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ladybird/Userland/Libraries/LibJS/Runtime/ECMAScriptFunctionObject.cpp
Linus Groh cf168fac50 LibJS: Implement [[Call]] and [[Construct]] internal slots properly 
This patch implements:

- Spec compliant [[Call]] and [[Construct]] internal slots, as virtual
  FunctionObject::internal_{call,construct}(). These effectively replace
  the old virtual FunctionObject::{call,construct}(), but with several
  advantages:
  - Clear and consistent naming, following the object internal methods
  - Use of completions
  - internal_construct() returns an Object, and not Value! This has been
    a source of confusion for a long time, since in the spec there's
    always an Object returned but the Value return type in LibJS meant
    that this could not be fully trusted and something could screw you
    over.
  - Arguments are passed explicitly in form of a MarkedValueList,
    allowing manipulation (BoundFunction). We still put them on the
    execution context as a lot of code depends on it (VM::arguments()),
    but not from the Call() / Construct() AOs anymore, which now allows
    for bypassing them and invoking [[Call]] / [[Construct]] directly.
    Nothing but Call() / Construct() themselves do that at the moment,
    but future additions to ECMA262 or already existing web specs might.
- Spec compliant, standalone Call() and Construct() AOs: currently the
  closest we have is VM::{call,construct}(), but those try to cater to
  all the different function object subclasses at once, resulting in a
  horrible mess and calling AOs with functions they should never be
  called with; most prominently PrepareForOrdinaryCall and
  OrdinaryCallBindThis, which are only for ECMAScriptFunctionObject.

As a result this also contains an implicit optimization: we no longer
need to create a new function environment for NativeFunctions - which,
worth mentioning, is what started this whole crusade in the first place
:^)
2021-10-09 14:29:20 +01:00

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/*
* Copyright (c) 2020, Stephan Unverwerth <s.unverwerth@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Debug.h>
#include <AK/Function.h>
#include <LibJS/AST.h>
#include <LibJS/Bytecode/BasicBlock.h>
#include <LibJS/Bytecode/Generator.h>
#include <LibJS/Bytecode/Interpreter.h>
#include <LibJS/Interpreter.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/ECMAScriptFunctionObject.h>
#include <LibJS/Runtime/Error.h>
#include <LibJS/Runtime/FunctionEnvironment.h>
#include <LibJS/Runtime/GeneratorObject.h>
#include <LibJS/Runtime/GeneratorObjectPrototype.h>
#include <LibJS/Runtime/GlobalObject.h>
#include <LibJS/Runtime/NativeFunction.h>
#include <LibJS/Runtime/Value.h>
namespace JS {
ECMAScriptFunctionObject* ECMAScriptFunctionObject::create(GlobalObject& global_object, FlyString name, Statement const& ecmascript_code, Vector<FunctionNode::Parameter> parameters, i32 m_function_length, Environment* parent_scope, FunctionKind kind, bool is_strict, bool might_need_arguments_object, bool contains_direct_call_to_eval, bool is_arrow_function)
{
Object* prototype = nullptr;
switch (kind) {
case FunctionKind::Regular:
prototype = global_object.function_prototype();
break;
case FunctionKind::Generator:
prototype = global_object.generator_function_prototype();
break;
}
return global_object.heap().allocate<ECMAScriptFunctionObject>(global_object, move(name), ecmascript_code, move(parameters), m_function_length, parent_scope, *prototype, kind, is_strict, might_need_arguments_object, contains_direct_call_to_eval, is_arrow_function);
}
ECMAScriptFunctionObject::ECMAScriptFunctionObject(FlyString name, Statement const& ecmascript_code, Vector<FunctionNode::Parameter> formal_parameters, i32 function_length, Environment* parent_scope, Object& prototype, FunctionKind kind, bool strict, bool might_need_arguments_object, bool contains_direct_call_to_eval, bool is_arrow_function)
: FunctionObject(prototype)
, m_environment(parent_scope)
, m_formal_parameters(move(formal_parameters))
, m_ecmascript_code(ecmascript_code)
, m_realm(vm().interpreter_if_exists() ? &vm().interpreter().realm() : nullptr)
, m_strict(strict)
, m_name(move(name))
, m_function_length(function_length)
, m_kind(kind)
, m_might_need_arguments_object(might_need_arguments_object)
, m_contains_direct_call_to_eval(contains_direct_call_to_eval)
, m_is_arrow_function(is_arrow_function)
{
// NOTE: This logic is from OrdinaryFunctionCreate, https://tc39.es/ecma262/#sec-ordinaryfunctioncreate
if (m_is_arrow_function)
m_this_mode = ThisMode::Lexical;
else if (m_strict)
m_this_mode = ThisMode::Strict;
else
m_this_mode = ThisMode::Global;
// 15.1.3 Static Semantics: IsSimpleParameterList, https://tc39.es/ecma262/#sec-static-semantics-issimpleparameterlist
m_has_simple_parameter_list = all_of(m_formal_parameters, [&](auto& parameter) {
if (parameter.is_rest)
return false;
if (parameter.default_value)
return false;
if (!parameter.binding.template has<FlyString>())
return false;
return true;
});
}
void ECMAScriptFunctionObject::initialize(GlobalObject& global_object)
{
auto& vm = this->vm();
Base::initialize(global_object);
if (!m_is_arrow_function) {
auto* prototype = vm.heap().allocate<Object>(global_object, *global_object.new_ordinary_function_prototype_object_shape());
switch (m_kind) {
case FunctionKind::Regular:
MUST(prototype->define_property_or_throw(vm.names.constructor, { .value = this, .writable = true, .enumerable = false, .configurable = true }));
break;
case FunctionKind::Generator:
// prototype is "g1.prototype" in figure-2 (https://tc39.es/ecma262/img/figure-2.png)
set_prototype(global_object.generator_object_prototype());
break;
}
define_direct_property(vm.names.prototype, prototype, Attribute::Writable);
}
MUST(define_property_or_throw(vm.names.length, { .value = Value(m_function_length), .writable = false, .enumerable = false, .configurable = true }));
MUST(define_property_or_throw(vm.names.name, { .value = js_string(vm, m_name.is_null() ? "" : m_name), .writable = false, .enumerable = false, .configurable = true }));
}
ECMAScriptFunctionObject::~ECMAScriptFunctionObject()
{
}
// 10.2.1 [[Call]] ( thisArgument, argumentsList ), https://tc39.es/ecma262/#sec-ecmascript-function-objects-call-thisargument-argumentslist
ThrowCompletionOr<Value> ECMAScriptFunctionObject::internal_call(Value this_argument, MarkedValueList arguments_list)
{
auto& vm = this->vm();
// 1. Let callerContext be the running execution context.
// NOTE: No-op, kept by the VM in its execution context stack.
ExecutionContext callee_context(heap());
// Non-standard
callee_context.arguments.extend(move(arguments_list));
if (auto* interpreter = vm.interpreter_if_exists())
callee_context.current_node = interpreter->current_node();
// 2. Let calleeContext be PrepareForOrdinaryCall(F, undefined).
vm.prepare_for_ordinary_call(*this, callee_context, nullptr);
// NOTE: We throw if the end of the native stack is reached, so unlike in the spec this _does_ need an exception check.
if (auto* exception = vm.exception())
return throw_completion(exception->value());
// 3. Assert: calleeContext is now the running execution context.
VERIFY(&vm.running_execution_context() == &callee_context);
// 4. If F.[[IsClassConstructor]] is true, then
if (m_is_class_constructor) {
// a. Let error be a newly created TypeError object.
// b. NOTE: error is created in calleeContext with F's associated Realm Record.
auto throw_completion = vm.throw_completion<TypeError>(global_object(), ErrorType::ClassConstructorWithoutNew, m_name);
// c. Remove calleeContext from the execution context stack and restore callerContext as the running execution context.
vm.pop_execution_context();
// d. Return ThrowCompletion(error).
return throw_completion;
}
// 5. Perform OrdinaryCallBindThis(F, calleeContext, thisArgument).
vm.ordinary_call_bind_this(*this, callee_context, this_argument);
// 6. Let result be OrdinaryCallEvaluateBody(F, argumentsList).
auto result = ordinary_call_evaluate_body();
// 7. Remove calleeContext from the execution context stack and restore callerContext as the running execution context.
vm.pop_execution_context();
// 8. If result.[[Type]] is return, return NormalCompletion(result.[[Value]]).
if (result.type() == Completion::Type::Return)
return result.value();
// 9. ReturnIfAbrupt(result).
if (result.is_abrupt()) {
// NOTE: I'm not sure if EvaluateBody can return a completion other than Normal, Return, or Throw.
// We're far from using completions in the AST anyway; in the meantime assume Throw.
VERIFY(result.is_error());
return result;
}
// 10. Return NormalCompletion(undefined).
return js_undefined();
}
// 10.2.2 [[Construct]] ( argumentsList, newTarget ), https://tc39.es/ecma262/#sec-ecmascript-function-objects-construct-argumentslist-newtarget
ThrowCompletionOr<Object*> ECMAScriptFunctionObject::internal_construct(MarkedValueList arguments_list, FunctionObject& new_target)
{
auto& vm = this->vm();
auto& global_object = this->global_object();
// 1. Let callerContext be the running execution context.
// NOTE: No-op, kept by the VM in its execution context stack.
// 2. Let kind be F.[[ConstructorKind]].
auto kind = m_constructor_kind;
Object* this_argument = nullptr;
// 3. If kind is base, then
if (kind == ConstructorKind::Base) {
// a. Let thisArgument be ? OrdinaryCreateFromConstructor(newTarget, "%Object.prototype%").
this_argument = TRY(ordinary_create_from_constructor<Object>(global_object, new_target, &GlobalObject::object_prototype));
}
ExecutionContext callee_context(heap());
// Non-standard
callee_context.arguments.extend(move(arguments_list));
if (auto* interpreter = vm.interpreter_if_exists())
callee_context.current_node = interpreter->current_node();
// 4. Let calleeContext be PrepareForOrdinaryCall(F, newTarget).
vm.prepare_for_ordinary_call(*this, callee_context, &new_target);
// NOTE: We throw if the end of the native stack is reached, so unlike in the spec this _does_ need an exception check.
if (auto* exception = vm.exception())
return throw_completion(exception->value());
// 5. Assert: calleeContext is now the running execution context.
VERIFY(&vm.running_execution_context() == &callee_context);
// 6. If kind is base, then
if (kind == ConstructorKind::Base) {
// a. Perform OrdinaryCallBindThis(F, calleeContext, thisArgument).
vm.ordinary_call_bind_this(*this, callee_context, this_argument);
// b. Let initializeResult be InitializeInstanceElements(thisArgument, F).
auto initialize_result = vm.initialize_instance_elements(*this_argument, *this);
// c. If initializeResult is an abrupt completion, then
if (initialize_result.is_throw_completion()) {
// i. Remove calleeContext from the execution context stack and restore callerContext as the running execution context.
vm.pop_execution_context();
// ii. Return Completion(initializeResult).
return initialize_result.throw_completion();
}
}
// 7. Let constructorEnv be the LexicalEnvironment of calleeContext.
auto* constructor_env = callee_context.lexical_environment;
// 8. Let result be OrdinaryCallEvaluateBody(F, argumentsList).
auto result = ordinary_call_evaluate_body();
// 9. Remove calleeContext from the execution context stack and restore callerContext as the running execution context.
vm.pop_execution_context();
// 10. If result.[[Type]] is return, then
if (result.type() == Completion::Type::Return) {
// FIXME: This is leftover from untangling the call/construct mess - doesn't belong here in any way, but removing it breaks derived classes.
// Likely fixed by making ClassDefinitionEvaluation fully spec compliant.
if (kind == ConstructorKind::Derived && result.value().is_object()) {
auto prototype = TRY(new_target.get(vm.names.prototype));
if (prototype.is_object())
TRY(result.value().as_object().internal_set_prototype_of(&prototype.as_object()));
}
// EOF (End of FIXME)
// a. If Type(result.[[Value]]) is Object, return NormalCompletion(result.[[Value]]).
if (result.value().is_object())
return &result.value().as_object();
// b. If kind is base, return NormalCompletion(thisArgument).
if (kind == ConstructorKind::Base)
return this_argument;
// c. If result.[[Value]] is not undefined, throw a TypeError exception.
if (!result.value().is_undefined())
return vm.throw_completion<TypeError>(global_object, ErrorType::DerivedConstructorReturningInvalidValue);
}
// 11. Else, ReturnIfAbrupt(result).
else {
// NOTE: I'm not sure if EvaluateBody can return a completion other than Normal, Return, or Throw.
// We're far from using completions in the AST anyway; in the meantime assume Throw.
VERIFY(result.is_error());
return result;
}
// 12. Return ? constructorEnv.GetThisBinding().
auto this_binding = constructor_env->get_this_binding(global_object);
if (auto* exception = vm.exception())
return throw_completion(exception->value());
return &this_binding.as_object();
}
void ECMAScriptFunctionObject::visit_edges(Visitor& visitor)
{
Base::visit_edges(visitor);
visitor.visit(m_environment);
visitor.visit(m_realm);
visitor.visit(m_home_object);
for (auto& field : m_fields) {
field.name.visit_edges(visitor);
visitor.visit(field.initializer);
}
}
// 9.1.2.4 NewFunctionEnvironment ( F, newTarget ), https://tc39.es/ecma262/#sec-newfunctionenvironment
FunctionEnvironment* ECMAScriptFunctionObject::new_function_environment(Object* new_target)
{
auto* environment = heap().allocate<FunctionEnvironment>(global_object(), m_environment);
environment->set_function_object(*this);
if (this_mode() == ThisMode::Lexical) {
environment->set_this_binding_status(FunctionEnvironment::ThisBindingStatus::Lexical);
}
environment->set_new_target(new_target ? new_target : js_undefined());
return environment;
}
// 10.2.11 FunctionDeclarationInstantiation ( func, argumentsList ), https://tc39.es/ecma262/#sec-functiondeclarationinstantiation
ThrowCompletionOr<void> ECMAScriptFunctionObject::function_declaration_instantiation(Interpreter* interpreter)
{
auto& vm = this->vm();
auto& callee_context = vm.running_execution_context();
// Needed to extract declarations and functions
ScopeNode const* scope_body = nullptr;
if (is<ScopeNode>(*m_ecmascript_code))
scope_body = static_cast<ScopeNode const*>(m_ecmascript_code.ptr());
bool has_parameter_expressions = false;
// FIXME: Maybe compute has duplicates at parse time? (We need to anyway since it's an error in some cases)
bool has_duplicates = false;
HashTable<FlyString> parameter_names;
for (auto& parameter : m_formal_parameters) {
if (parameter.default_value)
has_parameter_expressions = true;
parameter.binding.visit(
[&](FlyString const& name) {
if (parameter_names.set(name) != AK::HashSetResult::InsertedNewEntry)
has_duplicates = true;
},
[&](NonnullRefPtr<BindingPattern> const& pattern) {
if (pattern->contains_expression())
has_parameter_expressions = true;
pattern->for_each_bound_name([&](auto& name) {
if (parameter_names.set(name) != AK::HashSetResult::InsertedNewEntry)
has_duplicates = true;
});
});
}
auto arguments_object_needed = m_might_need_arguments_object;
if (this_mode() == ThisMode::Lexical)
arguments_object_needed = false;
if (parameter_names.contains(vm.names.arguments.as_string()))
arguments_object_needed = false;
HashTable<FlyString> function_names;
Vector<FunctionDeclaration const&> functions_to_initialize;
if (scope_body) {
scope_body->for_each_var_function_declaration_in_reverse_order([&](FunctionDeclaration const& function) {
if (function_names.set(function.name()) == AK::HashSetResult::InsertedNewEntry)
functions_to_initialize.append(function);
});
auto const& arguments_name = vm.names.arguments.as_string();
if (!has_parameter_expressions && function_names.contains(arguments_name))
arguments_object_needed = false;
if (!has_parameter_expressions && arguments_object_needed) {
scope_body->for_each_lexically_declared_name([&](auto const& name) {
if (name == arguments_name) {
arguments_object_needed = false;
return IterationDecision::Break;
}
return IterationDecision::Continue;
});
}
} else {
arguments_object_needed = false;
}
Environment* environment;
if (is_strict_mode() || !has_parameter_expressions) {
environment = callee_context.lexical_environment;
} else {
environment = new_declarative_environment(*callee_context.lexical_environment);
VERIFY(callee_context.variable_environment == callee_context.lexical_environment);
callee_context.lexical_environment = environment;
}
for (auto const& parameter_name : parameter_names) {
if (environment->has_binding(parameter_name))
continue;
environment->create_mutable_binding(global_object(), parameter_name, false);
if (has_duplicates)
environment->initialize_binding(global_object(), parameter_name, js_undefined());
VERIFY(!vm.exception());
}
if (arguments_object_needed) {
Object* arguments_object;
if (is_strict_mode() || !has_simple_parameter_list())
arguments_object = create_unmapped_arguments_object(global_object(), vm.running_execution_context().arguments);
else
arguments_object = create_mapped_arguments_object(global_object(), *this, formal_parameters(), vm.running_execution_context().arguments, *environment);
if (is_strict_mode())
environment->create_immutable_binding(global_object(), vm.names.arguments.as_string(), false);
else
environment->create_mutable_binding(global_object(), vm.names.arguments.as_string(), false);
environment->initialize_binding(global_object(), vm.names.arguments.as_string(), arguments_object);
parameter_names.set(vm.names.arguments.as_string());
}
// We now treat parameterBindings as parameterNames.
// The spec makes an iterator here to do IteratorBindingInitialization but we just do it manually
auto& execution_context_arguments = vm.running_execution_context().arguments;
for (size_t i = 0; i < m_formal_parameters.size(); ++i) {
auto& parameter = m_formal_parameters[i];
parameter.binding.visit(
[&](auto const& param) {
Value argument_value;
if (parameter.is_rest) {
auto* array = Array::create(global_object(), 0);
for (size_t rest_index = i; rest_index < execution_context_arguments.size(); ++rest_index)
array->indexed_properties().append(execution_context_arguments[rest_index]);
argument_value = move(array);
} else if (i < execution_context_arguments.size() && !execution_context_arguments[i].is_undefined()) {
argument_value = execution_context_arguments[i];
} else if (parameter.default_value) {
// FIXME: Support default arguments in the bytecode world!
if (interpreter)
argument_value = parameter.default_value->execute(*interpreter, global_object());
if (vm.exception())
return;
} else {
argument_value = js_undefined();
}
Environment* used_environment = has_duplicates ? nullptr : environment;
if constexpr (IsSame<FlyString const&, decltype(param)>) {
Reference reference = vm.resolve_binding(param, used_environment);
if (vm.exception())
return;
// Here the difference from hasDuplicates is important
if (has_duplicates)
reference.put_value(global_object(), argument_value);
else
reference.initialize_referenced_binding(global_object(), argument_value);
} else if (IsSame<NonnullRefPtr<BindingPattern> const&, decltype(param)>) {
// Here the difference from hasDuplicates is important
auto result = vm.binding_initialization(param, argument_value, used_environment, global_object());
if (result.is_error())
return;
}
if (vm.exception())
return;
});
if (auto* exception = vm.exception())
return throw_completion(exception->value());
}
Environment* var_environment;
HashTable<FlyString> instantiated_var_names;
if (scope_body)
instantiated_var_names.ensure_capacity(scope_body->var_declaration_count());
if (!has_parameter_expressions) {
if (scope_body) {
scope_body->for_each_var_declared_name([&](auto const& name) {
if (!parameter_names.contains(name) && instantiated_var_names.set(name) == AK::HashSetResult::InsertedNewEntry) {
environment->create_mutable_binding(global_object(), name, false);
environment->initialize_binding(global_object(), name, js_undefined());
}
});
}
var_environment = environment;
} else {
var_environment = new_declarative_environment(*environment);
callee_context.variable_environment = var_environment;
if (scope_body) {
scope_body->for_each_var_declared_name([&](auto const& name) {
if (instantiated_var_names.set(name) != AK::HashSetResult::InsertedNewEntry)
return IterationDecision::Continue;
var_environment->create_mutable_binding(global_object(), name, false);
Value initial_value;
if (!parameter_names.contains(name) || function_names.contains(name))
initial_value = js_undefined();
else
initial_value = environment->get_binding_value(global_object(), name, false);
var_environment->initialize_binding(global_object(), name, initial_value);
return IterationDecision::Continue;
});
}
}
// B.3.2.1 Changes to FunctionDeclarationInstantiation, https://tc39.es/ecma262/#sec-web-compat-functiondeclarationinstantiation
if (!m_strict && scope_body) {
scope_body->for_each_function_hoistable_with_annexB_extension([&](FunctionDeclaration& function_declaration) {
auto& function_name = function_declaration.name();
if (parameter_names.contains(function_name))
return IterationDecision::Continue;
// The spec says 'initializedBindings' here but that does not exist and it then adds it to 'instantiatedVarNames' so it probably means 'instantiatedVarNames'.
if (!instantiated_var_names.contains(function_name) && function_name != vm.names.arguments.as_string()) {
var_environment->create_mutable_binding(global_object(), function_name, false);
VERIFY(!vm.exception());
var_environment->initialize_binding(global_object(), function_name, js_undefined());
instantiated_var_names.set(function_name);
}
function_declaration.set_should_do_additional_annexB_steps();
return IterationDecision::Continue;
});
}
Environment* lex_environment;
// 30. If strict is false, then
if (!is_strict_mode()) {
// Optimization: We avoid creating empty top-level declarative environments in non-strict mode, if both of these conditions are true:
// 1. there is no direct call to eval() within this function
// 2. there are no lexical declarations that would go into the environment
bool can_elide_declarative_environment = !m_contains_direct_call_to_eval && (!scope_body || !scope_body->has_lexical_declarations());
if (can_elide_declarative_environment) {
lex_environment = var_environment;
} else {
// a. Let lexEnv be NewDeclarativeEnvironment(varEnv).
// b. NOTE: Non-strict functions use a separate Environment Record for top-level lexical declarations so that a direct eval
// can determine whether any var scoped declarations introduced by the eval code conflict with pre-existing top-level
// lexically scoped declarations. This is not needed for strict functions because a strict direct eval always places
// all declarations into a new Environment Record.
lex_environment = new_declarative_environment(*var_environment);
}
} else {
// 31. Else, let lexEnv be varEnv.
lex_environment = var_environment;
}
// 32. Set the LexicalEnvironment of calleeContext to lexEnv.
callee_context.lexical_environment = lex_environment;
if (!scope_body)
return {};
scope_body->for_each_lexically_scoped_declaration([&](Declaration const& declaration) {
declaration.for_each_bound_name([&](auto const& name) {
if (declaration.is_constant_declaration())
lex_environment->create_immutable_binding(global_object(), name, true);
else
lex_environment->create_mutable_binding(global_object(), name, false);
return IterationDecision::Continue;
});
});
VERIFY(!vm.exception());
for (auto& declaration : functions_to_initialize) {
auto* function = ECMAScriptFunctionObject::create(global_object(), declaration.name(), declaration.body(), declaration.parameters(), declaration.function_length(), lex_environment, declaration.kind(), declaration.is_strict_mode(), declaration.might_need_arguments_object(), declaration.contains_direct_call_to_eval());
var_environment->set_mutable_binding(global_object(), declaration.name(), function, false);
}
return {};
}
// 10.2.1.4 OrdinaryCallEvaluateBody ( F, argumentsList ), https://tc39.es/ecma262/#sec-ordinarycallevaluatebody
Completion ECMAScriptFunctionObject::ordinary_call_evaluate_body()
{
auto& vm = this->vm();
auto* bytecode_interpreter = Bytecode::Interpreter::current();
if (bytecode_interpreter) {
// FIXME: pass something to evaluate default arguments with
TRY(function_declaration_instantiation(nullptr));
if (!m_bytecode_executable.has_value()) {
m_bytecode_executable = Bytecode::Generator::generate(m_ecmascript_code, m_kind == FunctionKind::Generator);
auto& passes = JS::Bytecode::Interpreter::optimization_pipeline();
passes.perform(*m_bytecode_executable);
if constexpr (JS_BYTECODE_DEBUG) {
dbgln("Optimisation passes took {}us", passes.elapsed());
dbgln("Compiled Bytecode::Block for function '{}':", m_name);
for (auto& block : m_bytecode_executable->basic_blocks)
block.dump(*m_bytecode_executable);
}
}
auto result = bytecode_interpreter->run(*m_bytecode_executable);
if (auto* exception = vm.exception())
return throw_completion(exception->value());
// NOTE: Running the bytecode should eventually return a completion.
// Until it does, we assume "return" and include the undefined fallback from the call site.
if (m_kind != FunctionKind::Generator)
return { Completion::Type::Return, result.value_or(js_undefined()), {} };
return normal_completion(GeneratorObject::create(global_object(), result, this, vm.running_execution_context().lexical_environment, bytecode_interpreter->snapshot_frame()));
} else {
VERIFY(m_kind != FunctionKind::Generator);
OwnPtr<Interpreter> local_interpreter;
Interpreter* ast_interpreter = vm.interpreter_if_exists();
if (!ast_interpreter) {
local_interpreter = Interpreter::create_with_existing_realm(*realm());
ast_interpreter = local_interpreter.ptr();
}
VM::InterpreterExecutionScope scope(*ast_interpreter);
TRY(function_declaration_instantiation(ast_interpreter));
auto result = m_ecmascript_code->execute(*ast_interpreter, global_object());
if (auto* exception = vm.exception())
return throw_completion(exception->value());
// NOTE: Running the AST node should eventually return a completion.
// Until it does, we assume "return" and include the undefined fallback from the call site.
return { Completion::Type::Return, result.value_or(js_undefined()), {} };
}
VERIFY_NOT_REACHED();
}
void ECMAScriptFunctionObject::set_name(const FlyString& name)
{
VERIFY(!name.is_null());
auto& vm = this->vm();
m_name = name;
auto success = MUST(define_property_or_throw(vm.names.name, { .value = js_string(vm, m_name), .writable = false, .enumerable = false, .configurable = true }));
VERIFY(success);
}
// 7.3.31 DefineField ( receiver, fieldRecord ), https://tc39.es/ecma262/#sec-definefield
void ECMAScriptFunctionObject::InstanceField::define_field(VM& vm, Object& receiver) const
{
Value init_value = js_undefined();
if (initializer) {
auto init_value_or_error = vm.call(*initializer, receiver.value_of());
if (init_value_or_error.is_error())
return;
init_value = init_value_or_error.release_value();
}
(void)receiver.create_data_property_or_throw(name, init_value);
}
}
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