/* * Copyright (c) 2020-2021, Andreas Kling * Copyright (c) 2020-2021, Linus Groh * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace JS { class InterpreterNodeScope { AK_MAKE_NONCOPYABLE(InterpreterNodeScope); AK_MAKE_NONMOVABLE(InterpreterNodeScope); public: InterpreterNodeScope(Interpreter& interpreter, ASTNode const& node) : m_interpreter(interpreter) , m_chain_node { nullptr, node } { m_interpreter.vm().running_execution_context().current_node = &node; m_interpreter.push_ast_node(m_chain_node); } ~InterpreterNodeScope() { m_interpreter.pop_ast_node(); } private: Interpreter& m_interpreter; ExecutingASTNodeChain m_chain_node; }; String ASTNode::class_name() const { // NOTE: We strip the "JS::" prefix. return demangle(typeid(*this).name()).substring(4); } static void update_function_name(Value value, FlyString const& name) { if (!value.is_function()) return; auto& function = value.as_function(); if (is(function) && function.name().is_empty()) static_cast(function).set_name(name); } static String get_function_name(GlobalObject& global_object, Value value) { if (value.is_symbol()) return String::formatted("[{}]", value.as_symbol().description()); if (value.is_string()) return value.as_string().string(); return value.to_string(global_object); } Value ScopeNode::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return interpreter.execute_statement(global_object, *this); } Value Program::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return interpreter.execute_statement(global_object, *this, ScopeType::Block); } Value FunctionDeclaration::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; return {}; } // 15.2.5 Runtime Semantics: InstantiateOrdinaryFunctionExpression, https://tc39.es/ecma262/#sec-runtime-semantics-instantiateordinaryfunctionexpression Value FunctionExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto* func_env = interpreter.lexical_environment(); bool has_identifier = !name().is_empty() && !is_auto_renamed(); if (has_identifier) { func_env = interpreter.heap().allocate(global_object, func_env); func_env->create_immutable_binding(global_object, name(), false); } auto closure = OrdinaryFunctionObject::create(global_object, name(), body(), parameters(), function_length(), func_env, kind(), is_strict_mode(), is_arrow_function()); if (has_identifier) func_env->initialize_binding(global_object, name(), closure); return closure; } Value ExpressionStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return m_expression->execute(interpreter, global_object); } CallExpression::ThisAndCallee CallExpression::compute_this_and_callee(Interpreter& interpreter, GlobalObject& global_object) const { auto& vm = interpreter.vm(); if (is(*m_callee)) { auto& member_expression = static_cast(*m_callee); Value callee; Value this_value; if (is(member_expression.object())) { auto super_base = interpreter.current_function_environment()->get_super_base(); if (super_base.is_nullish()) { vm.throw_exception(global_object, ErrorType::ObjectPrototypeNullOrUndefinedOnSuperPropertyAccess, super_base.to_string_without_side_effects()); return {}; } auto property_name = member_expression.computed_property_name(interpreter, global_object); if (!property_name.is_valid()) return {}; auto reference = Reference { super_base, property_name, super_base, vm.in_strict_mode() }; callee = reference.get_value(global_object); if (vm.exception()) return {}; this_value = &vm.this_value(global_object).as_object(); } else { auto reference = member_expression.to_reference(interpreter, global_object); if (vm.exception()) return {}; callee = reference.get_value(global_object); if (vm.exception()) return {}; this_value = reference.get_this_value(); } return { this_value, callee }; } // [[Call]] will handle that in non-strict mode the this value becomes the global object return { js_undefined(), m_callee->execute(interpreter, global_object) }; } // 13.3.8.1 Runtime Semantics: ArgumentListEvaluation, https://tc39.es/ecma262/#sec-runtime-semantics-argumentlistevaluation static void argument_list_evaluation(Interpreter& interpreter, GlobalObject& global_object, Vector const& arguments, MarkedValueList& list) { auto& vm = global_object.vm(); list.ensure_capacity(arguments.size()); for (auto& argument : arguments) { auto value = argument.value->execute(interpreter, global_object); if (vm.exception()) return; if (argument.is_spread) { get_iterator_values(global_object, value, [&](Value iterator_value) { if (vm.exception()) return IterationDecision::Break; list.append(iterator_value); return IterationDecision::Continue; }); if (vm.exception()) return; } else { list.append(value); } } } Value NewExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); auto callee_value = m_callee->execute(interpreter, global_object); if (vm.exception()) return {}; if (!callee_value.is_function() || (is(callee_value.as_object()) && !static_cast(callee_value.as_object()).has_constructor())) { throw_type_error_for_callee(interpreter, global_object, callee_value, "constructor"sv); return {}; } MarkedValueList arg_list(vm.heap()); argument_list_evaluation(interpreter, global_object, m_arguments, arg_list); if (interpreter.exception()) return {}; auto& function = callee_value.as_function(); return vm.construct(function, function, move(arg_list)); } void CallExpression::throw_type_error_for_callee(Interpreter& interpreter, GlobalObject& global_object, Value callee_value, StringView call_type) const { auto& vm = interpreter.vm(); if (is(*m_callee) || is(*m_callee)) { String expression_string; if (is(*m_callee)) { expression_string = static_cast(*m_callee).string(); } else { expression_string = static_cast(*m_callee).to_string_approximation(); } vm.throw_exception(global_object, ErrorType::IsNotAEvaluatedFrom, callee_value.to_string_without_side_effects(), call_type, expression_string); } else { vm.throw_exception(global_object, ErrorType::IsNotA, callee_value.to_string_without_side_effects(), call_type); } } Value CallExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); auto [this_value, callee] = compute_this_and_callee(interpreter, global_object); if (vm.exception()) return {}; VERIFY(!callee.is_empty()); if (!callee.is_function()) { throw_type_error_for_callee(interpreter, global_object, callee, "function"sv); return {}; } MarkedValueList arg_list(vm.heap()); argument_list_evaluation(interpreter, global_object, m_arguments, arg_list); if (interpreter.exception()) return {}; auto& function = callee.as_function(); if (is(*m_callee) && static_cast(*m_callee).string() == vm.names.eval.as_string() && &function == global_object.eval_function()) { auto script_value = arg_list.size() == 0 ? js_undefined() : arg_list[0]; return perform_eval(script_value, global_object, vm.in_strict_mode() ? CallerMode::Strict : CallerMode::NonStrict, EvalMode::Direct); } return vm.call(function, this_value, move(arg_list)); } // 13.3.7.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation // SuperCall : super Arguments Value SuperCall::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); // 1. Let newTarget be GetNewTarget(). auto new_target = vm.get_new_target(); if (vm.exception()) return {}; // 2. Assert: Type(newTarget) is Object. VERIFY(new_target.is_function()); // 3. Let func be ! GetSuperConstructor(). auto* func = get_super_constructor(interpreter.vm()); VERIFY(!vm.exception()); // 4. Let argList be ? ArgumentListEvaluation of Arguments. MarkedValueList arg_list(vm.heap()); argument_list_evaluation(interpreter, global_object, m_arguments, arg_list); if (interpreter.exception()) return {}; // 5. If IsConstructor(func) is false, throw a TypeError exception. // FIXME: This check is non-conforming. if (!func || !func->is_function()) { vm.throw_exception(global_object, ErrorType::NotAConstructor, "Super constructor"); return {}; } // 6. Let result be ? Construct(func, argList, newTarget). auto& function = new_target.as_function(); auto result = vm.construct(static_cast(*func), function, move(arg_list)); if (vm.exception()) return {}; // 7. Let thisER be GetThisEnvironment(). auto& this_er = verify_cast(get_this_environment(interpreter.vm())); // 8. Perform ? thisER.BindThisValue(result). this_er.bind_this_value(global_object, result); if (vm.exception()) return {}; // 9. Let F be thisER.[[FunctionObject]]. // 10. Assert: F is an ECMAScript function object. (NOTE: This is implied by the strong C++ type.) [[maybe_unused]] auto& f = this_er.function_object(); // 11. Perform ? InitializeInstanceElements(result, F). // FIXME: This is missing here. // 12. Return result. return result; } Value YieldExpression::execute(Interpreter&, GlobalObject&) const { // This should be transformed to a return. VERIFY_NOT_REACHED(); } Value ReturnStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto value = argument() ? argument()->execute(interpreter, global_object) : js_undefined(); if (interpreter.exception()) return {}; interpreter.vm().unwind(ScopeType::Function); return value; } Value IfStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto predicate_result = m_predicate->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (predicate_result.to_boolean()) return interpreter.execute_statement(global_object, *m_consequent); if (m_alternate) return interpreter.execute_statement(global_object, *m_alternate); return js_undefined(); } // 14.11.2 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-with-statement-runtime-semantics-evaluation // WithStatement : with ( Expression ) Statement Value WithStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; // 1. Let value be the result of evaluating Expression. auto value = m_object->execute(interpreter, global_object); if (interpreter.exception()) return {}; // 2. Let obj be ? ToObject(? GetValue(value)). auto* object = value.to_object(global_object); if (interpreter.exception()) return {}; // 3. Let oldEnv be the running execution context's LexicalEnvironment. auto* old_environment = interpreter.vm().running_execution_context().lexical_environment; // 4. Let newEnv be NewObjectEnvironment(obj, true, oldEnv). auto* new_environment = new_object_environment(*object, true, old_environment); if (interpreter.exception()) return {}; // 5. Set the running execution context's LexicalEnvironment to newEnv. interpreter.vm().running_execution_context().lexical_environment = new_environment; // 6. Let C be the result of evaluating Statement. auto result = interpreter.execute_statement(global_object, m_body).value_or(js_undefined()); if (interpreter.exception()) return {}; // 7. Set the running execution context's LexicalEnvironment to oldEnv. interpreter.vm().running_execution_context().lexical_environment = old_environment; // 8. Return Completion(UpdateEmpty(C, undefined)). return result; } Value WhileStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto last_value = js_undefined(); for (;;) { auto test_result = m_test->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (!test_result.to_boolean()) break; last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); break; } else { return last_value; } } } return last_value; } Value DoWhileStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto last_value = js_undefined(); for (;;) { if (interpreter.exception()) return {}; last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); break; } else { return last_value; } } auto test_result = m_test->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (!test_result.to_boolean()) break; } return last_value; } Value ForStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; RefPtr wrapper; if (m_init && is(*m_init) && static_cast(*m_init).declaration_kind() != DeclarationKind::Var) { wrapper = create_ast_node(source_range()); NonnullRefPtrVector decls; decls.append(*static_cast(m_init.ptr())); wrapper->add_variables(decls); interpreter.enter_scope(*wrapper, ScopeType::Block, global_object); } auto wrapper_cleanup = ScopeGuard([&] { if (wrapper) interpreter.exit_scope(*wrapper); }); auto last_value = js_undefined(); if (m_init) { m_init->execute(interpreter, global_object); if (interpreter.exception()) return {}; } if (m_test) { while (true) { auto test_result = m_test->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (!test_result.to_boolean()) break; last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); break; } else { return last_value; } } if (m_update) { m_update->execute(interpreter, global_object); if (interpreter.exception()) return {}; } } } else { while (true) { last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); break; } else { return last_value; } } if (m_update) { m_update->execute(interpreter, global_object); if (interpreter.exception()) return {}; } } } return last_value; } static Variant, NonnullRefPtr> variable_from_for_declaration(Interpreter& interpreter, GlobalObject& global_object, ASTNode const& node, RefPtr wrapper) { if (is(node)) { auto& variable_declaration = static_cast(node); VERIFY(!variable_declaration.declarations().is_empty()); if (variable_declaration.declaration_kind() != DeclarationKind::Var) { wrapper = create_ast_node(node.source_range()); interpreter.enter_scope(*wrapper, ScopeType::Block, global_object); } variable_declaration.execute(interpreter, global_object); return variable_declaration.declarations().first().target(); } if (is(node)) { return NonnullRefPtr(static_cast(node)); } VERIFY_NOT_REACHED(); } Value ForInStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; bool has_declaration = is(*m_lhs); if (!has_declaration && !is(*m_lhs)) { // FIXME: Implement "for (foo.bar in baz)", "for (foo[0] in bar)" VERIFY_NOT_REACHED(); } RefPtr wrapper; auto target = variable_from_for_declaration(interpreter, global_object, m_lhs, wrapper); auto wrapper_cleanup = ScopeGuard([&] { if (wrapper) interpreter.exit_scope(*wrapper); }); auto last_value = js_undefined(); auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (rhs_result.is_nullish()) return {}; auto* object = rhs_result.to_object(global_object); while (object) { auto property_names = object->enumerable_own_property_names(Object::PropertyKind::Key); for (auto& value : property_names) { interpreter.vm().assign(target, value, global_object, has_declaration); if (interpreter.exception()) return {}; last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); break; } else { return last_value; } } } object = object->internal_get_prototype_of(); if (interpreter.exception()) return {}; } return last_value; } Value ForOfStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; bool has_declaration = is(*m_lhs); if (!has_declaration && !is(*m_lhs)) { // FIXME: Implement "for (foo.bar of baz)", "for (foo[0] of bar)" VERIFY_NOT_REACHED(); } RefPtr wrapper; auto target = variable_from_for_declaration(interpreter, global_object, m_lhs, wrapper); auto wrapper_cleanup = ScopeGuard([&] { if (wrapper) interpreter.exit_scope(*wrapper); }); auto last_value = js_undefined(); auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; get_iterator_values(global_object, rhs_result, [&](Value value) { interpreter.vm().assign(target, value, global_object, has_declaration); last_value = interpreter.execute_statement(global_object, *m_body).value_or(last_value); if (interpreter.exception()) return IterationDecision::Break; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { interpreter.vm().stop_unwind(); } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); return IterationDecision::Break; } else { return IterationDecision::Break; } } return IterationDecision::Continue; }); if (interpreter.exception()) return {}; return last_value; } Value BinaryExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto lhs_result = m_lhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; switch (m_op) { case BinaryOp::Addition: return add(global_object, lhs_result, rhs_result); case BinaryOp::Subtraction: return sub(global_object, lhs_result, rhs_result); case BinaryOp::Multiplication: return mul(global_object, lhs_result, rhs_result); case BinaryOp::Division: return div(global_object, lhs_result, rhs_result); case BinaryOp::Modulo: return mod(global_object, lhs_result, rhs_result); case BinaryOp::Exponentiation: return exp(global_object, lhs_result, rhs_result); case BinaryOp::TypedEquals: return Value(strict_eq(lhs_result, rhs_result)); case BinaryOp::TypedInequals: return Value(!strict_eq(lhs_result, rhs_result)); case BinaryOp::AbstractEquals: return Value(abstract_eq(global_object, lhs_result, rhs_result)); case BinaryOp::AbstractInequals: return Value(!abstract_eq(global_object, lhs_result, rhs_result)); case BinaryOp::GreaterThan: return greater_than(global_object, lhs_result, rhs_result); case BinaryOp::GreaterThanEquals: return greater_than_equals(global_object, lhs_result, rhs_result); case BinaryOp::LessThan: return less_than(global_object, lhs_result, rhs_result); case BinaryOp::LessThanEquals: return less_than_equals(global_object, lhs_result, rhs_result); case BinaryOp::BitwiseAnd: return bitwise_and(global_object, lhs_result, rhs_result); case BinaryOp::BitwiseOr: return bitwise_or(global_object, lhs_result, rhs_result); case BinaryOp::BitwiseXor: return bitwise_xor(global_object, lhs_result, rhs_result); case BinaryOp::LeftShift: return left_shift(global_object, lhs_result, rhs_result); case BinaryOp::RightShift: return right_shift(global_object, lhs_result, rhs_result); case BinaryOp::UnsignedRightShift: return unsigned_right_shift(global_object, lhs_result, rhs_result); case BinaryOp::In: return in(global_object, lhs_result, rhs_result); case BinaryOp::InstanceOf: return instance_of(global_object, lhs_result, rhs_result); } VERIFY_NOT_REACHED(); } Value LogicalExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto lhs_result = m_lhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; switch (m_op) { case LogicalOp::And: if (lhs_result.to_boolean()) { auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; return rhs_result; } return lhs_result; case LogicalOp::Or: { if (lhs_result.to_boolean()) return lhs_result; auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; return rhs_result; } case LogicalOp::NullishCoalescing: if (lhs_result.is_nullish()) { auto rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; return rhs_result; } return lhs_result; } VERIFY_NOT_REACHED(); } Reference Expression::to_reference(Interpreter&, GlobalObject&) const { return {}; } Reference Identifier::to_reference(Interpreter& interpreter, GlobalObject&) const { return interpreter.vm().resolve_binding(string()); } Reference MemberExpression::to_reference(Interpreter& interpreter, GlobalObject& global_object) const { // 13.3.7.1 Runtime Semantics: Evaluation // SuperProperty : super [ Expression ] // SuperProperty : super . IdentifierName // https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation if (is(object())) { // 1. Let env be GetThisEnvironment(). auto& environment = get_this_environment(interpreter.vm()); // 2. Let actualThis be ? env.GetThisBinding(). auto actual_this = environment.get_this_binding(global_object); StringOrSymbol property_key; if (is_computed()) { // SuperProperty : super [ Expression ] // 3. Let propertyNameReference be the result of evaluating Expression. // 4. Let propertyNameValue be ? GetValue(propertyNameReference). auto property_name_value = m_property->execute(interpreter, global_object); if (interpreter.exception()) return {}; // 5. Let propertyKey be ? ToPropertyKey(propertyNameValue). property_key = property_name_value.to_property_key(global_object); } else { // SuperProperty : super . IdentifierName // 3. Let propertyKey be StringValue of IdentifierName. VERIFY(is(property())); property_key = static_cast(property()).string(); } // 6. If the code matched by this SuperProperty is strict mode code, let strict be true; else let strict be false. bool strict = interpreter.vm().in_strict_mode(); // 7. Return ? MakeSuperPropertyReference(actualThis, propertyKey, strict). return make_super_property_reference(global_object, actual_this, property_key, strict); } auto object_value = m_object->execute(interpreter, global_object); if (interpreter.exception()) return {}; // From here on equivalent to // 13.3.4 EvaluatePropertyAccessWithIdentifierKey ( baseValue, identifierName, strict ), https://tc39.es/ecma262/#sec-evaluate-property-access-with-identifier-key object_value = require_object_coercible(global_object, object_value); if (interpreter.exception()) return {}; auto property_name = computed_property_name(interpreter, global_object); if (!property_name.is_valid()) return Reference {}; auto strict = interpreter.vm().in_strict_mode(); return Reference { object_value, property_name, {}, strict }; } Value UnaryExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); if (m_op == UnaryOp::Delete) { auto reference = m_lhs->to_reference(interpreter, global_object); if (interpreter.exception()) return {}; return Value(reference.delete_(global_object)); } Value lhs_result; if (m_op == UnaryOp::Typeof && is(*m_lhs)) { auto reference = m_lhs->to_reference(interpreter, global_object); if (interpreter.exception()) { return {}; } if (reference.is_unresolvable()) { lhs_result = js_undefined(); } else { lhs_result = reference.get_value(global_object, false); } } else { lhs_result = m_lhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; } switch (m_op) { case UnaryOp::BitwiseNot: return bitwise_not(global_object, lhs_result); case UnaryOp::Not: return Value(!lhs_result.to_boolean()); case UnaryOp::Plus: return unary_plus(global_object, lhs_result); case UnaryOp::Minus: return unary_minus(global_object, lhs_result); case UnaryOp::Typeof: return js_string(vm, lhs_result.typeof()); case UnaryOp::Void: return js_undefined(); case UnaryOp::Delete: VERIFY_NOT_REACHED(); } VERIFY_NOT_REACHED(); } Value SuperExpression::execute(Interpreter&, GlobalObject&) const { // The semantics for SuperExpression are handled in CallExpression and SuperCall. VERIFY_NOT_REACHED(); } Value ClassMethod::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return m_function->execute(interpreter, global_object); } Value ClassExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); Value class_constructor_value = m_constructor->execute(interpreter, global_object); if (interpreter.exception()) return {}; update_function_name(class_constructor_value, m_name); VERIFY(class_constructor_value.is_function() && is(class_constructor_value.as_function())); auto* class_constructor = static_cast(&class_constructor_value.as_function()); class_constructor->set_is_class_constructor(); Value super_constructor = js_undefined(); if (!m_super_class.is_null()) { super_constructor = m_super_class->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (!super_constructor.is_function() && !super_constructor.is_null()) { interpreter.vm().throw_exception(global_object, ErrorType::ClassExtendsValueNotAConstructorOrNull, super_constructor.to_string_without_side_effects()); return {}; } class_constructor->set_constructor_kind(FunctionObject::ConstructorKind::Derived); Object* super_constructor_prototype = nullptr; if (!super_constructor.is_null()) { auto super_constructor_prototype_value = super_constructor.as_object().get(vm.names.prototype); if (interpreter.exception()) return {}; if (!super_constructor_prototype_value.is_object() && !super_constructor_prototype_value.is_null()) { interpreter.vm().throw_exception(global_object, ErrorType::ClassExtendsValueInvalidPrototype, super_constructor_prototype_value.to_string_without_side_effects()); return {}; } if (super_constructor_prototype_value.is_object()) super_constructor_prototype = &super_constructor_prototype_value.as_object(); } auto* prototype = Object::create(global_object, super_constructor_prototype); prototype->define_direct_property(vm.names.constructor, class_constructor, 0); if (interpreter.exception()) return {}; class_constructor->define_direct_property(vm.names.prototype, prototype, Attribute::Writable); if (interpreter.exception()) return {}; class_constructor->internal_set_prototype_of(super_constructor.is_null() ? global_object.function_prototype() : &super_constructor.as_object()); } auto class_prototype = class_constructor->get(vm.names.prototype); if (interpreter.exception()) return {}; if (!class_prototype.is_object()) { interpreter.vm().throw_exception(global_object, ErrorType::NotAnObject, "Class prototype"); return {}; } for (const auto& method : m_methods) { auto method_value = method.execute(interpreter, global_object); if (interpreter.exception()) return {}; auto& method_function = method_value.as_function(); auto key = method.key().execute(interpreter, global_object); if (interpreter.exception()) return {}; auto property_key = key.to_property_key(global_object); if (interpreter.exception()) return {}; auto& target = method.is_static() ? *class_constructor : class_prototype.as_object(); method_function.set_home_object(&target); switch (method.kind()) { case ClassMethod::Kind::Method: target.define_property_or_throw(property_key, { .value = method_value, .writable = true, .enumerable = false, .configurable = true }); break; case ClassMethod::Kind::Getter: update_function_name(method_value, String::formatted("get {}", get_function_name(global_object, key))); target.define_property_or_throw(property_key, { .get = &method_function, .enumerable = true, .configurable = true }); break; case ClassMethod::Kind::Setter: update_function_name(method_value, String::formatted("set {}", get_function_name(global_object, key))); target.define_property_or_throw(property_key, { .set = &method_function, .enumerable = true, .configurable = true }); break; default: VERIFY_NOT_REACHED(); } if (interpreter.exception()) return {}; } return class_constructor; } Value ClassDeclaration::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; Value class_constructor = m_class_expression->execute(interpreter, global_object); if (interpreter.exception()) return {}; interpreter.lexical_environment()->put_into_environment(m_class_expression->name(), { class_constructor, DeclarationKind::Let }); return {}; } static void print_indent(int indent) { out("{}", String::repeated(' ', indent * 2)); } void ASTNode::dump(int indent) const { print_indent(indent); outln("{}", class_name()); } void ScopeNode::dump(int indent) const { ASTNode::dump(indent); if (!m_variables.is_empty()) { print_indent(indent + 1); outln("(Variables)"); for (auto& variable : m_variables) variable.dump(indent + 2); } if (!m_children.is_empty()) { print_indent(indent + 1); outln("(Children)"); for (auto& child : children()) child.dump(indent + 2); } } void BinaryExpression::dump(int indent) const { const char* op_string = nullptr; switch (m_op) { case BinaryOp::Addition: op_string = "+"; break; case BinaryOp::Subtraction: op_string = "-"; break; case BinaryOp::Multiplication: op_string = "*"; break; case BinaryOp::Division: op_string = "/"; break; case BinaryOp::Modulo: op_string = "%"; break; case BinaryOp::Exponentiation: op_string = "**"; break; case BinaryOp::TypedEquals: op_string = "==="; break; case BinaryOp::TypedInequals: op_string = "!=="; break; case BinaryOp::AbstractEquals: op_string = "=="; break; case BinaryOp::AbstractInequals: op_string = "!="; break; case BinaryOp::GreaterThan: op_string = ">"; break; case BinaryOp::GreaterThanEquals: op_string = ">="; break; case BinaryOp::LessThan: op_string = "<"; break; case BinaryOp::LessThanEquals: op_string = "<="; break; case BinaryOp::BitwiseAnd: op_string = "&"; break; case BinaryOp::BitwiseOr: op_string = "|"; break; case BinaryOp::BitwiseXor: op_string = "^"; break; case BinaryOp::LeftShift: op_string = "<<"; break; case BinaryOp::RightShift: op_string = ">>"; break; case BinaryOp::UnsignedRightShift: op_string = ">>>"; break; case BinaryOp::In: op_string = "in"; break; case BinaryOp::InstanceOf: op_string = "instanceof"; break; } print_indent(indent); outln("{}", class_name()); m_lhs->dump(indent + 1); print_indent(indent + 1); outln("{}", op_string); m_rhs->dump(indent + 1); } void LogicalExpression::dump(int indent) const { const char* op_string = nullptr; switch (m_op) { case LogicalOp::And: op_string = "&&"; break; case LogicalOp::Or: op_string = "||"; break; case LogicalOp::NullishCoalescing: op_string = "??"; break; } print_indent(indent); outln("{}", class_name()); m_lhs->dump(indent + 1); print_indent(indent + 1); outln("{}", op_string); m_rhs->dump(indent + 1); } void UnaryExpression::dump(int indent) const { const char* op_string = nullptr; switch (m_op) { case UnaryOp::BitwiseNot: op_string = "~"; break; case UnaryOp::Not: op_string = "!"; break; case UnaryOp::Plus: op_string = "+"; break; case UnaryOp::Minus: op_string = "-"; break; case UnaryOp::Typeof: op_string = "typeof "; break; case UnaryOp::Void: op_string = "void "; break; case UnaryOp::Delete: op_string = "delete "; break; } print_indent(indent); outln("{}", class_name()); print_indent(indent + 1); outln("{}", op_string); m_lhs->dump(indent + 1); } void CallExpression::dump(int indent) const { print_indent(indent); if (is(*this)) outln("CallExpression [new]"); else outln("CallExpression"); m_callee->dump(indent + 1); for (auto& argument : m_arguments) argument.value->dump(indent + 1); } void SuperCall::dump(int indent) const { print_indent(indent); outln("SuperCall"); for (auto& argument : m_arguments) argument.value->dump(indent + 1); } void ClassDeclaration::dump(int indent) const { ASTNode::dump(indent); m_class_expression->dump(indent + 1); } void ClassExpression::dump(int indent) const { print_indent(indent); outln("ClassExpression: \"{}\"", m_name); print_indent(indent); outln("(Constructor)"); m_constructor->dump(indent + 1); if (!m_super_class.is_null()) { print_indent(indent); outln("(Super Class)"); m_super_class->dump(indent + 1); } print_indent(indent); outln("(Methods)"); for (auto& method : m_methods) method.dump(indent + 1); } void ClassMethod::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("(Key)"); m_key->dump(indent + 1); const char* kind_string = nullptr; switch (m_kind) { case Kind::Method: kind_string = "Method"; break; case Kind::Getter: kind_string = "Getter"; break; case Kind::Setter: kind_string = "Setter"; break; } print_indent(indent); outln("Kind: {}", kind_string); print_indent(indent); outln("Static: {}", m_is_static); print_indent(indent); outln("(Function)"); m_function->dump(indent + 1); } void StringLiteral::dump(int indent) const { print_indent(indent); outln("StringLiteral \"{}\"", m_value); } void SuperExpression::dump(int indent) const { print_indent(indent); outln("super"); } void NumericLiteral::dump(int indent) const { print_indent(indent); outln("NumericLiteral {}", m_value); } void BigIntLiteral::dump(int indent) const { print_indent(indent); outln("BigIntLiteral {}", m_value); } void BooleanLiteral::dump(int indent) const { print_indent(indent); outln("BooleanLiteral {}", m_value); } void NullLiteral::dump(int indent) const { print_indent(indent); outln("null"); } void BindingPattern::dump(int indent) const { print_indent(indent); outln("BindingPattern {}", kind == Kind::Array ? "Array" : "Object"); for (auto& entry : entries) { print_indent(indent + 1); outln("(Property)"); if (kind == Kind::Object) { print_indent(indent + 2); outln("(Identifier)"); if (entry.name.has>()) { entry.name.get>()->dump(indent + 3); } else { entry.name.get>()->dump(indent + 3); } } else if (entry.is_elision()) { print_indent(indent + 2); outln("(Elision)"); continue; } print_indent(indent + 2); outln("(Pattern{})", entry.is_rest ? " rest=true" : ""); if (entry.alias.has>()) { entry.alias.get>()->dump(indent + 3); } else if (entry.alias.has>()) { entry.alias.get>()->dump(indent + 3); } else { print_indent(indent + 3); outln(""); } if (entry.initializer) { print_indent(indent + 2); outln("(Initializer)"); entry.initializer->dump(indent + 3); } } } void FunctionNode::dump(int indent, String const& class_name) const { print_indent(indent); outln("{}{} '{}'", class_name, m_kind == FunctionKind::Generator ? "*" : "", name()); if (!m_parameters.is_empty()) { print_indent(indent + 1); outln("(Parameters)"); for (auto& parameter : m_parameters) { print_indent(indent + 2); if (parameter.is_rest) out("..."); parameter.binding.visit( [&](FlyString const& name) { outln("{}", name); }, [&](BindingPattern const& pattern) { pattern.dump(indent + 2); }); if (parameter.default_value) parameter.default_value->dump(indent + 3); } } print_indent(indent + 1); outln("(Body)"); body().dump(indent + 2); } void FunctionDeclaration::dump(int indent) const { FunctionNode::dump(indent, class_name()); } void FunctionExpression::dump(int indent) const { FunctionNode::dump(indent, class_name()); } void YieldExpression::dump(int indent) const { ASTNode::dump(indent); if (argument()) argument()->dump(indent + 1); } void ReturnStatement::dump(int indent) const { ASTNode::dump(indent); if (argument()) argument()->dump(indent + 1); } void IfStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("If"); predicate().dump(indent + 1); consequent().dump(indent + 1); if (alternate()) { print_indent(indent); outln("Else"); alternate()->dump(indent + 1); } } void WhileStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("While"); test().dump(indent + 1); body().dump(indent + 1); } void WithStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); outln("Object"); object().dump(indent + 2); print_indent(indent + 1); outln("Body"); body().dump(indent + 2); } void DoWhileStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("DoWhile"); test().dump(indent + 1); body().dump(indent + 1); } void ForStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("For"); if (init()) init()->dump(indent + 1); if (test()) test()->dump(indent + 1); if (update()) update()->dump(indent + 1); body().dump(indent + 1); } void ForInStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("ForIn"); lhs().dump(indent + 1); rhs().dump(indent + 1); body().dump(indent + 1); } void ForOfStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("ForOf"); lhs().dump(indent + 1); rhs().dump(indent + 1); body().dump(indent + 1); } Value Identifier::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto value = interpreter.vm().get_variable(string(), global_object); if (interpreter.exception()) return {}; if (value.is_empty()) { interpreter.vm().throw_exception(global_object, ErrorType::UnknownIdentifier, string()); return {}; } return value; } void Identifier::dump(int indent) const { print_indent(indent); outln("Identifier \"{}\"", m_string); } void SpreadExpression::dump(int indent) const { ASTNode::dump(indent); m_target->dump(indent + 1); } Value SpreadExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return m_target->execute(interpreter, global_object); } Value ThisExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; return interpreter.vm().resolve_this_binding(global_object); } void ThisExpression::dump(int indent) const { ASTNode::dump(indent); } Value AssignmentExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; #define EXECUTE_LHS() \ do { \ if (auto* ptr = m_lhs.get_pointer>()) { \ lhs_result = (*ptr)->execute(interpreter, global_object); \ if (interpreter.exception()) \ return {}; \ } \ } while (0) #define EXECUTE_LHS_AND_RHS() \ do { \ EXECUTE_LHS(); \ rhs_result = m_rhs->execute(interpreter, global_object); \ if (interpreter.exception()) \ return {}; \ } while (0) Value lhs_result; Value rhs_result; switch (m_op) { case AssignmentOp::Assignment: break; case AssignmentOp::AdditionAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = add(global_object, lhs_result, rhs_result); break; case AssignmentOp::SubtractionAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = sub(global_object, lhs_result, rhs_result); break; case AssignmentOp::MultiplicationAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = mul(global_object, lhs_result, rhs_result); break; case AssignmentOp::DivisionAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = div(global_object, lhs_result, rhs_result); break; case AssignmentOp::ModuloAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = mod(global_object, lhs_result, rhs_result); break; case AssignmentOp::ExponentiationAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = exp(global_object, lhs_result, rhs_result); break; case AssignmentOp::BitwiseAndAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = bitwise_and(global_object, lhs_result, rhs_result); break; case AssignmentOp::BitwiseOrAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = bitwise_or(global_object, lhs_result, rhs_result); break; case AssignmentOp::BitwiseXorAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = bitwise_xor(global_object, lhs_result, rhs_result); break; case AssignmentOp::LeftShiftAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = left_shift(global_object, lhs_result, rhs_result); break; case AssignmentOp::RightShiftAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = right_shift(global_object, lhs_result, rhs_result); break; case AssignmentOp::UnsignedRightShiftAssignment: EXECUTE_LHS_AND_RHS(); rhs_result = unsigned_right_shift(global_object, lhs_result, rhs_result); break; case AssignmentOp::AndAssignment: EXECUTE_LHS(); if (!lhs_result.to_boolean()) return lhs_result; rhs_result = m_rhs->execute(interpreter, global_object); break; case AssignmentOp::OrAssignment: EXECUTE_LHS(); if (lhs_result.to_boolean()) return lhs_result; rhs_result = m_rhs->execute(interpreter, global_object); break; case AssignmentOp::NullishAssignment: EXECUTE_LHS(); if (!lhs_result.is_nullish()) return lhs_result; rhs_result = m_rhs->execute(interpreter, global_object); break; } if (interpreter.exception()) return {}; return m_lhs.visit( [&](NonnullRefPtr& lhs) -> JS::Value { auto reference = lhs->to_reference(interpreter, global_object); if (interpreter.exception()) return {}; if (m_op == AssignmentOp::Assignment) { rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; } if (reference.is_unresolvable()) { interpreter.vm().throw_exception(global_object, ErrorType::InvalidLeftHandAssignment); return {}; } reference.put_value(global_object, rhs_result); if (interpreter.exception()) return {}; return rhs_result; }, [&](NonnullRefPtr& pattern) -> JS::Value { VERIFY(m_op == AssignmentOp::Assignment); rhs_result = m_rhs->execute(interpreter, global_object); if (interpreter.exception()) return {}; interpreter.vm().assign(pattern, rhs_result, global_object); if (interpreter.exception()) return {}; return rhs_result; }); } Value UpdateExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto reference = m_argument->to_reference(interpreter, global_object); if (interpreter.exception()) return {}; auto old_value = reference.get_value(global_object); if (interpreter.exception()) return {}; old_value = old_value.to_numeric(global_object); if (interpreter.exception()) return {}; Value new_value; switch (m_op) { case UpdateOp::Increment: if (old_value.is_number()) new_value = Value(old_value.as_double() + 1); else new_value = js_bigint(interpreter.heap(), old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 })); break; case UpdateOp::Decrement: if (old_value.is_number()) new_value = Value(old_value.as_double() - 1); else new_value = js_bigint(interpreter.heap(), old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 })); break; default: VERIFY_NOT_REACHED(); } reference.put_value(global_object, new_value); if (interpreter.exception()) return {}; return m_prefixed ? new_value : old_value; } void AssignmentExpression::dump(int indent) const { const char* op_string = nullptr; switch (m_op) { case AssignmentOp::Assignment: op_string = "="; break; case AssignmentOp::AdditionAssignment: op_string = "+="; break; case AssignmentOp::SubtractionAssignment: op_string = "-="; break; case AssignmentOp::MultiplicationAssignment: op_string = "*="; break; case AssignmentOp::DivisionAssignment: op_string = "/="; break; case AssignmentOp::ModuloAssignment: op_string = "%="; break; case AssignmentOp::ExponentiationAssignment: op_string = "**="; break; case AssignmentOp::BitwiseAndAssignment: op_string = "&="; break; case AssignmentOp::BitwiseOrAssignment: op_string = "|="; break; case AssignmentOp::BitwiseXorAssignment: op_string = "^="; break; case AssignmentOp::LeftShiftAssignment: op_string = "<<="; break; case AssignmentOp::RightShiftAssignment: op_string = ">>="; break; case AssignmentOp::UnsignedRightShiftAssignment: op_string = ">>>="; break; case AssignmentOp::AndAssignment: op_string = "&&="; break; case AssignmentOp::OrAssignment: op_string = "||="; break; case AssignmentOp::NullishAssignment: op_string = "\?\?="; break; } ASTNode::dump(indent); print_indent(indent + 1); outln("{}", op_string); m_lhs.visit([&](auto& lhs) { lhs->dump(indent + 1); }); m_rhs->dump(indent + 1); } void UpdateExpression::dump(int indent) const { const char* op_string = nullptr; switch (m_op) { case UpdateOp::Increment: op_string = "++"; break; case UpdateOp::Decrement: op_string = "--"; break; } ASTNode::dump(indent); if (m_prefixed) { print_indent(indent + 1); outln("{}", op_string); } m_argument->dump(indent + 1); if (!m_prefixed) { print_indent(indent + 1); outln("{}", op_string); } } Value VariableDeclaration::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; for (auto& declarator : m_declarations) { if (auto* init = declarator.init()) { auto initializer_result = init->execute(interpreter, global_object); if (interpreter.exception()) return {}; declarator.target().visit( [&](NonnullRefPtr const& id) { auto variable_name = id->string(); if (is(*init)) update_function_name(initializer_result, variable_name); interpreter.vm().set_variable(variable_name, initializer_result, global_object, true); }, [&](NonnullRefPtr const& pattern) { interpreter.vm().assign(pattern, initializer_result, global_object, true); }); } } return {}; } Value VariableDeclarator::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; // NOTE: VariableDeclarator execution is handled by VariableDeclaration. VERIFY_NOT_REACHED(); } void VariableDeclaration::dump(int indent) const { const char* declaration_kind_string = nullptr; switch (m_declaration_kind) { case DeclarationKind::Let: declaration_kind_string = "Let"; break; case DeclarationKind::Var: declaration_kind_string = "Var"; break; case DeclarationKind::Const: declaration_kind_string = "Const"; break; } ASTNode::dump(indent); print_indent(indent + 1); outln("{}", declaration_kind_string); for (auto& declarator : m_declarations) declarator.dump(indent + 1); } void VariableDeclarator::dump(int indent) const { ASTNode::dump(indent); m_target.visit([indent](const auto& value) { value->dump(indent + 1); }); if (m_init) m_init->dump(indent + 1); } void ObjectProperty::dump(int indent) const { ASTNode::dump(indent); m_key->dump(indent + 1); m_value->dump(indent + 1); } void ObjectExpression::dump(int indent) const { ASTNode::dump(indent); for (auto& property : m_properties) { property.dump(indent + 1); } } void ExpressionStatement::dump(int indent) const { ASTNode::dump(indent); m_expression->dump(indent + 1); } Value ObjectProperty::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; // NOTE: ObjectProperty execution is handled by ObjectExpression. VERIFY_NOT_REACHED(); } Value ObjectExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto* object = Object::create(global_object, global_object.object_prototype()); for (auto& property : m_properties) { auto key = property.key().execute(interpreter, global_object); if (interpreter.exception()) return {}; if (property.type() == ObjectProperty::Type::Spread) { if (key.is_object() && is(key.as_object())) { auto& array_to_spread = static_cast(key.as_object()); for (auto& entry : array_to_spread.indexed_properties()) { auto value = array_to_spread.get(entry.index()); if (interpreter.exception()) return {}; object->indexed_properties().put(entry.index(), value); if (interpreter.exception()) return {}; } } else if (key.is_object()) { auto& obj_to_spread = key.as_object(); for (auto& it : obj_to_spread.shape().property_table_ordered()) { if (it.value.attributes.is_enumerable()) { object->define_direct_property(it.key, obj_to_spread.get(it.key), JS::default_attributes); if (interpreter.exception()) return {}; } } } else if (key.is_string()) { auto& str_to_spread = key.as_string().string(); for (size_t i = 0; i < str_to_spread.length(); i++) { object->define_direct_property(i, js_string(interpreter.heap(), str_to_spread.substring(i, 1)), JS::default_attributes); if (interpreter.exception()) return {}; } } continue; } auto value = property.value().execute(interpreter, global_object); if (interpreter.exception()) return {}; if (value.is_function() && property.is_method()) value.as_function().set_home_object(object); String name = get_function_name(global_object, key); if (property.type() == ObjectProperty::Type::Getter) { name = String::formatted("get {}", name); } else if (property.type() == ObjectProperty::Type::Setter) { name = String::formatted("set {}", name); } update_function_name(value, name); switch (property.type()) { case ObjectProperty::Type::Getter: VERIFY(value.is_function()); object->define_direct_accessor(PropertyName::from_value(global_object, key), &value.as_function(), nullptr, Attribute::Configurable | Attribute::Enumerable); break; case ObjectProperty::Type::Setter: VERIFY(value.is_function()); object->define_direct_accessor(PropertyName::from_value(global_object, key), nullptr, &value.as_function(), Attribute::Configurable | Attribute::Enumerable); break; case ObjectProperty::Type::KeyValue: object->define_direct_property(PropertyName::from_value(global_object, key), value, JS::default_attributes); break; case ObjectProperty::Type::Spread: default: VERIFY_NOT_REACHED(); } if (interpreter.exception()) return {}; } return object; } void MemberExpression::dump(int indent) const { print_indent(indent); outln("{}(computed={})", class_name(), is_computed()); m_object->dump(indent + 1); m_property->dump(indent + 1); } PropertyName MemberExpression::computed_property_name(Interpreter& interpreter, GlobalObject& global_object) const { if (!is_computed()) return verify_cast(*m_property).string(); auto value = m_property->execute(interpreter, global_object); if (interpreter.exception()) return {}; VERIFY(!value.is_empty()); return PropertyName::from_value(global_object, value); } String MemberExpression::to_string_approximation() const { String object_string = ""; if (is(*m_object)) object_string = static_cast(*m_object).string(); if (is_computed()) return String::formatted("{}[]", object_string); return String::formatted("{}.{}", object_string, verify_cast(*m_property).string()); } Value MemberExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto reference = to_reference(interpreter, global_object); if (interpreter.exception()) return {}; return reference.get_value(global_object); } void MetaProperty::dump(int indent) const { String name; if (m_type == MetaProperty::Type::NewTarget) name = "new.target"; else if (m_type == MetaProperty::Type::ImportMeta) name = "import.meta"; else VERIFY_NOT_REACHED(); print_indent(indent); outln("{} {}", class_name(), name); } Value MetaProperty::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; if (m_type == MetaProperty::Type::NewTarget) return interpreter.vm().get_new_target().value_or(js_undefined()); if (m_type == MetaProperty::Type::ImportMeta) TODO(); VERIFY_NOT_REACHED(); } Value StringLiteral::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; return js_string(interpreter.heap(), m_value); } Value NumericLiteral::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; return Value(m_value); } Value BigIntLiteral::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; Crypto::SignedBigInteger integer; if (m_value[0] == '0' && m_value.length() >= 3) { if (m_value[1] == 'x' || m_value[1] == 'X') { return js_bigint(interpreter.heap(), Crypto::SignedBigInteger::from_base(16, m_value.substring(2, m_value.length() - 3))); } else if (m_value[1] == 'o' || m_value[1] == 'O') { return js_bigint(interpreter.heap(), Crypto::SignedBigInteger::from_base(8, m_value.substring(2, m_value.length() - 3))); } else if (m_value[1] == 'b' || m_value[1] == 'B') { return js_bigint(interpreter.heap(), Crypto::SignedBigInteger::from_base(2, m_value.substring(2, m_value.length() - 3))); } } return js_bigint(interpreter.heap(), Crypto::SignedBigInteger::from_base(10, m_value.substring(0, m_value.length() - 1))); } Value BooleanLiteral::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; return Value(m_value); } Value NullLiteral::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; return js_null(); } void RegExpLiteral::dump(int indent) const { print_indent(indent); outln("{} (/{}/{})", class_name(), pattern(), flags()); } Value RegExpLiteral::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; Regex regex(parsed_regex(), parsed_pattern(), parsed_flags()); return RegExpObject::create(global_object, move(regex), pattern(), flags()); } void ArrayExpression::dump(int indent) const { ASTNode::dump(indent); for (auto& element : m_elements) { if (element) { element->dump(indent + 1); } else { print_indent(indent + 1); outln(""); } } } Value ArrayExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto* array = Array::create(global_object, 0); for (auto& element : m_elements) { auto value = Value(); if (element) { value = element->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (is(*element)) { get_iterator_values(global_object, value, [&](Value iterator_value) { array->indexed_properties().append(iterator_value); return IterationDecision::Continue; }); if (interpreter.exception()) return {}; continue; } } array->indexed_properties().append(value); } return array; } void TemplateLiteral::dump(int indent) const { ASTNode::dump(indent); for (auto& expression : m_expressions) expression.dump(indent + 1); } Value TemplateLiteral::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; StringBuilder string_builder; for (auto& expression : m_expressions) { auto expr = expression.execute(interpreter, global_object); if (interpreter.exception()) return {}; auto string = expr.to_string(global_object); if (interpreter.exception()) return {}; string_builder.append(string); } return js_string(interpreter.heap(), string_builder.build()); } void TaggedTemplateLiteral::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); outln("(Tag)"); m_tag->dump(indent + 2); print_indent(indent + 1); outln("(Template Literal)"); m_template_literal->dump(indent + 2); } Value TaggedTemplateLiteral::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto& vm = interpreter.vm(); auto tag = m_tag->execute(interpreter, global_object); if (vm.exception()) return {}; if (!tag.is_function()) { vm.throw_exception(global_object, ErrorType::NotAFunction, tag.to_string_without_side_effects()); return {}; } auto& tag_function = tag.as_function(); auto& expressions = m_template_literal->expressions(); auto* strings = Array::create(global_object, 0); MarkedValueList arguments(vm.heap()); arguments.append(strings); for (size_t i = 0; i < expressions.size(); ++i) { auto value = expressions[i].execute(interpreter, global_object); if (vm.exception()) return {}; // tag`${foo}` -> "", foo, "" -> tag(["", ""], foo) // tag`foo${bar}baz${qux}` -> "foo", bar, "baz", qux, "" -> tag(["foo", "baz", ""], bar, qux) if (i % 2 == 0) { strings->indexed_properties().append(value); } else { arguments.append(value); } } auto* raw_strings = Array::create(global_object, 0); for (auto& raw_string : m_template_literal->raw_strings()) { auto value = raw_string.execute(interpreter, global_object); if (vm.exception()) return {}; raw_strings->indexed_properties().append(value); } strings->define_direct_property(vm.names.raw, raw_strings, 0); return vm.call(tag_function, js_undefined(), move(arguments)); } void TryStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent); outln("(Block)"); block().dump(indent + 1); if (handler()) { print_indent(indent); outln("(Handler)"); handler()->dump(indent + 1); } if (finalizer()) { print_indent(indent); outln("(Finalizer)"); finalizer()->dump(indent + 1); } } void CatchClause::dump(int indent) const { print_indent(indent); m_parameter.visit( [&](FlyString const& parameter) { if (parameter.is_null()) outln("CatchClause"); else outln("CatchClause ({})", parameter); }, [&](NonnullRefPtr const& pattern) { outln("CatchClause"); print_indent(indent); outln("(Parameter)"); pattern->dump(indent + 2); }); body().dump(indent + 1); } void ThrowStatement::dump(int indent) const { ASTNode::dump(indent); argument().dump(indent + 1); } Value TryStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto result = interpreter.execute_statement(global_object, m_block, ScopeType::Try); if (auto* exception = interpreter.exception()) { if (m_handler) { interpreter.vm().clear_exception(); HashMap parameters; m_handler->parameter().visit( [&](FlyString const& parameter) { parameters.set(parameter, Variable { exception->value(), DeclarationKind::Var }); }, [&](NonnullRefPtr const& pattern) { pattern->for_each_bound_name([&](auto& name) { parameters.set(name, Variable { Value {}, DeclarationKind::Var }); }); }); auto* catch_scope = interpreter.heap().allocate(global_object, move(parameters), interpreter.vm().running_execution_context().lexical_environment); TemporaryChange scope_change(interpreter.vm().running_execution_context().lexical_environment, catch_scope); if (auto* pattern = m_handler->parameter().get_pointer>()) interpreter.vm().assign(*pattern, exception->value(), global_object, true); if (interpreter.exception()) result = js_undefined(); else result = interpreter.execute_statement(global_object, m_handler->body()); } } if (m_finalizer) { // Keep, if any, and then clear the current exception so we can // execute() the finalizer without an exception in our way. auto* previous_exception = interpreter.exception(); interpreter.vm().clear_exception(); // Remember what scope type we were unwinding to, and temporarily // clear it as well (e.g. return from handler). auto unwind_until = interpreter.vm().unwind_until(); interpreter.vm().stop_unwind(); auto finalizer_result = m_finalizer->execute(interpreter, global_object); if (interpreter.vm().should_unwind()) { // This was NOT a 'normal' completion (e.g. return from finalizer). result = finalizer_result; } else { // Continue unwinding to whatever we found ourselves unwinding // to when the finalizer was entered (e.g. return from handler, // which is unaffected by normal completion from finalizer). interpreter.vm().unwind(unwind_until); // If we previously had an exception and the finalizer didn't // throw a new one, restore the old one. if (previous_exception && !interpreter.exception()) interpreter.vm().set_exception(*previous_exception); } } return result.value_or(js_undefined()); } Value CatchClause::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; // NOTE: CatchClause execution is handled by TryStatement. VERIFY_NOT_REACHED(); return {}; } Value ThrowStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto value = m_argument->execute(interpreter, global_object); if (interpreter.vm().exception()) return {}; interpreter.vm().throw_exception(global_object, value); return {}; } Value SwitchStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto discriminant_result = m_discriminant->execute(interpreter, global_object); if (interpreter.exception()) return {}; bool falling_through = false; auto last_value = js_undefined(); for (auto& switch_case : m_cases) { if (!falling_through && switch_case.test()) { auto test_result = switch_case.test()->execute(interpreter, global_object); if (interpreter.exception()) return {}; if (!strict_eq(discriminant_result, test_result)) continue; } falling_through = true; for (auto& statement : switch_case.consequent()) { auto value = statement.execute(interpreter, global_object); if (!value.is_empty()) last_value = value; if (interpreter.exception()) return {}; if (interpreter.vm().should_unwind()) { if (interpreter.vm().should_unwind_until(ScopeType::Continuable, m_label)) { // No stop_unwind(), the outer loop will handle that - we just need to break out of the switch/case. return last_value; } else if (interpreter.vm().should_unwind_until(ScopeType::Breakable, m_label)) { interpreter.vm().stop_unwind(); return last_value; } else { return last_value; } } } } return last_value; } Value SwitchCase::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; // NOTE: SwitchCase execution is handled by SwitchStatement. VERIFY_NOT_REACHED(); return {}; } Value BreakStatement::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; interpreter.vm().unwind(ScopeType::Breakable, m_target_label); return {}; } Value ContinueStatement::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; interpreter.vm().unwind(ScopeType::Continuable, m_target_label); return {}; } void SwitchStatement::dump(int indent) const { ASTNode::dump(indent); m_discriminant->dump(indent + 1); for (auto& switch_case : m_cases) { switch_case.dump(indent + 1); } } void SwitchCase::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); if (m_test) { outln("(Test)"); m_test->dump(indent + 2); } else { outln("(Default)"); } print_indent(indent + 1); outln("(Consequent)"); for (auto& statement : m_consequent) statement.dump(indent + 2); } Value ConditionalExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; auto test_result = m_test->execute(interpreter, global_object); if (interpreter.exception()) return {}; Value result; if (test_result.to_boolean()) { result = m_consequent->execute(interpreter, global_object); } else { result = m_alternate->execute(interpreter, global_object); } if (interpreter.exception()) return {}; return result; } void ConditionalExpression::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); outln("(Test)"); m_test->dump(indent + 2); print_indent(indent + 1); outln("(Consequent)"); m_consequent->dump(indent + 2); print_indent(indent + 1); outln("(Alternate)"); m_alternate->dump(indent + 2); } void SequenceExpression::dump(int indent) const { ASTNode::dump(indent); for (auto& expression : m_expressions) expression.dump(indent + 1); } Value SequenceExpression::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; Value last_value; for (auto& expression : m_expressions) { last_value = expression.execute(interpreter, global_object); if (interpreter.exception()) return {}; } return last_value; } Value DebuggerStatement::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; // Sorry, no JavaScript debugger available (yet)! return {}; } void ScopeNode::add_variables(NonnullRefPtrVector variables) { m_variables.extend(move(variables)); } void ScopeNode::add_functions(NonnullRefPtrVector functions) { m_functions.extend(move(functions)); } void ScopeNode::add_hoisted_function(NonnullRefPtr hoisted_function) { m_hoisted_functions.append(hoisted_function); } Value ImportStatement::execute(Interpreter& interpreter, GlobalObject&) const { InterpreterNodeScope node_scope { interpreter, *this }; dbgln("Modules are not fully supported yet!"); TODO(); return {}; } Value ExportStatement::execute(Interpreter& interpreter, GlobalObject& global_object) const { InterpreterNodeScope node_scope { interpreter, *this }; if (m_statement) return m_statement->execute(interpreter, global_object); return {}; } void ExportStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); outln("(ExportEntries)"); auto string_or_null = [](String const& string) -> String { if (string.is_empty()) { return "null"; } return String::formatted("\"{}\"", string); }; for (auto& entry : m_entries) { print_indent(indent + 2); outln("ModuleRequest: {}, ImportName: {}, LocalName: {}, ExportName: {}", string_or_null(entry.module_request), entry.kind == ExportEntry::ModuleRequest ? string_or_null(entry.local_or_import_name) : "null", entry.kind != ExportEntry::ModuleRequest ? string_or_null(entry.local_or_import_name) : "null", string_or_null(entry.export_name)); } } void ImportStatement::dump(int indent) const { ASTNode::dump(indent); print_indent(indent + 1); if (m_entries.is_empty()) { // direct from "module" import outln("Entire module '{}'", m_module_request); } else { outln("(ExportEntries) from {}", m_module_request); for (auto& entry : m_entries) { print_indent(indent + 2); outln("ImportName: {}, LocalName: {}", entry.import_name, entry.local_name); } } } bool ExportStatement::has_export(StringView export_name) const { return any_of(m_entries.begin(), m_entries.end(), [&](auto& entry) { return entry.export_name == export_name; }); } bool ImportStatement::has_bound_name(StringView name) const { return any_of(m_entries.begin(), m_entries.end(), [&](auto& entry) { return entry.local_name == name; }); } }