_value.as_double() - 1));
else
interpreter.set(m_src, BigInt::create(vm, old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 })));
return {};
}
ThrowCompletionOr<void> Throw::execute_impl(Bytecode::Interpreter& interpreter) const
{
return throw_completion(interpreter.get(src()));
}
ThrowCompletionOr<void> ThrowIfNotObject::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto src = interpreter.get(m_src);
if (!src.is_object())
return vm.throw_completion<TypeError>(ErrorType::NotAnObject, src.to_string_without_side_effects());
return {};
}
ThrowCompletionOr<void> ThrowIfNullish::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
if (value.is_nullish())
return vm.throw_completion<TypeError>(ErrorType::NotObjectCoercible, value.to_string_without_side_effects());
return {};
}
ThrowCompletionOr<void> ThrowIfTDZ::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
if (value.is_empty())
return vm.throw_completion<ReferenceError>(ErrorType::BindingNotInitialized, value.to_string_without_side_effects());
return {};
}
void LeaveLexicalEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& running_execution_context = interpreter.running_execution_context();
running_execution_context.lexical_environment = running_execution_context.saved_lexical_environments.take_last();
}
void LeavePrivateEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& running_execution_context = interpreter.vm().running_execution_context();
running_execution_context.private_environment = running_execution_context.private_environment->outer_environment();
}
void LeaveUnwindContext::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.leave_unwind_context();
}
void Yield::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto yielded_value = interpreter.get(m_value).value_or(js_undefined());
interpreter.do_return(
interpreter.do_yield(yielded_value, m_continuation_label));
}
void PrepareYield::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto value = interpreter.get(m_value).value_or(js_undefined());
interpreter.set(m_dest, interpreter.do_yield(value, {}));
}
void Await::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto yielded_value = interpreter.get(m_argument).value_or(js_undefined());
auto object = Object::create(interpreter.realm(), nullptr);
object->define_direct_property("result", yielded_value, JS::default_attributes);
// FIXME: If we get a pointer, which is not accurately representable as a double
// will cause this to explode
object->define_direct_property("continuation", Value(m_continuation_label.address()), JS::default_attributes);
object->define_direct_property("isAwait", Value(true), JS::default_attributes);
interpreter.do_return(object);
}
ThrowCompletionOr<void> GetByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), TRY(get_by_value(interpreter.vm(), m_base_identifier, interpreter.get(m_base), interpreter.get(m_property), interpreter.current_executable())));
return {};
}
ThrowCompletionOr<void> GetByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto property_key_value = interpreter.get(m_property);
auto object = TRY(interpreter.get(m_base).to_object(vm));
auto property_key = TRY(property_key_value.to_property_key(vm));
interpreter.set(dst(), TRY(object->internal_get(property_key, interpreter.get(m_this_value))));
return {};
}
ThrowCompletionOr<void> PutByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
TRY(put_by_value(vm, interpreter.get(m_base), base_identifier, interpreter.get(m_property), value, m_kind));
return {};
}
ThrowCompletionOr<void> PutByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
auto property_key = m_kind != PropertyKind::Spread ? TRY(interpreter.get(m_property).to_property_key(vm)) : PropertyKey {};
TRY(put_by_property_key(vm, base, interpreter.get(m_this_value), value, {}, property_key, m_kind));
return {};
}
ThrowCompletionOr<void> DeleteByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto base_value = interpreter.get(m_base);
auto property_key_value = interpreter.get(m_property);
interpreter.set(dst(), TRY(delete_by_value(interpreter, base_value, property_key_value)));
return {};
}
ThrowCompletionOr<void> DeleteByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto property_key_value = interpreter.get(m_property);
auto base_value = interpreter.get(m_base);
auto this_value = interpreter.get(m_this_value);
interpreter.set(dst(), TRY(delete_by_value_with_this(interpreter, base_value, property_key_value, this_value)));
return {};
}
ThrowCompletionOr<void> GetIterator::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
interpreter.set(dst(), TRY(get_iterator(vm, interpreter.get(iterable()), m_hint)));
return {};
}
ThrowCompletionOr<void> GetObjectFromIteratorRecord::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(m_object, iterator_record.iterator);
return {};
}
ThrowCompletionOr<void> GetNextMethodFromIteratorRecord::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(m_next_method, iterator_record.next_method);
return {};
}
ThrowCompletionOr<void> GetMethod::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto identifier = interpreter.current_executable().get_identifier(m_property);
auto method = TRY(interpreter.get(m_object).get_method(vm, identifier));
interpreter.set(dst(), method ?: js_undefined());
return {};
}
ThrowCompletionOr<void> GetObjectPropertyIterator::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.set(dst(), TRY(get_object_property_iterator(interpreter.vm(), interpreter.get(object()))));
return {};
}
ThrowCompletionOr<void> IteratorClose::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& iterator = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
// FIXME: Return the value of the resulting completion. (Note that m_completion_value can be empty!)
TRY(iterator_close(vm, iterator, Completion { m_completion_type, m_completion_value }));
return {};
}
ThrowCompletionOr<void> AsyncIteratorClose::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& iterator = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
// FIXME: Return the value of the resulting completion. (Note that m_completion_value can be empty!)
TRY(async_iterator_close(vm, iterator, Completion { m_completion_type, m_completion_value }));
return {};
}
ThrowCompletionOr<void> IteratorNext::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(dst(), TRY(iterator_next(vm, iterator_record)));
return {};
}
ThrowCompletionOr<void> NewClass::execute_impl(Bytecode::Interpreter& interpreter) const
{
Value super_class;
if (m_super_class.has_value())
super_class = interpreter.get(m_super_class.value());
Vector<Value> element_keys;
for (size_t i = 0; i < m_element_keys_count; ++i) {
Value element_key;
if (m_element_keys[i].has_value())
element_key = interpreter.get(m_element_keys[i].value());
element_keys.append(element_key);
}
interpreter.set(dst(), TRY(new_class(interpreter.vm(), super_class, m_class_expression, m_lhs_name, element_keys)));
return {};
}
// 13.5.3.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-typeof-operator-runtime-semantics-evaluation
ThrowCompletionOr<void> TypeofBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
if (m_cache.is_valid()) {
auto const* environment = interpreter.running_execution_context().lexical_environment.ptr();
for (size_t i = 0; i < m_cache.hops; ++i)
environment = environment->outer_environment();
if (!environment->is_permanently_screwed_by_eval()) {
auto value = TRY(static_cast<DeclarativeEnvironment const&>(*environment).get_binding_value_direct(vm, m_cache.index));
interpreter.set(dst(), PrimitiveString::create(vm, value.typeof()));
return {};
}
m_cache = {};
}
// 1. Let val be the result of evaluating UnaryExpression.
auto reference = TRY(vm.resolve_binding(interpreter.current_executable().get_identifier(m_identifier)));
// 2. If val is a Reference Record, then
// a. If IsUnresolvableReference(val) is true, return "undefined".
if (reference.is_unresolvable()) {
interpreter.set(dst(), PrimitiveString::create(vm, "undefined"_string));
return {};
}
// 3. Set val to ? GetValue(val).
auto value = TRY(reference.get_value(vm));
if (reference.environment_coordinate().has_value())
m_cache = reference.environment_coordinate().value();
// 4. NOTE: This step is replaced in section B.3.6.3.
// 5. Return a String according to Table 41.
interpreter.set(dst(), PrimitiveString::create(vm, value.typeof()));
return {};
}
void BlockDeclarationInstantiation::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_environment = interpreter.running_execution_context().lexical_environment;
auto& running_execution_context = interpreter.running_execution_context();
running_execution_context.saved_lexical_environments.append(old_environment);
running_execution_context.lexical_environment = new_declarative_environment(*old_environment);
m_scope_node.block_declaration_instantiation(vm, running_execution_context.lexical_environment);
}
ByteString Mov::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Mov {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("src"sv, m_src, executable));
}
ByteString NewArray::to_byte_string_impl(Bytecode::Executable const& executable) const
{
StringBuilder builder;
builder.appendff("NewArray {}", format_operand("dst"sv, dst(), executable));
if (m_element_count != 0) {
builder.appendff(", {}", format_operand_list("args"sv, { m_elements, m_element_count }, executable));
}
return builder.to_byte_string();
}
ByteString NewPrimitiveArray::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("NewPrimitiveArray {}, {}"sv,
format_operand("dst"sv, dst(), executable),
format_value_list("elements"sv, elements()));
}
ByteString AddPrivateName::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("AddPrivateName {}"sv, executable.identifier_table->get(m_name));
}
ByteString ArrayAppend::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Append {}, {}{}",
format_operand("dst"sv, dst(), executable),
format_operand("src"sv, src(), executable),
m_is_spread ? " **"sv : ""sv);
}
ByteString IteratorToArray::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("IteratorToArray {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("iterator"sv, iterator(), executable));
}
ByteString NewObject::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("NewObject {}", format_operand("dst"sv, dst(), executable));
}
ByteString NewRegExp::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("NewRegExp {}, source:{} (\"{}\") flags:{} (\"{}\")",
format_operand("dst"sv, dst(), executable),
m_source_index, executable.get_string(m_source_index), m_flags_index, executable.get_string(m_flags_index));
}
ByteString CopyObjectExcludingProperties::to_byte_string_impl(Bytecode::Executable const& executable) const
{
StringBuilder builder;
builder.appendff("CopyObjectExcludingProperties {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("from"sv, m_from_object, executable));
if (m_excluded_names_count != 0) {
builder.append(" excluding:["sv);
for (size_t i = 0; i < m_excluded_names_count; ++i) {
if (i != 0)
builder.append(", "sv);
builder.append(format_operand("#"sv, m_excluded_names[i], executable));
}
builder.append(']');
}
return builder.to_byte_string();
}
ByteString ConcatString::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ConcatString {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("src"sv, src(), executable));
}
ByteString GetCalleeAndThisFromEnvironment::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetCalleeAndThisFromEnvironment {}, {} <- {}",
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable),
executable.identifier_table->get(m_identifier));
}
ByteString GetBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetBinding {}, {}",
format_operand("dst"sv, dst(), executable),
executable.identifier_table->get(m_identifier));
}
ByteString GetGlobal::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetGlobal {}, {}", format_operand("dst"sv, dst(), executable),
executable.identifier_table->get(m_identifier));
}
ByteString DeleteVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("DeleteVariable {}", executable.identifier_table->get(m_identifier));
}
ByteString CreateLexicalEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
{
return "CreateLexicalEnvironment"sv;
}
ByteString CreatePrivateEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
{
return "CreatePrivateEnvironment"sv;
}
ByteString CreateVariableEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
{
return "CreateVariableEnvironment"sv;
}
ByteString CreateVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto mode_string = m_mode == EnvironmentMode::Lexical ? "Lexical" : "Variable";
return ByteString::formatted("CreateVariable env:{} immutable:{} global:{} {}", mode_string, m_is_immutable, m_is_global, executable.identifier_table->get(m_identifier));
}
ByteString CreateRestParams::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("CreateRestParams {}, rest_index:{}", format_operand("dst"sv, m_dst, executable), m_rest_index);
}
ByteString CreateArguments::to_byte_string_impl(Bytecode::Executable const& executable) const
{
StringBuilder builder;
builder.appendff("CreateArguments");
if (m_dst.has_value())
builder.appendff(" {}", format_operand("dst"sv, *m_dst, executable));
builder.appendff(" {} immutable:{}", m_kind == Kind::Mapped ? "mapped"sv : "unmapped"sv, m_is_immutable);
return builder.to_byte_string();
}
ByteString EnterObjectEnvironment::to_byte_string_impl(Executable const& executable) const
{
return ByteString::formatted("EnterObjectEnvironment {}",
format_operand("object"sv, m_object, executable));
}
ByteString InitializeLexicalBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("InitializeLexicalBinding {}, {}",
executable.identifier_table->get(m_identifier),
format_operand("src"sv, src(), executable));
}
ByteString InitializeVariableBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("InitializeVariableBinding {}, {}",
executable.identifier_table->get(m_identifier),
format_operand("src"sv, src(), executable));
}
ByteString SetLexicalBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("SetLexicalBinding {}, {}",
executable.identifier_table->get(m_identifier),
format_operand("src"sv, src(), executable));
}
ByteString SetVariableBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("SetVariableBinding {}, {}",
executable.identifier_table->get(m_identifier),
format_operand("src"sv, src(), executable));
}
ByteString GetArgument::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetArgument {}, {}", index(), format_operand("dst"sv, dst(), executable));
}
ByteString SetArgument::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("SetArgument {}, {}", index(), format_operand("src"sv, src(), executable));
}
static StringView property_kind_to_string(PropertyKind kind)
{
switch (kind) {
case PropertyKind::Getter:
return "getter"sv;
case PropertyKind::Setter:
return "setter"sv;
case PropertyKind::KeyValue:
return "key-value"sv;
case PropertyKind::DirectKeyValue:
return "direct-key-value"sv;
case PropertyKind::Spread:
return "spread"sv;
case PropertyKind::ProtoSetter:
return "proto-setter"sv;
}
VERIFY_NOT_REACHED();
}
ByteString PutById::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto kind = property_kind_to_string(m_kind);
return ByteString::formatted("PutById {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
kind);
}
ByteString PutByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto kind = property_kind_to_string(m_kind);
return ByteString::formatted("PutByIdWithThis {}, {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
format_operand("this"sv, m_this_value, executable),
kind);
}
ByteString PutPrivateById::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto kind = property_kind_to_string(m_kind);
return ByteString::formatted(
"PutPrivateById {}, {}, {}, kind:{} ",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
kind);
}
ByteString GetById::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
}
ByteString GetByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetByIdWithThis {}, {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("this"sv, m_this_value, executable));
}
ByteString GetLength::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetLength {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable));
}
ByteString GetLengthWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetLengthWithThis {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
format_operand("this"sv, m_this_value, executable));
}
ByteString GetPrivateById::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetPrivateById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
}
ByteString HasPrivateId::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("HasPrivateId {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
}
ByteString DeleteById::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("DeleteById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
}
ByteString DeleteByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("DeleteByIdWithThis {}, {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("this"sv, m_this_value, executable));
}
ByteString Jump::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("Jump {}", m_target);
}
ByteString JumpIf::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpIf {}, \033[32mtrue\033[0m:{} \033[32mfalse\033[0m:{}",
format_operand("condition"sv, m_condition, executable),
m_true_target,
m_false_target);
}
ByteString JumpTrue::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpTrue {}, {}",
format_operand("condition"sv, m_condition, executable),
m_target);
}
ByteString JumpFalse::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpFalse {}, {}",
format_operand("condition"sv, m_condition, executable),
m_target);
}
ByteString JumpNullish::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpNullish {}, null:{} nonnull:{}",
format_operand("condition"sv, m_condition, executable),
m_true_target,
m_false_target);
}
#define HANDLE_COMPARISON_OP(op_TitleCase, op_snake_case, numeric_operator) \
ByteString Jump##op_TitleCase::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted("Jump" #op_TitleCase " {}, {}, true:{}, false:{}", \
format_operand("lhs"sv, m_lhs, executable), \
format_operand("rhs"sv, m_rhs, executable), \
m_true_target, \
m_false_target); \
}
JS_ENUMERATE_COMPARISON_OPS(HANDLE_COMPARISON_OP)
ByteString JumpUndefined::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpUndefined {}, undefined:{} defined:{}",
format_operand("condition"sv, m_condition, executable),
m_true_target,
m_false_target);
}
static StringView call_type_to_string(CallType type)
{
switch (type) {
case CallType::Call:
return ""sv;
case CallType::Construct:
return " (Construct)"sv;
case CallType::DirectEval:
return " (DirectEval)"sv;
}
VERIFY_NOT_REACHED();
}
ByteString Call::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto type = call_type_to_string(m_type);
StringBuilder builder;
builder.appendff("Call{} {}, {}, {}, "sv,
type,
format_operand("dst"sv, m_dst, executable),
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable));
builder.append(format_operand_list("args"sv, { m_arguments, m_argument_count }, executable));
if (m_builtin.has_value()) {
builder.appendff(", (builtin:{})", m_builtin.value());
}
if (m_expression_string.has_value()) {
builder.appendff(", `{}`", executable.get_string(m_expression_string.value()));
}
return builder.to_byte_string();
}
ByteString CallWithArgumentArray::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto type = call_type_to_string(m_type);
StringBuilder builder;
builder.appendff("CallWithArgumentArray{} {}, {}, {}, {}",
type,
format_operand("dst"sv, m_dst, executable),
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable),
format_operand("arguments"sv, m_arguments, executable));
if (m_expression_string.has_value())
builder.appendff(" ({})", executable.get_string(m_expression_string.value()));
return builder.to_byte_string();
}
ByteString SuperCallWithArgumentArray::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("SuperCallWithArgumentArray {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("arguments"sv, m_arguments, executable));
}
ByteString NewFunction::to_byte_string_impl(Bytecode::Executable const& executable) const
{
StringBuilder builder;
builder.appendff("NewFunction {}",
format_operand("dst"sv, m_dst, executable));
if (m_function_node.has_name())
builder.appendff(" name:{}"sv, m_function_node.name());
if (m_lhs_name.has_value())
builder.appendff(" lhs_name:{}"sv, executable.get_identifier(m_lhs_name.value()));
if (m_home_object.has_value())
builder.appendff(", {}"sv, format_operand("home_object"sv, m_home_object.value(), executable));
return builder.to_byte_string();
}
ByteString NewClass::to_byte_string_impl(Bytecode::Executable const& executable) const
{
StringBuilder builder;
auto name = m_class_expression.name();
builder.appendff("NewClass {}",
format_operand("dst"sv, m_dst, executable));
if (m_super_class.has_value())
builder.appendff(", {}", format_operand("super_class"sv, *m_super_class, executable));
if (!name.is_empty())
builder.appendff(", {}", name);
if (m_lhs_name.has_value())
builder.appendff(", lhs_name:{}"sv, executable.get_identifier(m_lhs_name.value()));
return builder.to_byte_string();
}
ByteString Return::to_byte_string_impl(Bytecode::Executable const& executable) const
{
if (m_value.has_value())
return ByteString::formatted("Return {}", format_operand("value"sv, m_value.value(), executable));
return "Return";
}
ByteString Increment::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Increment {}", format_operand("dst"sv, m_dst, executable));
}
ByteString PostfixIncrement::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("PostfixIncrement {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("src"sv, m_src, executable));
}
ByteString Decrement::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Decrement {}", format_operand("dst"sv, m_dst, executable));
}
ByteString PostfixDecrement::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("PostfixDecrement {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("src"sv, m_src, executable));
}
ByteString Throw::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Throw {}",
format_operand("src"sv, m_src, executable));
}
ByteString ThrowIfNotObject::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ThrowIfNotObject {}",
format_operand("src"sv, m_src, executable));
}
ByteString ThrowIfNullish::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ThrowIfNullish {}",
format_operand("src"sv, m_src, executable));
}
ByteString ThrowIfTDZ::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ThrowIfTDZ {}",
format_operand("src"sv, m_src, executable));
}
ByteString EnterUnwindContext::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("EnterUnwindContext entry:{}", m_entry_point);
}
ByteString ScheduleJump::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("ScheduleJump {}", m_target);
}
ByteString LeaveLexicalEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
{
return "LeaveLexicalEnvironment"sv;
}
ByteString LeavePrivateEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
{
return "LeavePrivateEnvironment"sv;
}
ByteString LeaveUnwindContext::to_byte_string_impl(Bytecode::Executable const&) const
{
return "LeaveUnwindContext";
}
ByteString ContinuePendingUnwind::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("ContinuePendingUnwind resume:{}", m_resume_target);
}
ByteString Yield::to_byte_string_impl(Bytecode::Executable const& executable) const
{
if (m_continuation_label.has_value()) {
return ByteString::formatted("Yield continuation:{}, {}",
m_continuation_label.value(),
format_operand("value"sv, m_value, executable));
}
return ByteString::formatted("Yield return {}",
format_operand("value"sv, m_value, executable));
}
ByteString PrepareYield::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("PrepareYield {}, {}",
format_operand("dst"sv, m_dest, executable),
format_operand("value"sv, m_value, executable));
}
ByteString Await::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Await {}, continuation:{}",
format_operand("argument"sv, m_argument, executable),
m_continuation_label);
}
ByteString GetByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetByValue {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
}
ByteString GetByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetByValueWithThis {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
}
ByteString PutByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto kind = property_kind_to_string(m_kind);
return ByteString::formatted("PutByValue {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("src"sv, m_src, executable),
kind);
}
ByteString PutByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
auto kind = property_kind_to_string(m_kind);
return ByteString::formatted("PutByValueWithThis {}, {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("src"sv, m_src, executable),
format_operand("this"sv, m_this_value, executable),
kind);
}
ByteString DeleteByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("DeleteByValue {}, {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
}
ByteString DeleteByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("DeleteByValueWithThis {}, {}, {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("this"sv, m_this_value, executable));
}
ByteString GetIterator::to_byte_string_impl(Executable const& executable) const
{
auto hint = m_hint == IteratorHint::Sync ? "sync" : "async";
return ByteString::formatted("GetIterator {}, {}, hint:{}",
format_operand("dst"sv, m_dst, executable),
format_operand("iterable"sv, m_iterable, executable),
hint);
}
ByteString GetMethod::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetMethod {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("object"sv, m_object, executable),
executable.identifier_table->get(m_property));
}
ByteString GetObjectPropertyIterator::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetObjectPropertyIterator {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("object"sv, object(), executable));
}
ByteString IteratorClose::to_byte_string_impl(Bytecode::Executable const& executable) const
{
if (!m_completion_value.has_value())
return ByteString::formatted("IteratorClose {}, completion_type={} completion_value=<empty>",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type));
auto completion_value_string = m_completion_value->to_string_without_side_effects();
return ByteString::formatted("IteratorClose {}, completion_type={} completion_value={}",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type), completion_value_string);
}
ByteString AsyncIteratorClose::to_byte_string_impl(Bytecode::Executable const& executable) const
{
if (!m_completion_value.has_value()) {
return ByteString::formatted("AsyncIteratorClose {}, completion_type:{} completion_value:<empty>",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type));
}
return ByteString::formatted("AsyncIteratorClose {}, completion_type:{}, completion_value:{}",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type), m_completion_value);
}
ByteString IteratorNext::to_byte_string_impl(Executable const& executable) const
{
return ByteString::formatted("IteratorNext {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
}
ByteString ResolveThisBinding::to_byte_string_impl(Bytecode::Executable const&) const
{
return "ResolveThisBinding"sv;
}
ByteString ResolveSuperBase::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ResolveSuperBase {}",
format_operand("dst"sv, m_dst, executable));
}
ByteString GetNewTarget::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetNewTarget {}", format_operand("dst"sv, m_dst, executable));
}
ByteString GetImportMeta::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetImportMeta {}", format_operand("dst"sv, m_dst, executable));
}
ByteString TypeofBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("TypeofBinding {}, {}",
format_operand("dst"sv, m_dst, executable),
executable.identifier_table->get(m_identifier));
}
ByteString BlockDeclarationInstantiation::to_byte_string_impl(Bytecode::Executable const&) const
{
return "BlockDeclarationInstantiation"sv;
}
ByteString ImportCall::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ImportCall {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("specifier"sv, m_specifier, executable),
format_operand("options"sv, m_options, executable));
}
ByteString Catch::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Catch {}",
format_operand("dst"sv, m_dst, executable));
}
ByteString LeaveFinally::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("LeaveFinally");
}
ByteString RestoreScheduledJump::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("RestoreScheduledJump");
}
ByteString GetObjectFromIteratorRecord::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetObjectFromIteratorRecord {}, {}",
format_operand("object"sv, m_object, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
}
ByteString GetNextMethodFromIteratorRecord::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("GetNextMethodFromIteratorRecord {}, {}",
format_operand("next_method"sv, m_next_method, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
}
ByteString End::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("End {}", format_operand("value"sv, m_value, executable));
}
ByteString Dump::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Dump '{}', {}", m_text,
format_operand("value"sv, m_value, executable));
}
}
Reference in a new issue View git blame Copy permalink