ladybird/Userland/Libraries/LibJS/CyclicModule.cpp
Andreas Kling 4b1053e327 LibJS: Fix logic typo in CyclicModule::inner_module_linking()
The comment was right, but the code didn't match.
2023-12-03 20:46:55 +01:00

919 lines
39 KiB
C++

/*
* Copyright (c) 2022, David Tuin <davidot@serenityos.org>
* Copyright (c) 2023, networkException <networkexception@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Debug.h>
#include <AK/TypeCasts.h>
#include <LibJS/CyclicModule.h>
#include <LibJS/Runtime/ModuleRequest.h>
#include <LibJS/Runtime/PromiseCapability.h>
#include <LibJS/Runtime/PromiseConstructor.h>
#include <LibJS/Runtime/VM.h>
namespace JS {
JS_DEFINE_ALLOCATOR(CyclicModule);
CyclicModule::CyclicModule(Realm& realm, StringView filename, bool has_top_level_await, Vector<ModuleRequest> requested_modules, Script::HostDefined* host_defined)
: Module(realm, filename, host_defined)
, m_requested_modules(move(requested_modules))
, m_has_top_level_await(has_top_level_await)
{
}
void CyclicModule::visit_edges(Cell::Visitor& visitor)
{
Base::visit_edges(visitor);
visitor.visit(m_cycle_root);
visitor.visit(m_top_level_capability);
for (auto const& module : m_async_parent_modules)
visitor.visit(module);
for (auto const& loaded_module : m_loaded_modules)
visitor.visit(loaded_module.module);
}
void GraphLoadingState::visit_edges(Cell::Visitor& visitor)
{
Base::visit_edges(visitor);
visitor.visit(promise_capability);
visitor.visit(host_defined);
for (auto* module : visited)
visitor.visit(*module);
}
// 16.2.1.5.1 LoadRequestedModules ( [ hostDefined ] ), https://tc39.es/ecma262/#sec-LoadRequestedModules
PromiseCapability& CyclicModule::load_requested_modules(GCPtr<GraphLoadingState::HostDefined> host_defined)
{
// 1. If hostDefined is not present, let hostDefined be EMPTY.
// NOTE: The empty state is handled by hostDefined being an optional without value.
// 2. Let pc be ! NewPromiseCapability(%Promise%).
auto promise_capability = MUST(new_promise_capability(vm(), vm().current_realm()->intrinsics().promise_constructor()));
// 3. Let state be the GraphLoadingState Record { [[IsLoading]]: true, [[PendingModulesCount]]: 1, [[Visited]]: « », [[PromiseCapability]]: pc, [[HostDefined]]: hostDefined }.
auto state = heap().allocate_without_realm<GraphLoadingState>(promise_capability, true, 1, HashTable<CyclicModule*> {}, move(host_defined));
// 4. Perform InnerModuleLoading(state, module).
inner_module_loading(state);
// NOTE: This is likely a spec bug, see https://matrixlogs.bakkot.com/WHATWG/2023-02-13#L1
// FIXME: 5. Return pc.[[Promise]].
return promise_capability;
}
// 16.2.1.5.1.1 InnerModuleLoading ( state, module ), https://tc39.es/ecma262/#sec-InnerModuleLoading
void CyclicModule::inner_module_loading(JS::GraphLoadingState& state)
{
// 1. Assert: state.[[IsLoading]] is true.
VERIFY(state.is_loading);
// 2. If module is a Cyclic Module Record, module.[[Status]] is NEW, and state.[[Visited]] does not contain module, then
if (m_status == ModuleStatus::New && !state.visited.contains(this)) {
// a. Append module to state.[[Visited]].
state.visited.set(this);
// b. Let requestedModulesCount be the number of elements in module.[[RequestedModules]].
auto requested_modules_count = m_requested_modules.size();
// c. Set state.[[PendingModulesCount]] to state.[[PendingModulesCount]] + requestedModulesCount.
state.pending_module_count += requested_modules_count;
// d. For each String required of module.[[RequestedModules]], do
for (auto const& required : m_requested_modules) {
bool found_record_in_loaded_modules = false;
// i. If module.[[LoadedModules]] contains a Record whose [[Specifier]] is required, then
for (auto const& record : m_loaded_modules) {
if (record.specifier == required.module_specifier) {
// 1. Let record be that Record.
// 2. Perform InnerModuleLoading(state, record.[[Module]]).
static_cast<CyclicModule&>(*record.module).inner_module_loading(state);
found_record_in_loaded_modules = true;
break;
}
}
// ii. Else,
if (!found_record_in_loaded_modules) {
// 1. Perform HostLoadImportedModule(module, required, state.[[HostDefined]], state).
vm().host_load_imported_module(NonnullGCPtr<CyclicModule> { *this }, required, state.host_defined, NonnullGCPtr<GraphLoadingState> { state });
// 2. NOTE: HostLoadImportedModule will call FinishLoadingImportedModule, which re-enters the graph loading process through ContinueModuleLoading.
}
// iii. If state.[[IsLoading]] is false, return UNUSED.
if (!state.is_loading)
return;
}
}
// 3. Assert: state.[[PendingModulesCount]] ≥ 1.
VERIFY(state.pending_module_count >= 1);
// 4. Set state.[[PendingModulesCount]] to state.[[PendingModulesCount]] - 1.
--state.pending_module_count;
// 5. If state.[[PendingModulesCount]] = 0, then
if (state.pending_module_count == 0) {
// a. Set state.[[IsLoading]] to false.
state.is_loading = false;
// b. For each Cyclic Module Record loaded of state.[[Visited]], do
for (auto const& loaded : state.visited) {
// i. If loaded.[[Status]] is NEW, set loaded.[[Status]] to UNLINKED.
if (loaded->m_status == ModuleStatus::New)
loaded->m_status = ModuleStatus::Unlinked;
}
// c. Perform ! Call(state.[[PromiseCapability]].[[Resolve]], undefined, « undefined »).
MUST(call(vm(), *state.promise_capability->resolve(), js_undefined(), js_undefined()));
}
// 6. Return unused.
}
// 16.2.1.5.1.2 ContinueModuleLoading ( state, moduleCompletion ), https://tc39.es/ecma262/#sec-ContinueModuleLoading
void continue_module_loading(GraphLoadingState& state, ThrowCompletionOr<NonnullGCPtr<Module>> const& module_completion)
{
// 1. If state.[[IsLoading]] is false, return UNUSED.
if (state.is_loading)
return;
// 2. If moduleCompletion is a normal completion, then
if (!module_completion.is_error()) {
auto module = module_completion.value();
// a. Perform InnerModuleLoading(state, moduleCompletion.[[Value]]).
verify_cast<CyclicModule>(*module).inner_module_loading(state);
}
// 3. Else,
else {
// a. Set state.[[IsLoading]] to false.
state.is_loading = false;
auto value = module_completion.throw_completion().value();
// b. Perform ! Call(state.[[PromiseCapability]].[[Reject]], undefined, « moduleCompletion.[[Value]] »).
MUST(call(state.vm(), *state.promise_capability->reject(), js_undefined(), *value));
}
// 4. Return UNUSED.
}
// 16.2.1.5.1 Link ( ), https://tc39.es/ecma262/#sec-moduledeclarationlinking
ThrowCompletionOr<void> CyclicModule::link(VM& vm)
{
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] link[{}]()", this);
// 1. Assert: module.[[Status]] is not linking or evaluating.
VERIFY(m_status != ModuleStatus::Linking);
VERIFY(m_status != ModuleStatus::Evaluating);
// 2. Let stack be a new empty List.
Vector<Module*> stack;
// 3. Let result be Completion(InnerModuleLinking(module, stack, 0)).
auto result = inner_module_linking(vm, stack, 0);
// 4. If result is an abrupt completion, then
if (result.is_throw_completion()) {
// a. For each Cyclic Module Record m of stack, do
for (auto* module : stack) {
if (is<CyclicModule>(module)) {
auto& cyclic_module = static_cast<CyclicModule&>(*module);
// i. Assert: m.[[Status]] is linking.
VERIFY(cyclic_module.m_status == ModuleStatus::Linking);
// ii. Set m.[[Status]] to unlinked.
cyclic_module.m_status = ModuleStatus::Unlinked;
}
}
// b. Assert: module.[[Status]] is unlinked.
VERIFY(m_status == ModuleStatus::Unlinked);
// c. Return result.
return result.release_error();
}
// 5. Assert: module.[[Status]] is linked, evaluating-async, or evaluated.
VERIFY(m_status == ModuleStatus::Linked || m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated);
// 6. Assert: stack is empty.
VERIFY(stack.is_empty());
// 7. Return unused.
return {};
}
// 16.2.1.5.1.1 InnerModuleLinking ( module, stack, index ), https://tc39.es/ecma262/#sec-InnerModuleLinking
ThrowCompletionOr<u32> CyclicModule::inner_module_linking(VM& vm, Vector<Module*>& stack, u32 index)
{
// 1. If module is not a Cyclic Module Record, then
// a. Perform ? module.Link().
// b. Return index.
// Note: Step 1, 1.a and 1.b are handled in Module.cpp
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] inner_module_linking[{}](vm, {}, {})", this, DeprecatedString::join(',', stack), index);
// 2. If module.[[Status]] is linking, linked, evaluating-async, or evaluated, then
if (m_status == ModuleStatus::Linking || m_status == ModuleStatus::Linked || m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated) {
// a. Return index.
return index;
}
// 3. Assert: module.[[Status]] is unlinked.
VERIFY(m_status == ModuleStatus::Unlinked);
// 4. Set module.[[Status]] to linking.
m_status = ModuleStatus::Linking;
// 5. Set module.[[DFSIndex]] to index.
m_dfs_index = index;
// 6. Set module.[[DFSAncestorIndex]] to index.
m_dfs_ancestor_index = index;
// 7. Set index to index + 1.
++index;
// 8. Append module to stack.
stack.append(this);
#if JS_MODULE_DEBUG
StringBuilder request_module_names;
for (auto& module_request : m_requested_modules) {
request_module_names.append(module_request.module_specifier);
request_module_names.append(", "sv);
}
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] module: {} has requested modules: [{}]", filename(), request_module_names.string_view());
#endif
// 9. For each String required of module.[[RequestedModules]], do
for (auto& required_string : m_requested_modules) {
ModuleRequest required { required_string };
// a. Let requiredModule be GetImportedModule(module, required).
auto required_module = get_imported_module(required);
// b. Set index to ? InnerModuleLinking(requiredModule, stack, index).
index = TRY(required_module->inner_module_linking(vm, stack, index));
// c. If requiredModule is a Cyclic Module Record, then
if (is<CyclicModule>(*required_module)) {
auto& cyclic_module = static_cast<CyclicModule&>(*required_module);
// i. Assert: requiredModule.[[Status]] is either linking, linked, evaluating-async, or evaluated.
VERIFY(cyclic_module.m_status == ModuleStatus::Linking || cyclic_module.m_status == ModuleStatus::Linked || cyclic_module.m_status == ModuleStatus::EvaluatingAsync || cyclic_module.m_status == ModuleStatus::Evaluated);
// ii. Assert: requiredModule.[[Status]] is linking if and only if requiredModule is in stack.
VERIFY((cyclic_module.m_status == ModuleStatus::Linking) == (stack.contains_slow(&cyclic_module)));
// iii. If requiredModule.[[Status]] is linking, then
if (cyclic_module.m_status == ModuleStatus::Linking) {
// 1. Set module.[[DFSAncestorIndex]] to min(module.[[DFSAncestorIndex]], requiredModule.[[DFSAncestorIndex]]).
m_dfs_ancestor_index = min(m_dfs_ancestor_index.value(), cyclic_module.m_dfs_ancestor_index.value());
}
}
}
// 10. Perform ? module.InitializeEnvironment().
TRY(initialize_environment(vm));
// 11. Assert: module occurs exactly once in stack.
size_t count = 0;
for (auto* module : stack) {
if (module == this)
count++;
}
VERIFY(count == 1);
// 12. Assert: module.[[DFSAncestorIndex]] ≤ module.[[DFSIndex]].
VERIFY(m_dfs_ancestor_index.value() <= m_dfs_index.value());
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] module {} after inner_linking has dfs {} and ancestor dfs {}", filename(), m_dfs_index.value(), m_dfs_ancestor_index.value());
// 13. If module.[[DFSAncestorIndex]] = module.[[DFSIndex]], then
if (m_dfs_ancestor_index == m_dfs_index) {
// a. Let done be false.
// b. Repeat, while done is false,
while (true) {
// i. Let requiredModule be the last element in stack.
// ii. Remove the last element of stack.
auto* required_module = stack.take_last();
// iii. Assert: requiredModule is a Cyclic Module Record.
VERIFY(is<CyclicModule>(*required_module));
// iv. Set requiredModule.[[Status]] to linked.
static_cast<CyclicModule&>(*required_module).m_status = ModuleStatus::Linked;
// v. If requiredModule and module are the same Module Record, set done to true.
if (required_module == this)
break;
}
}
// 14. Return index.
return index;
}
// 16.2.1.5.3 Evaluate ( ), https://tc39.es/ecma262/#sec-moduleevaluation
ThrowCompletionOr<Promise*> CyclicModule::evaluate(VM& vm)
{
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] evaluate[{}](vm)", this);
// 1. Assert: This call to Evaluate is not happening at the same time as another call to Evaluate within the surrounding agent.
// FIXME: Verify this somehow
// 2. Assert: module.[[Status]] is one of linked, evaluating-async, or evaluated.
VERIFY(m_status == ModuleStatus::Linked || m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated);
// NOTE: The spec does not catch the case where evaluate is called twice on a script which failed
// during evaluation. This means the script is evaluated but does not have a cycle root.
// In that case we first check if this module itself has a top level capability.
// See also: https://github.com/tc39/ecma262/issues/2823 .
if (m_top_level_capability != nullptr)
return verify_cast<Promise>(m_top_level_capability->promise().ptr());
// 3. If module.[[Status]] is either evaluating-async or evaluated, set module to module.[[CycleRoot]].
if (m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated) {
// Note: This will continue this function with module.[[CycleRoot]]
VERIFY(m_cycle_root);
VERIFY(this != m_cycle_root);
VERIFY(m_cycle_root->m_status == ModuleStatus::Linked);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] evaluate[{}](vm) deferring to cycle root at {}", this, m_cycle_root.ptr());
return m_cycle_root->evaluate(vm);
}
// 4. If module.[[TopLevelCapability]] is not empty, then
if (m_top_level_capability != nullptr) {
// a. Return module.[[TopLevelCapability]].[[Promise]].
return verify_cast<Promise>(m_top_level_capability->promise().ptr());
}
// 5. Let stack be a new empty List.
Vector<Module*> stack;
auto& realm = *vm.current_realm();
// 6. Let capability be ! NewPromiseCapability(%Promise%).
// 7. Set module.[[TopLevelCapability]] to capability.
m_top_level_capability = MUST(new_promise_capability(vm, realm.intrinsics().promise_constructor()));
// 8. Let result be Completion(InnerModuleEvaluation(module, stack, 0)).
auto result = inner_module_evaluation(vm, stack, 0);
// 9. If result is an abrupt completion, then
if (result.is_throw_completion()) {
VERIFY(!m_evaluation_error.is_error());
// a. For each Cyclic Module Record m of stack, do
for (auto* mod : stack) {
if (!is<CyclicModule>(*mod))
continue;
auto& cyclic_module = static_cast<CyclicModule&>(*mod);
// i. Assert: m.[[Status]] is evaluating.
VERIFY(cyclic_module.m_status == ModuleStatus::Evaluating);
// ii. Set m.[[Status]] to evaluated.
cyclic_module.m_status = ModuleStatus::Evaluated;
// iii. Set m.[[EvaluationError]] to result.
cyclic_module.m_evaluation_error = result.throw_completion();
}
// b. Assert: module.[[Status]] is evaluated.
VERIFY(m_status == ModuleStatus::Evaluated);
// c. Assert: module.[[EvaluationError]] is result.
VERIFY(m_evaluation_error.is_error());
VERIFY(same_value(*m_evaluation_error.throw_completion().value(), *result.throw_completion().value()));
// d. Perform ! Call(capability.[[Reject]], undefined, « result.[[Value]] »).
MUST(call(vm, *m_top_level_capability->reject(), js_undefined(), *result.throw_completion().value()));
}
// 10. Else,
else {
// a. Assert: module.[[Status]] is either evaluating-async or evaluated.
VERIFY(m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated);
// b. Assert: module.[[EvaluationError]] is empty.
VERIFY(!m_evaluation_error.is_error());
// c. If module.[[AsyncEvaluation]] is false, then
if (!m_async_evaluation) {
// i. Assert: module.[[Status]] is evaluated.
VERIFY(m_status == ModuleStatus::Evaluated);
// ii. Perform ! Call(capability.[[Resolve]], undefined, « undefined »).
MUST(call(vm, *m_top_level_capability->resolve(), js_undefined(), js_undefined()));
}
// d. Assert: stack is empty.
VERIFY(stack.is_empty());
}
// 11. Return capability.[[Promise]].
return verify_cast<Promise>(m_top_level_capability->promise().ptr());
}
// 16.2.1.5.2.1 InnerModuleEvaluation ( module, stack, index ), https://tc39.es/ecma262/#sec-innermoduleevaluation
ThrowCompletionOr<u32> CyclicModule::inner_module_evaluation(VM& vm, Vector<Module*>& stack, u32 index)
{
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] inner_module_evaluation[{}](vm, {}, {})", this, DeprecatedString::join(", "sv, stack), index);
// Note: Step 1 is performed in Module.cpp
// 2. If module.[[Status]] is evaluating-async or evaluated, then
if (m_status == ModuleStatus::EvaluatingAsync || m_status == ModuleStatus::Evaluated) {
// a. If module.[[EvaluationError]] is empty, return index.
if (!m_evaluation_error.is_error())
return index;
// b. Otherwise, return ? module.[[EvaluationError]].
return m_evaluation_error.throw_completion();
}
// 3. If module.[[Status]] is evaluating, return index.
if (m_status == ModuleStatus::Evaluating)
return index;
// 4. Assert: module.[[Status]] is linked.
VERIFY(m_status == ModuleStatus::Linked);
// 5. Set module.[[Status]] to evaluating.
m_status = ModuleStatus::Evaluating;
// 6. Set module.[[DFSIndex]] to index.
m_dfs_index = index;
// 7. Set module.[[DFSAncestorIndex]] to index.
m_dfs_ancestor_index = index;
// 8. Set module.[[PendingAsyncDependencies]] to 0.
m_pending_async_dependencies = 0;
// 9. Set index to index + 1.
++index;
// 10. Append module to stack.
stack.append(this);
// 11. For each String required of module.[[RequestedModules]], do
for (auto& required : m_requested_modules) {
// a. Let requiredModule be GetImportedModule(module, required).
auto required_module = get_imported_module(required);
// b. Set index to ? InnerModuleEvaluation(requiredModule, stack, index).
index = TRY(required_module->inner_module_evaluation(vm, stack, index));
// c. If requiredModule is a Cyclic Module Record, then
if (!is<CyclicModule>(*required_module))
continue;
JS::NonnullGCPtr<CyclicModule> cyclic_module = verify_cast<CyclicModule>(*required_module);
// i. Assert: requiredModule.[[Status]] is either evaluating, evaluating-async, or evaluated.
VERIFY(cyclic_module->m_status == ModuleStatus::Evaluating || cyclic_module->m_status == ModuleStatus::EvaluatingAsync || cyclic_module->m_status == ModuleStatus::Evaluated);
// ii. Assert: requiredModule.[[Status]] is evaluating if and only if requiredModule is in stack.
VERIFY(cyclic_module->m_status != ModuleStatus::Evaluating || stack.contains_slow(cyclic_module));
// iii. If requiredModule.[[Status]] is evaluating, then
if (cyclic_module->m_status == ModuleStatus::Evaluating) {
// 1. Set module.[[DFSAncestorIndex]] to min(module.[[DFSAncestorIndex]], requiredModule.[[DFSAncestorIndex]]).
m_dfs_ancestor_index = min(m_dfs_ancestor_index.value(), cyclic_module->m_dfs_ancestor_index.value());
}
// iv. Else,
else {
// 1. Set requiredModule to requiredModule.[[CycleRoot]].
VERIFY(cyclic_module->m_cycle_root);
cyclic_module = *cyclic_module->m_cycle_root;
// 2. Assert: requiredModule.[[Status]] is evaluating-async or evaluated.
VERIFY(cyclic_module->m_status == ModuleStatus::EvaluatingAsync || cyclic_module->m_status == ModuleStatus::Evaluated);
// 3. If requiredModule.[[EvaluationError]] is not empty, return ? requiredModule.[[EvaluationError]].
if (cyclic_module->m_evaluation_error.is_error())
return cyclic_module->m_evaluation_error.throw_completion();
}
// v. If requiredModule.[[AsyncEvaluation]] is true, then
if (cyclic_module->m_async_evaluation) {
// 1. Set module.[[PendingAsyncDependencies]] to module.[[PendingAsyncDependencies]] + 1.
++m_pending_async_dependencies.value();
// 2. Append module to requiredModule.[[AsyncParentModules]].
cyclic_module->m_async_parent_modules.append(this);
}
}
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] inner_module_evaluation on {} has tla: {} and pending async dep: {} dfs: {} ancestor dfs: {}", filename(), m_has_top_level_await, m_pending_async_dependencies.value(), m_dfs_index.value(), m_dfs_ancestor_index.value());
// 12. If module.[[PendingAsyncDependencies]] > 0 or module.[[HasTLA]] is true, then
if (m_pending_async_dependencies.value() > 0 || m_has_top_level_await) {
// a. Assert: module.[[AsyncEvaluation]] is false and was never previously set to true.
VERIFY(!m_async_evaluation); // FIXME: I don't think we can check previously?
// b. Set module.[[AsyncEvaluation]] to true.
m_async_evaluation = true;
// c. NOTE: The order in which module records have their [[AsyncEvaluation]] fields transition to true is significant. (See 16.2.1.5.2.4.)
// d. If module.[[PendingAsyncDependencies]] is 0, perform ExecuteAsyncModule(module).
if (m_pending_async_dependencies.value() == 0)
execute_async_module(vm);
}
// 13. Otherwise, perform ? module.ExecuteModule().
else {
TRY(execute_module(vm));
}
// 14. Assert: module occurs exactly once in stack.
auto count = 0;
for (auto* module : stack) {
if (module == this)
count++;
}
VERIFY(count == 1);
// 15. Assert: module.[[DFSAncestorIndex]] ≤ module.[[DFSIndex]].
VERIFY(m_dfs_ancestor_index.value() <= m_dfs_index.value());
// 16. If module.[[DFSAncestorIndex]] = module.[[DFSIndex]], then
if (m_dfs_ancestor_index == m_dfs_index) {
// a. Let done be false.
bool done = false;
// b. Repeat, while done is false,
while (!done) {
// i. Let requiredModule be the last element in stack.
// ii. Remove the last element of stack.
auto* required_module = stack.take_last();
// iii. Assert: requiredModule is a Cyclic Module Record.
VERIFY(is<CyclicModule>(*required_module));
auto& cyclic_module = static_cast<CyclicModule&>(*required_module);
// iv. If requiredModule.[[AsyncEvaluation]] is false, set requiredModule.[[Status]] to evaluated.
if (!cyclic_module.m_async_evaluation)
cyclic_module.m_status = ModuleStatus::Evaluated;
// v. Otherwise, set requiredModule.[[Status]] to evaluating-async.
else
cyclic_module.m_status = ModuleStatus::EvaluatingAsync;
// vi. If requiredModule and module are the same Module Record, set done to true.
if (required_module == this)
done = true;
// vii. Set requiredModule.[[CycleRoot]] to module.
cyclic_module.m_cycle_root = this;
}
}
// 17. Return index.
return index;
}
ThrowCompletionOr<void> CyclicModule::initialize_environment(VM&)
{
// Note: In ecma262 this is never called on a cyclic module only on SourceTextModules.
// So this check is to make sure we don't accidentally call this.
VERIFY_NOT_REACHED();
}
ThrowCompletionOr<void> CyclicModule::execute_module(VM&, GCPtr<PromiseCapability>)
{
// Note: In ecma262 this is never called on a cyclic module only on SourceTextModules.
// So this check is to make sure we don't accidentally call this.
VERIFY_NOT_REACHED();
}
// 16.2.1.5.2.2 ExecuteAsyncModule ( module ), https://tc39.es/ecma262/#sec-execute-async-module
void CyclicModule::execute_async_module(VM& vm)
{
auto& realm = *vm.current_realm();
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] executing async module {}", filename());
// 1. Assert: module.[[Status]] is evaluating or evaluating-async.
VERIFY(m_status == ModuleStatus::Evaluating || m_status == ModuleStatus::EvaluatingAsync);
// 2. Assert: module.[[HasTLA]] is true.
VERIFY(m_has_top_level_await);
// 3. Let capability be ! NewPromiseCapability(%Promise%).
auto capability = MUST(new_promise_capability(vm, realm.intrinsics().promise_constructor()));
// 4. Let fulfilledClosure be a new Abstract Closure with no parameters that captures module and performs the following steps when called:
auto fulfilled_closure = [&](VM& vm) -> ThrowCompletionOr<Value> {
// a. Perform AsyncModuleExecutionFulfilled(module).
async_module_execution_fulfilled(vm);
// b. Return undefined.
return js_undefined();
};
// 5. Let onFulfilled be CreateBuiltinFunction(fulfilledClosure, 0, "", « »).
auto on_fulfilled = NativeFunction::create(realm, move(fulfilled_closure), 0, "");
// 6. Let rejectedClosure be a new Abstract Closure with parameters (error) that captures module and performs the following steps when called:
auto rejected_closure = [&](VM& vm) -> ThrowCompletionOr<Value> {
auto error = vm.argument(0);
// a. Perform AsyncModuleExecutionRejected(module, error).
async_module_execution_rejected(vm, error);
// b. Return undefined.
return js_undefined();
};
// 7. Let onRejected be CreateBuiltinFunction(rejectedClosure, 0, "", « »).
auto on_rejected = NativeFunction::create(realm, move(rejected_closure), 0, "");
// 8. Perform PerformPromiseThen(capability.[[Promise]], onFulfilled, onRejected).
verify_cast<Promise>(capability->promise().ptr())->perform_then(on_fulfilled, on_rejected, {});
// 9. Perform ! module.ExecuteModule(capability).
MUST(execute_module(vm, capability));
// 10. Return unused.
}
// 16.2.1.5.2.3 GatherAvailableAncestors ( module, execList ), https://tc39.es/ecma262/#sec-gather-available-ancestors
void CyclicModule::gather_available_ancestors(Vector<CyclicModule*>& exec_list)
{
// 1. For each Cyclic Module Record m of module.[[AsyncParentModules]], do
for (auto module : m_async_parent_modules) {
// a. If execList does not contain m and m.[[CycleRoot]].[[EvaluationError]] is empty, then
if (!exec_list.contains_slow(module) && !module->m_cycle_root->m_evaluation_error.is_error()) {
// i. Assert: m.[[Status]] is evaluating-async.
VERIFY(module->m_status == ModuleStatus::EvaluatingAsync);
// ii. Assert: m.[[EvaluationError]] is empty.
VERIFY(!module->m_evaluation_error.is_error());
// iii. Assert: m.[[AsyncEvaluation]] is true.
VERIFY(module->m_async_evaluation);
// iv. Assert: m.[[PendingAsyncDependencies]] > 0.
VERIFY(module->m_pending_async_dependencies.value() > 0);
// v. Set m.[[PendingAsyncDependencies]] to m.[[PendingAsyncDependencies]] - 1.
module->m_pending_async_dependencies.value()--;
// vi. If m.[[PendingAsyncDependencies]] = 0, then
if (module->m_pending_async_dependencies.value() == 0) {
// 1. Append m to execList.
exec_list.append(module);
// 2. If m.[[HasTLA]] is false, perform GatherAvailableAncestors(m, execList).
if (!module->m_has_top_level_await)
module->gather_available_ancestors(exec_list);
}
}
}
// 2. Return unused.
}
// 16.2.1.5.2.4 AsyncModuleExecutionFulfilled ( module ), https://tc39.es/ecma262/#sec-async-module-execution-fulfilled
void CyclicModule::async_module_execution_fulfilled(VM& vm)
{
// 1. If module.[[Status]] is evaluated, then
if (m_status == ModuleStatus::Evaluated) {
// a. Assert: module.[[EvaluationError]] is not empty.
VERIFY(m_evaluation_error.is_error());
// b. Return unused.
return;
}
// 2. Assert: module.[[Status]] is evaluating-async.
VERIFY(m_status == ModuleStatus::EvaluatingAsync);
// 3. Assert: module.[[AsyncEvaluation]] is true.
VERIFY(m_async_evaluation);
// 4. Assert: module.[[EvaluationError]] is empty.
VERIFY(!m_evaluation_error.is_error());
// 5. Set module.[[AsyncEvaluation]] to false.
m_async_evaluation = false;
// 6. Set module.[[Status]] to evaluated.
m_status = ModuleStatus::Evaluated;
// 7. If module.[[TopLevelCapability]] is not empty, then
if (m_top_level_capability != nullptr) {
// a. Assert: module.[[CycleRoot]] is module.
VERIFY(m_cycle_root == this);
// b. Perform ! Call(module.[[TopLevelCapability]].[[Resolve]], undefined, « undefined »).
MUST(call(vm, *m_top_level_capability->resolve(), js_undefined(), js_undefined()));
}
// 8. Let execList be a new empty List.
Vector<CyclicModule*> exec_list;
// 9. Perform GatherAvailableAncestors(module, execList).
gather_available_ancestors(exec_list);
// 10. Let sortedExecList be a List whose elements are the elements of execList, in the order in which they had their [[AsyncEvaluation]] fields set to true in InnerModuleEvaluation.
// FIXME: Sort the list. To do this we need to use more than an Optional<bool> to track [[AsyncEvaluation]].
// 11. Assert: All elements of sortedExecList have their [[AsyncEvaluation]] field set to true, [[PendingAsyncDependencies]] field set to 0, and [[EvaluationError]] field set to empty.
VERIFY(all_of(exec_list, [&](CyclicModule* module) { return module->m_async_evaluation && module->m_pending_async_dependencies.value() == 0 && !module->m_evaluation_error.is_error(); }));
// 12. For each Cyclic Module Record m of sortedExecList, do
for (auto* module : exec_list) {
// a. If m.[[Status]] is evaluated, then
if (module->m_status == ModuleStatus::Evaluated) {
// i. Assert: m.[[EvaluationError]] is not empty.
VERIFY(module->m_evaluation_error.is_error());
}
// b. Else if m.[[HasTLA]] is true, then
else if (module->m_has_top_level_await) {
// i. Perform ExecuteAsyncModule(m).
module->execute_async_module(vm);
}
// c. Else,
else {
// i. Let result be m.ExecuteModule().
auto result = module->execute_module(vm);
// ii. If result is an abrupt completion, then
if (result.is_throw_completion()) {
// 1. Perform AsyncModuleExecutionRejected(m, result.[[Value]]).
module->async_module_execution_rejected(vm, *result.throw_completion().value());
}
// iii. Else,
else {
// 1. Set m.[[Status]] to evaluated.
module->m_status = ModuleStatus::Evaluated;
// 2. If m.[[TopLevelCapability]] is not empty, then
if (module->m_top_level_capability != nullptr) {
// a. Assert: m.[[CycleRoot]] is m.
VERIFY(module->m_cycle_root == module);
// b. Perform ! Call(m.[[TopLevelCapability]].[[Resolve]], undefined, « undefined »).
MUST(call(vm, *module->m_top_level_capability->resolve(), js_undefined(), js_undefined()));
}
}
}
}
// 13. Return unused.
}
// 16.2.1.5.2.5 AsyncModuleExecutionRejected ( module, error ), https://tc39.es/ecma262/#sec-async-module-execution-rejected
void CyclicModule::async_module_execution_rejected(VM& vm, Value error)
{
// 1. If module.[[Status]] is evaluated, then
if (m_status == ModuleStatus::Evaluated) {
// a. Assert: module.[[EvaluationError]] is not empty.
VERIFY(m_evaluation_error.is_error());
// b. Return unused.
return;
}
// 2. Assert: module.[[Status]] is evaluating-async.
VERIFY(m_status == ModuleStatus::EvaluatingAsync);
// 3. Assert: module.[[AsyncEvaluation]] is true.
VERIFY(m_async_evaluation);
// 4. Assert: module.[[EvaluationError]] is empty.
VERIFY(!m_evaluation_error.is_error());
// 5. Set module.[[EvaluationError]] to ThrowCompletion(error)
m_evaluation_error = throw_completion(error);
// 6. Set module.[[Status]] to evaluated.
m_status = ModuleStatus::Evaluated;
// 7. For each Cyclic Module Record m of module.[[AsyncParentModules]], do
for (auto module : m_async_parent_modules) {
// a. Perform AsyncModuleExecutionRejected(m, error).
module->async_module_execution_rejected(vm, error);
}
// 8. If module.[[TopLevelCapability]] is not empty, then
if (m_top_level_capability != nullptr) {
// a. Assert: module.[[CycleRoot]] is module.
VERIFY(m_cycle_root == this);
// b. Perform ! Call(module.[[TopLevelCapability]].[[Reject]], undefined, « error »).
MUST(call(vm, *m_top_level_capability->reject(), js_undefined(), error));
}
// 9. Return unused.
}
// 16.2.1.7 GetImportedModule ( referrer, specifier ), https://tc39.es/ecma262/#sec-GetImportedModule
NonnullGCPtr<Module> CyclicModule::get_imported_module(ModuleRequest const& request)
{
// 1. Assert: Exactly one element of referrer.[[LoadedModules]] is a Record whose [[Specifier]] is specifier,
// since LoadRequestedModules has completed successfully on referrer prior to invoking this abstract operation.
size_t element_with_specifier_count = 0;
for (auto const& loaded_module : m_loaded_modules) {
if (loaded_module.specifier == request.module_specifier)
++element_with_specifier_count;
}
VERIFY(element_with_specifier_count == 1);
for (auto const& loaded_module : m_loaded_modules) {
if (loaded_module.specifier == request.module_specifier) {
// 2. Let record be the Record in referrer.[[LoadedModules]] whose [[Specifier]] is specifier.
// 3. Return record.[[Module]].
return loaded_module.module;
}
}
VERIFY_NOT_REACHED();
}
// 13.3.10.1.1 ContinueDynamicImport ( promiseCapability, moduleCompletion ), https://tc39.es/ecma262/#sec-ContinueDynamicImport
void continue_dynamic_import(NonnullGCPtr<PromiseCapability> promise_capability, ThrowCompletionOr<NonnullGCPtr<Module>> const& module_completion)
{
auto& vm = promise_capability->vm();
// 1. If moduleCompletion is an abrupt completion, then
if (module_completion.is_throw_completion()) {
// a. Perform ! Call(promiseCapability.[[Reject]], undefined, « moduleCompletion.[[Value]] »).
MUST(call(vm, *promise_capability->reject(), js_undefined(), *module_completion.throw_completion().value()));
// b. Return unused.
return;
}
// 2. Let module be moduleCompletion.[[Value]].
auto& module = *module_completion.value();
// 3. Let loadPromise be module.LoadRequestedModules().
auto& load_promise = verify_cast<CyclicModule>(module).load_requested_modules({});
// 4. Let rejectedClosure be a new Abstract Closure with parameters (reason) that captures promiseCapability and performs the
// following steps when called:
auto reject_closure = [promise_capability](VM& vm) -> ThrowCompletionOr<Value> {
auto reason = vm.argument(0);
// a. Perform ! Call(promiseCapability.[[Reject]], undefined, « reason »).
MUST(call(vm, *promise_capability->reject(), js_undefined(), reason));
// b. Return unused.
return js_undefined();
};
// 5. Let onRejected be CreateBuiltinFunction(rejectedClosure, 1, "", « »).
auto on_rejected = NativeFunction::create(*vm.current_realm(), move(reject_closure), 1, "");
// 6. Let linkAndEvaluateClosure be a new Abstract Closure with no parameters that captures module, promiseCapability,
// and onRejected and performs the following steps when called:
auto link_and_evaluate_closure = [&module, promise_capability, on_rejected](VM& vm) -> ThrowCompletionOr<Value> {
// a. Let link be Completion(module.Link()).
auto link = module.link(vm);
// b. If link is an abrupt completion, then
if (link.is_throw_completion()) {
// i. Perform ! Call(promiseCapability.[[Reject]], undefined, « link.[[Value]] »).
MUST(call(vm, *promise_capability->reject(), js_undefined(), *link.throw_completion().value()));
// ii. Return unused.
return js_undefined();
}
// c. Let evaluatePromise be module.Evaluate().
auto evaluate_promise = module.evaluate(vm);
// d. Let fulfilledClosure be a new Abstract Closure with no parameters that captures module and
// promiseCapability and performs the following steps when called:
auto fulfilled_closure = [&module, promise_capability](VM& vm) -> ThrowCompletionOr<Value> {
// i. Let namespace be GetModuleNamespace(module).
auto namespace_ = module.get_module_namespace(vm);
// ii. Perform ! Call(promiseCapability.[[Resolve]], undefined, « namespace »).
MUST(call(vm, *promise_capability->resolve(), js_undefined(), namespace_.value()));
// iii. Return unused.
return js_undefined();
};
// e. Let onFulfilled be CreateBuiltinFunction(fulfilledClosure, 0, "", « »).
auto on_fulfilled = NativeFunction::create(*vm.current_realm(), move(fulfilled_closure), 0, "");
// f. Perform PerformPromiseThen(evaluatePromise, onFulfilled, onRejected).
evaluate_promise.value()->perform_then(on_fulfilled, on_rejected, {});
// g. Return unused.
return js_undefined();
};
// 7. Let linkAndEvaluate be CreateBuiltinFunction(linkAndEvaluateClosure, 0, "", « »).
auto link_and_evaluate = NativeFunction::create(*vm.current_realm(), move(link_and_evaluate_closure), 0, "");
// 8. Perform PerformPromiseThen(loadPromise, linkAndEvaluate, onRejected).
// FIXME: This is likely a spec bug, see load_requested_modules.
verify_cast<Promise>(*load_promise.promise()).perform_then(link_and_evaluate, on_rejected, {});
// 9. Return unused.
}
}