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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/* JavaScript modules (as in, the syntactic construct) implementation. */
#include "vm/Modules.h"
#include "mozilla/Assertions.h" // MOZ_ASSERT
#include "mozilla/ScopeExit.h"
#include "mozilla/Utf8.h" // mozilla::Utf8Unit
#include <stdint.h> // uint32_t
#include "jstypes.h" // JS_PUBLIC_API
#include "builtin/JSON.h" // js::ParseJSONWithReviver
#include "builtin/ModuleObject.h" // js::FinishDynamicModuleImport, js::{,Requested}ModuleObject
#include "builtin/Promise.h" // js::CreatePromiseObjectForAsync, js::AsyncFunctionReturned
#include "ds/Sort.h"
#include "frontend/BytecodeCompiler.h" // js::frontend::CompileModule
#include "frontend/FrontendContext.h" // js::AutoReportFrontendContext
#include "js/ColumnNumber.h" // JS::ColumnNumberOneOrigin
#include "js/Context.h" // js::AssertHeapIsIdle
#include "js/ErrorReport.h" // JSErrorBase
#include "js/RootingAPI.h" // JS::MutableHandle
#include "js/Value.h" // JS::Value
#include "vm/EnvironmentObject.h" // js::ModuleEnvironmentObject
#include "vm/JSAtomUtils.h" // AtomizeString
#include "vm/JSContext.h" // CHECK_THREAD, JSContext
#include "vm/JSObject.h" // JSObject
#include "vm/JSONParser.h" // JSONParser
#include "vm/List.h" // ListObject
#include "vm/Runtime.h" // JSRuntime
#include "vm/JSAtomUtils-inl.h" // AtomToId
#include "vm/JSContext-inl.h" // JSContext::{c,releaseC}heck
#include "vm/JSObject-inl.h"
#include "vm/NativeObject-inl.h"
using namespace js;
using mozilla::Utf8Unit;
static bool ModuleLink(JSContext* cx, Handle<ModuleObject*> module);
static bool ModuleEvaluate(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<Value> result);
static bool SyntheticModuleEvaluate(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<Value> result);
////////////////////////////////////////////////////////////////////////////////
// Public API
JS_PUBLIC_API JS::ModuleResolveHook JS::GetModuleResolveHook(JSRuntime* rt) {
AssertHeapIsIdle();
return rt->moduleResolveHook;
}
JS_PUBLIC_API void JS::SetModuleResolveHook(JSRuntime* rt,
ModuleResolveHook func) {
AssertHeapIsIdle();
rt->moduleResolveHook = func;
}
JS_PUBLIC_API JS::ModuleMetadataHook JS::GetModuleMetadataHook(JSRuntime* rt) {
AssertHeapIsIdle();
return rt->moduleMetadataHook;
}
JS_PUBLIC_API void JS::SetModuleMetadataHook(JSRuntime* rt,
ModuleMetadataHook func) {
AssertHeapIsIdle();
rt->moduleMetadataHook = func;
}
JS_PUBLIC_API JS::ModuleDynamicImportHook JS::GetModuleDynamicImportHook(
JSRuntime* rt) {
AssertHeapIsIdle();
return rt->moduleDynamicImportHook;
}
JS_PUBLIC_API void JS::SetModuleDynamicImportHook(
JSRuntime* rt, ModuleDynamicImportHook func) {
AssertHeapIsIdle();
rt->moduleDynamicImportHook = func;
}
JS_PUBLIC_API bool JS::FinishDynamicModuleImport(
JSContext* cx, Handle<JSObject*> evaluationPromise,
Handle<Value> referencingPrivate, Handle<JSObject*> moduleRequest,
Handle<JSObject*> promise) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(referencingPrivate, promise);
return js::FinishDynamicModuleImport(
cx, evaluationPromise, referencingPrivate, moduleRequest, promise);
}
template <typename Unit>
static JSObject* CompileModuleHelper(JSContext* cx,
const JS::ReadOnlyCompileOptions& options,
JS::SourceText<Unit>& srcBuf) {
MOZ_ASSERT(!cx->zone()->isAtomsZone());
AssertHeapIsIdle();
CHECK_THREAD(cx);
JS::Rooted<JSObject*> mod(cx);
{
AutoReportFrontendContext fc(cx);
mod = frontend::CompileModule(cx, &fc, options, srcBuf);
}
return mod;
}
JS_PUBLIC_API JSObject* JS::CompileModule(JSContext* cx,
const ReadOnlyCompileOptions& options,
SourceText<char16_t>& srcBuf) {
return CompileModuleHelper(cx, options, srcBuf);
}
JS_PUBLIC_API JSObject* JS::CompileModule(JSContext* cx,
const ReadOnlyCompileOptions& options,
SourceText<Utf8Unit>& srcBuf) {
return CompileModuleHelper(cx, options, srcBuf);
}
JS_PUBLIC_API JSObject* JS::CompileJsonModule(
JSContext* cx, const ReadOnlyCompileOptions& options,
SourceText<mozilla::Utf8Unit>& srcBuf) {
size_t length = srcBuf.length();
auto chars =
UniqueTwoByteChars(UTF8CharsToNewTwoByteCharsZ(
cx, JS::UTF8Chars(srcBuf.get(), srcBuf.length()),
&length, js::MallocArena)
.get());
if (!chars) {
return nullptr;
}
JS::SourceText<char16_t> source;
if (!source.init(cx, std::move(chars), length)) {
return nullptr;
}
return CompileJsonModule(cx, options, source);
}
JS_PUBLIC_API JSObject* JS::CompileJsonModule(
JSContext* cx, const ReadOnlyCompileOptions& options,
SourceText<char16_t>& srcBuf) {
MOZ_ASSERT(!cx->zone()->isAtomsZone());
AssertHeapIsIdle();
CHECK_THREAD(cx);
auto charRange =
mozilla::Range<const char16_t>(srcBuf.get(), srcBuf.length());
Rooted<JSONParser<char16_t>> parser(
cx, cx, charRange, JSONParser<char16_t>::ParseType::JSONParse);
parser.reportLineNumbersFromParsedData(true);
parser.setFilename(options.filename());
JS::RootedValue jsonValue(cx);
if (!parser.parse(&jsonValue)) {
return nullptr;
}
Rooted<ExportNameVector> exportNames(cx);
if (!exportNames.append(cx->names().default_)) {
ReportOutOfMemory(cx);
return nullptr;
}
Rooted<ModuleObject*> moduleObject(
cx, ModuleObject::createSynthetic(cx, &exportNames));
if (!moduleObject) {
return nullptr;
}
RootedVector<Value> exportValues(cx);
if (!exportValues.append(jsonValue)) {
ReportOutOfMemory(cx);
return nullptr;
}
if (!ModuleObject::createSyntheticEnvironment(cx, moduleObject,
exportValues)) {
return nullptr;
}
return moduleObject;
}
JS_PUBLIC_API void JS::SetModulePrivate(JSObject* module, const Value& value) {
JSRuntime* rt = module->zone()->runtimeFromMainThread();
module->as<ModuleObject>().scriptSourceObject()->setPrivate(rt, value);
}
JS_PUBLIC_API void JS::ClearModulePrivate(JSObject* module) {
// |module| may be gray, be careful not to create edges to it.
JSRuntime* rt = module->zone()->runtimeFromMainThread();
module->as<ModuleObject>().scriptSourceObject()->clearPrivate(rt);
}
JS_PUBLIC_API JS::Value JS::GetModulePrivate(JSObject* module) {
return module->as<ModuleObject>().scriptSourceObject()->getPrivate();
}
JS_PUBLIC_API bool JS::IsCyclicModule(JSObject* module) {
return module->as<ModuleObject>().hasCyclicModuleFields();
}
JS_PUBLIC_API bool JS::ModuleLink(JSContext* cx, Handle<JSObject*> moduleArg) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->releaseCheck(moduleArg);
return ::ModuleLink(cx, moduleArg.as<ModuleObject>());
}
JS_PUBLIC_API bool JS::ModuleEvaluate(JSContext* cx,
Handle<JSObject*> moduleRecord,
MutableHandle<JS::Value> rval) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->releaseCheck(moduleRecord);
cx->isEvaluatingModule++;
auto guard = mozilla::MakeScopeExit([cx] {
MOZ_ASSERT(cx->isEvaluatingModule != 0);
cx->isEvaluatingModule--;
});
if (moduleRecord.as<ModuleObject>()->hasSyntheticModuleFields()) {
return SyntheticModuleEvaluate(cx, moduleRecord.as<ModuleObject>(), rval);
}
return ::ModuleEvaluate(cx, moduleRecord.as<ModuleObject>(), rval);
}
JS_PUBLIC_API bool JS::ThrowOnModuleEvaluationFailure(
JSContext* cx, Handle<JSObject*> evaluationPromise,
ModuleErrorBehaviour errorBehaviour) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->releaseCheck(evaluationPromise);
return OnModuleEvaluationFailure(cx, evaluationPromise, errorBehaviour);
}
JS_PUBLIC_API uint32_t
JS::GetRequestedModulesCount(JSContext* cx, Handle<JSObject*> moduleRecord) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRecord);
return moduleRecord->as<ModuleObject>().requestedModules().Length();
}
JS_PUBLIC_API JSString* JS::GetRequestedModuleSpecifier(
JSContext* cx, Handle<JSObject*> moduleRecord, uint32_t index) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRecord);
auto* moduleRequest = moduleRecord->as<ModuleObject>()
.requestedModules()[index]
.moduleRequest();
// This implements step 7.1.1 in HostLoadImportedModule.
//
// If moduleRequest.[[Attributes]] contains a Record entry such that
// entry.[[Key]] is not "type",
if (moduleRequest->hasFirstUnsupportedAttributeKey()) {
UniqueChars printableKey = AtomToPrintableString(
cx, moduleRequest->getFirstUnsupportedAttributeKey());
JS_ReportErrorNumberASCII(
cx, GetErrorMessage, nullptr,
JSMSG_IMPORT_ATTRIBUTES_STATIC_IMPORT_UNSUPPORTED_ATTRIBUTE,
printableKey ? printableKey.get() : "");
return nullptr;
}
// This implements step 7.1.5 in HostLoadImportedModule.
//
// If the result of running the module type allowed steps given moduleType and
// settings is false.
if (moduleRequest->moduleType() == JS::ModuleType::Unknown) {
JS_ReportErrorNumberASCII(cx, js::GetErrorMessage, nullptr,
JSMSG_BAD_MODULE_TYPE);
return nullptr;
}
return moduleRequest->specifier();
}
JS_PUBLIC_API void JS::GetRequestedModuleSourcePos(
JSContext* cx, Handle<JSObject*> moduleRecord, uint32_t index,
uint32_t* lineNumber, JS::ColumnNumberOneOrigin* columnNumber) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRecord);
MOZ_ASSERT(lineNumber);
MOZ_ASSERT(columnNumber);
auto& module = moduleRecord->as<ModuleObject>();
*lineNumber = module.requestedModules()[index].lineNumber();
*columnNumber = module.requestedModules()[index].columnNumber();
}
JS_PUBLIC_API JS::ModuleType JS::GetRequestedModuleType(
JSContext* cx, Handle<JSObject*> moduleRecord, uint32_t index) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRecord);
auto& module = moduleRecord->as<ModuleObject>();
return module.requestedModules()[index].moduleRequest()->moduleType();
}
JS_PUBLIC_API JSScript* JS::GetModuleScript(JS::HandleObject moduleRecord) {
AssertHeapIsIdle();
auto& module = moduleRecord->as<ModuleObject>();
// A synthetic module does not have a script associated with it.
if (module.hasSyntheticModuleFields()) {
return nullptr;
}
return module.script();
}
JS_PUBLIC_API JSObject* JS::GetModuleObject(HandleScript moduleScript) {
AssertHeapIsIdle();
MOZ_ASSERT(moduleScript->isModule());
return moduleScript->module();
}
JS_PUBLIC_API JSObject* JS::GetModuleNamespace(JSContext* cx,
HandleObject moduleRecord) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRecord);
MOZ_ASSERT(moduleRecord->is<ModuleObject>());
return GetOrCreateModuleNamespace(cx, moduleRecord.as<ModuleObject>());
}
JS_PUBLIC_API JSObject* JS::GetModuleForNamespace(
JSContext* cx, HandleObject moduleNamespace) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleNamespace);
MOZ_ASSERT(moduleNamespace->is<ModuleNamespaceObject>());
return &moduleNamespace->as<ModuleNamespaceObject>().module();
}
JS_PUBLIC_API JSObject* JS::GetModuleEnvironment(JSContext* cx,
Handle<JSObject*> moduleObj) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleObj);
MOZ_ASSERT(moduleObj->is<ModuleObject>());
return moduleObj->as<ModuleObject>().environment();
}
JS_PUBLIC_API JSObject* JS::CreateModuleRequest(JSContext* cx,
Handle<JSString*> specifierArg,
JS::ModuleType moduleType) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
Rooted<JSAtom*> specifierAtom(cx, AtomizeString(cx, specifierArg));
if (!specifierAtom) {
return nullptr;
}
return ModuleRequestObject::create(cx, specifierAtom, moduleType);
}
JS_PUBLIC_API JSString* JS::GetModuleRequestSpecifier(
JSContext* cx, Handle<JSObject*> moduleRequestArg) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRequestArg);
return moduleRequestArg->as<ModuleRequestObject>().specifier();
}
JS_PUBLIC_API JS::ModuleType JS::GetModuleRequestType(
JSContext* cx, Handle<JSObject*> moduleRequestArg) {
AssertHeapIsIdle();
CHECK_THREAD(cx);
cx->check(moduleRequestArg);
return moduleRequestArg->as<ModuleRequestObject>().moduleType();
}
JS_PUBLIC_API void JS::ClearModuleEnvironment(JSObject* moduleObj) {
MOZ_ASSERT(moduleObj);
AssertHeapIsIdle();
js::ModuleEnvironmentObject* env =
moduleObj->as<js::ModuleObject>().environment();
if (!env) {
return;
}
const JSClass* clasp = env->getClass();
uint32_t numReserved = JSCLASS_RESERVED_SLOTS(clasp);
uint32_t numSlots = env->slotSpan();
for (uint32_t i = numReserved; i < numSlots; i++) {
env->setSlot(i, UndefinedValue());
}
}
JS_PUBLIC_API bool JS::ModuleIsLinked(JSObject* moduleObj) {
AssertHeapIsIdle();
return moduleObj->as<ModuleObject>().status() != ModuleStatus::Unlinked;
}
////////////////////////////////////////////////////////////////////////////////
// Internal implementation
class ResolveSetEntry {
ModuleObject* module_;
JSAtom* exportName_;
public:
ResolveSetEntry(ModuleObject* module, JSAtom* exportName)
: module_(module), exportName_(exportName) {}
ModuleObject* module() const { return module_; }
JSAtom* exportName() const { return exportName_; }
void trace(JSTracer* trc) {
TraceRoot(trc, &module_, "ResolveSetEntry::module_");
TraceRoot(trc, &exportName_, "ResolveSetEntry::exportName_");
}
};
using ResolveSet = GCVector<ResolveSetEntry, 0, SystemAllocPolicy>;
using ModuleSet =
GCHashSet<ModuleObject*, DefaultHasher<ModuleObject*>, SystemAllocPolicy>;
static ModuleObject* HostResolveImportedModule(
JSContext* cx, Handle<ModuleObject*> module,
Handle<ModuleRequestObject*> moduleRequest,
ModuleStatus expectedMinimumStatus);
static bool CyclicModuleResolveExport(JSContext* cx,
Handle<ModuleObject*> module,
Handle<JSAtom*> exportName,
MutableHandle<ResolveSet> resolveSet,
MutableHandle<Value> result,
ModuleErrorInfo* errorInfoOut = nullptr);
static bool SyntheticModuleResolveExport(JSContext* cx,
Handle<ModuleObject*> module,
Handle<JSAtom*> exportName,
MutableHandle<Value> result,
ModuleErrorInfo* errorInfoOut);
static ModuleNamespaceObject* ModuleNamespaceCreate(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<UniquePtr<ExportNameVector>> exports);
static bool InnerModuleLinking(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> stack, size_t index,
size_t* indexOut);
static bool InnerModuleEvaluation(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> stack,
size_t index, size_t* indexOut);
static bool ExecuteAsyncModule(JSContext* cx, Handle<ModuleObject*> module);
static bool GatherAvailableModuleAncestors(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> execList);
static const char* ModuleStatusName(ModuleStatus status) {
switch (status) {
case ModuleStatus::Unlinked:
return "Unlinked";
case ModuleStatus::Linking:
return "Linking";
case ModuleStatus::Linked:
return "Linked";
case ModuleStatus::Evaluating:
return "Evaluating";
case ModuleStatus::EvaluatingAsync:
return "EvaluatingAsync";
case ModuleStatus::Evaluated:
return "Evaluated";
default:
MOZ_CRASH("Unexpected ModuleStatus");
}
}
static bool ContainsElement(const ExportNameVector& list, JSAtom* atom) {
for (JSAtom* a : list) {
if (a == atom) {
return true;
}
}
return false;
}
static bool ContainsElement(Handle<ModuleVector> stack, ModuleObject* module) {
for (ModuleObject* m : stack) {
if (m == module) {
return true;
}
}
return false;
}
#ifdef DEBUG
static size_t CountElements(Handle<ModuleVector> stack, ModuleObject* module) {
size_t count = 0;
for (ModuleObject* m : stack) {
if (m == module) {
count++;
}
}
return count;
}
#endif
static bool SyntheticModuleGetExportedNames(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ExportNameVector> exportedNames) {
MOZ_ASSERT(exportedNames.empty());
if (!exportedNames.appendAll(module->syntheticExportNames())) {
ReportOutOfMemory(cx);
return false;
}
return true;
}
// ES2023 16.2.1.6.2 GetExportedNames
static bool ModuleGetExportedNames(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleSet> exportStarSet,
MutableHandle<ExportNameVector> exportedNames) {
// Step 4. Let exportedNames be a new empty List.
MOZ_ASSERT(exportedNames.empty());
if (module->hasSyntheticModuleFields()) {
return SyntheticModuleGetExportedNames(cx, module, exportedNames);
}
// Step 2. If exportStarSet contains module, then:
if (exportStarSet.has(module)) {
// Step 2.a. We've reached the starting point of an export * circularity.
// Step 2.b. Return a new empty List.
return true;
}
// Step 3. Append module to exportStarSet.
if (!exportStarSet.put(module)) {
ReportOutOfMemory(cx);
return false;
}
// Step 5. For each ExportEntry Record e of module.[[LocalExportEntries]], do:
for (const ExportEntry& e : module->localExportEntries()) {
// Step 5.a. Assert: module provides the direct binding for this export.
// Step 5.b. Append e.[[ExportName]] to exportedNames.
if (!exportedNames.append(e.exportName())) {
ReportOutOfMemory(cx);
return false;
}
}
// Step 6. For each ExportEntry Record e of module.[[IndirectExportEntries]],
// do:
for (const ExportEntry& e : module->indirectExportEntries()) {
// Step 6.a. Assert: module imports a specific binding for this export.
// Step 6.b. Append e.[[ExportName]] to exportedNames.
if (!exportedNames.append(e.exportName())) {
ReportOutOfMemory(cx);
return false;
}
}
// Step 7. For each ExportEntry Record e of module.[[StarExportEntries]], do:
Rooted<ModuleRequestObject*> moduleRequest(cx);
Rooted<ModuleObject*> requestedModule(cx);
Rooted<JSAtom*> name(cx);
for (const ExportEntry& e : module->starExportEntries()) {
// Step 7.a. Let requestedModule be ? HostResolveImportedModule(module,
// e.[[ModuleRequest]]).
moduleRequest = e.moduleRequest();
requestedModule = HostResolveImportedModule(cx, module, moduleRequest,
ModuleStatus::Unlinked);
if (!requestedModule) {
return false;
}
// Step 7.b. Let starNames be ?
// requestedModule.GetExportedNames(exportStarSet).
Rooted<ExportNameVector> starNames(cx);
if (!ModuleGetExportedNames(cx, requestedModule, exportStarSet,
&starNames)) {
return false;
}
// Step 7.c. For each element n of starNames, do:
for (JSAtom* name : starNames) {
// Step 7.c.i. If SameValue(n, "default") is false, then:
if (name != cx->names().default_) {
// Step 7.c.i.1. If n is not an element of exportedNames, then:
if (!ContainsElement(exportedNames, name)) {
// Step 7.c.i.1.a. Append n to exportedNames.
if (!exportedNames.append(name)) {
ReportOutOfMemory(cx);
return false;
}
}
}
}
}
// Step 8. Return exportedNames.
return true;
}
static void ThrowUnexpectedModuleStatus(JSContext* cx, ModuleStatus status) {
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
JSMSG_BAD_MODULE_STATUS, ModuleStatusName(status));
}
static ModuleObject* HostResolveImportedModule(
JSContext* cx, Handle<ModuleObject*> module,
Handle<ModuleRequestObject*> moduleRequest,
ModuleStatus expectedMinimumStatus) {
MOZ_ASSERT(module);
MOZ_ASSERT(moduleRequest);
Rooted<Value> referencingPrivate(cx, JS::GetModulePrivate(module));
Rooted<ModuleObject*> requestedModule(cx);
requestedModule =
CallModuleResolveHook(cx, referencingPrivate, moduleRequest);
if (!requestedModule) {
return nullptr;
}
if (requestedModule->status() < expectedMinimumStatus) {
ThrowUnexpectedModuleStatus(cx, requestedModule->status());
return nullptr;
}
return requestedModule;
}
// ES2023 16.2.1.6.3 ResolveExport
//
// Returns an value describing the location of the resolved export or indicating
// a failure.
//
// On success this returns a resolved binding record: { module, bindingName }
//
// There are two failure cases:
//
// - If no definition was found or the request is found to be circular, *null*
// is returned.
//
// - If the request is found to be ambiguous, the string `"ambiguous"` is
// returned.
//
static bool ModuleResolveExport(JSContext* cx, Handle<ModuleObject*> module,
Handle<JSAtom*> exportName,
MutableHandle<Value> result,
ModuleErrorInfo* errorInfoOut = nullptr) {
if (module->hasSyntheticModuleFields()) {
return SyntheticModuleResolveExport(cx, module, exportName, result,
errorInfoOut);
}
// Step 1. If resolveSet is not present, set resolveSet to a new empty List.
Rooted<ResolveSet> resolveSet(cx);
return CyclicModuleResolveExport(cx, module, exportName, &resolveSet, result,
errorInfoOut);
}
static bool CreateResolvedBindingObject(JSContext* cx,
Handle<ModuleObject*> module,
Handle<JSAtom*> bindingName,
MutableHandle<Value> result) {
Rooted<ResolvedBindingObject*> obj(
cx, ResolvedBindingObject::create(cx, module, bindingName));
if (!obj) {
return false;
}
result.setObject(*obj);
return true;
}
static bool CyclicModuleResolveExport(JSContext* cx,
Handle<ModuleObject*> module,
Handle<JSAtom*> exportName,
MutableHandle<ResolveSet> resolveSet,
MutableHandle<Value> result,
ModuleErrorInfo* errorInfoOut) {
// Step 2. For each Record { [[Module]], [[ExportName]] } r of resolveSet, do:
for (const auto& entry : resolveSet) {
// Step 2.a. If module and r.[[Module]] are the same Module Record and
// SameValue(exportName, r.[[ExportName]]) is true, then:
if (entry.module() == module && entry.exportName() == exportName) {
// Step 2.a.i. Assert: This is a circular import request.
// Step 2.a.ii. Return null.
result.setNull();
if (errorInfoOut) {
errorInfoOut->setCircularImport(cx, module);
}
return true;
}
}
// Step 3. Append the Record { [[Module]]: module, [[ExportName]]: exportName
// } to resolveSet.
if (!resolveSet.emplaceBack(module, exportName)) {
ReportOutOfMemory(cx);
return false;
}
// Step 4. For each ExportEntry Record e of module.[[LocalExportEntries]], do:
for (const ExportEntry& e : module->localExportEntries()) {
// Step 4.a. If SameValue(exportName, e.[[ExportName]]) is true, then:
if (exportName == e.exportName()) {
// Step 4.a.i. Assert: module provides the direct binding for this export.
// Step 4.a.ii. Return ResolvedBinding Record { [[Module]]: module,
// [[BindingName]]: e.[[LocalName]] }.
Rooted<JSAtom*> localName(cx, e.localName());
return CreateResolvedBindingObject(cx, module, localName, result);
}
}
// Step 5. For each ExportEntry Record e of module.[[IndirectExportEntries]],
// do:
Rooted<ModuleRequestObject*> moduleRequest(cx);
Rooted<ModuleObject*> importedModule(cx);
Rooted<JSAtom*> name(cx);
for (const ExportEntry& e : module->indirectExportEntries()) {
// Step 5.a. If SameValue(exportName, e.[[ExportName]]) is true, then:
if (exportName == e.exportName()) {
// Step 5.a.i. Let importedModule be ? HostResolveImportedModule(module,
// e.[[ModuleRequest]]).
moduleRequest = e.moduleRequest();
importedModule = HostResolveImportedModule(cx, module, moduleRequest,
ModuleStatus::Unlinked);
if (!importedModule) {
return false;
}
// Step 5.a.ii. If e.[[ImportName]] is all, then:
if (!e.importName()) {
// Step 5.a.ii.1. Assert: module does not provide the direct binding for
// this export.
// Step 5.a.ii.2. Return ResolvedBinding Record { [[Module]]:
// importedModule, [[BindingName]]: namespace }.
name = cx->names().star_namespace_star_;
return CreateResolvedBindingObject(cx, importedModule, name, result);
} else {
// Step 5.a.iii.1. Assert: module imports a specific binding for this
// export.
// Step 5.a.iii.2. Return ?
// importedModule.ResolveExport(e.[[ImportName]],
// resolveSet).
name = e.importName();
return CyclicModuleResolveExport(cx, importedModule, name, resolveSet,
result, errorInfoOut);
}
}
}
// Step 6. If SameValue(exportName, "default") is true, then:
if (exportName == cx->names().default_) {
// Step 6.a. Assert: A default export was not explicitly defined by this
// module.
// Step 6.b. Return null.
// Step 6.c. NOTE: A default export cannot be provided by an export * from
// "mod" declaration.
result.setNull();
if (errorInfoOut) {
errorInfoOut->setImportedModule(cx, module);
}
return true;
}
// Step 7. Let starResolution be null.
Rooted<ResolvedBindingObject*> starResolution(cx);
// Step 8. For each ExportEntry Record e of module.[[StarExportEntries]], do:
Rooted<Value> resolution(cx);
Rooted<ResolvedBindingObject*> binding(cx);
for (const ExportEntry& e : module->starExportEntries()) {
// Step 8.a. Let importedModule be ? HostResolveImportedModule(module,
// e.[[ModuleRequest]]).
moduleRequest = e.moduleRequest();
importedModule = HostResolveImportedModule(cx, module, moduleRequest,
ModuleStatus::Unlinked);
if (!importedModule) {
return false;
}
// Step 8.b. Let resolution be ? importedModule.ResolveExport(exportName,
// resolveSet).
if (!CyclicModuleResolveExport(cx, importedModule, exportName, resolveSet,
&resolution, errorInfoOut)) {
return false;
}
// Step 8.c. If resolution is ambiguous, return ambiguous.
if (resolution == StringValue(cx->names().ambiguous)) {
result.set(resolution);
return true;
}
// Step 8.d. If resolution is not null, then:
if (!resolution.isNull()) {
// Step 8.d.i. Assert: resolution is a ResolvedBinding Record.
binding = &resolution.toObject().as<ResolvedBindingObject>();
// Step 8.d.ii. If starResolution is null, set starResolution to
// resolution.
if (!starResolution) {
starResolution = binding;
} else {
// Step 8.d.iii. Else:
// Step 8.d.iii.1. Assert: There is more than one * import that includes
// the requested name.
// Step 8.d.iii.2. If resolution.[[Module]] and
// starResolution.[[Module]] are not the same Module
// Record, return ambiguous.
// Step 8.d.iii.3. If resolution.[[BindingName]] is namespace and
// starResolution.[[BindingName]] is not namespace, or
// if resolution.[[BindingName]] is not namespace and
// starResolution.[[BindingName]] is namespace, return
// ambiguous.
// Step 8.d.iii.4. If resolution.[[BindingName]] is a String,
// starResolution.[[BindingName]] is a String, and
// SameValue(resolution.[[BindingName]],
// starResolution.[[BindingName]]) is false, return
// ambiguous.
if (binding->module() != starResolution->module() ||
binding->bindingName() != starResolution->bindingName()) {
result.set(StringValue(cx->names().ambiguous));
if (errorInfoOut) {
Rooted<ModuleObject*> module1(cx, starResolution->module());
Rooted<ModuleObject*> module2(cx, binding->module());
errorInfoOut->setForAmbiguousImport(cx, module, module1, module2);
}
return true;
}
}
}
}
// Step 9. Return starResolution.
result.setObjectOrNull(starResolution);
if (!starResolution && errorInfoOut) {
errorInfoOut->setImportedModule(cx, module);
}
return true;
}
static bool SyntheticModuleResolveExport(JSContext* cx,
Handle<ModuleObject*> module,
Handle<JSAtom*> exportName,
MutableHandle<Value> result,
ModuleErrorInfo* errorInfoOut) {
// Step 2. If module.[[ExportNames]] does not contain exportName, return null.
if (!ContainsElement(module->syntheticExportNames(), exportName)) {
result.setNull();
if (errorInfoOut) {
errorInfoOut->setImportedModule(cx, module);
}
return true;
}
// Step 3. Return ResolvedBinding Record { [[Module]]: module,
// [[BindingName]]: exportName }.
return CreateResolvedBindingObject(cx, module, exportName, result);
}
// ES2023 16.2.1.10 GetModuleNamespace
ModuleNamespaceObject* js::GetOrCreateModuleNamespace(
JSContext* cx, Handle<ModuleObject*> module) {
// Step 1. Assert: If module is a Cyclic Module Record, then module.[[Status]]
// is not unlinked.
MOZ_ASSERT(module->status() != ModuleStatus::Unlinked);
// Step 2. Let namespace be module.[[Namespace]].
Rooted<ModuleNamespaceObject*> ns(cx, module->namespace_());
// Step 3. If namespace is empty, then:
if (!ns) {
// Step 3.a. Let exportedNames be ? module.GetExportedNames().
Rooted<ModuleSet> exportStarSet(cx);
Rooted<ExportNameVector> exportedNames(cx);
if (!ModuleGetExportedNames(cx, module, &exportStarSet, &exportedNames)) {
return nullptr;
}
// Step 3.b. Let unambiguousNames be a new empty List.
Rooted<UniquePtr<ExportNameVector>> unambiguousNames(
cx, cx->make_unique<ExportNameVector>());
if (!unambiguousNames) {
return nullptr;
}
// Step 3.c. For each element name of exportedNames, do:
Rooted<JSAtom*> name(cx);
Rooted<Value> resolution(cx);
for (JSAtom* atom : exportedNames) {
name = atom;
// Step 3.c.i. Let resolution be ? module.ResolveExport(name).
if (!ModuleResolveExport(cx, module, name, &resolution)) {
return nullptr;
}
// Step 3.c.ii. If resolution is a ResolvedBinding Record, append name to
// unambiguousNames.
if (resolution.isObject() && !unambiguousNames->append(name)) {
ReportOutOfMemory(cx);
return nullptr;
}
}
// Step 3.d. Set namespace to ModuleNamespaceCreate(module,
// unambiguousNames).
ns = ModuleNamespaceCreate(cx, module, &unambiguousNames);
}
// Step 4. Return namespace.
return ns;
}
static bool IsResolvedBinding(JSContext* cx, Handle<Value> resolution) {
MOZ_ASSERT(resolution.isObjectOrNull() ||
resolution.toString() == cx->names().ambiguous);
return resolution.isObject();
}
static void InitNamespaceBinding(JSContext* cx,
Handle<ModuleEnvironmentObject*> env,
Handle<JSAtom*> name,
Handle<ModuleNamespaceObject*> ns) {
// The property already exists in the evironment but is not writable, so set
// the slot directly.
RootedId id(cx, AtomToId(name));
mozilla::Maybe<PropertyInfo> prop = env->lookup(cx, id);
MOZ_ASSERT(prop.isSome());
env->setSlot(prop->slot(), ObjectValue(*ns));
}
struct AtomComparator {
bool operator()(JSAtom* a, JSAtom* b, bool* lessOrEqualp) {
int32_t result = CompareStrings(a, b);
*lessOrEqualp = (result <= 0);
return true;
}
};
// ES2023 10.4.6.12 ModuleNamespaceCreate
static ModuleNamespaceObject* ModuleNamespaceCreate(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<UniquePtr<ExportNameVector>> exports) {
// Step 1. Assert: module.[[Namespace]] is empty.
MOZ_ASSERT(!module->namespace_());
// Step 6. Let sortedExports be a List whose elements are the elements of
// exports ordered as if an Array of the same values had been sorted
// using %Array.prototype.sort% using undefined as comparefn.
ExportNameVector scratch;
if (!scratch.resize(exports->length())) {
ReportOutOfMemory(cx);
return nullptr;
}
MOZ_ALWAYS_TRUE(MergeSort(exports->begin(), exports->length(),
scratch.begin(), AtomComparator()));
// Steps 2 - 5.
Rooted<ModuleNamespaceObject*> ns(
cx, ModuleObject::createNamespace(cx, module, exports));
if (!ns) {
return nullptr;
}
// Pre-compute all binding mappings now instead of on each access.
// See:
// ES2023 10.4.6.8 Module Namespace Exotic Object [[Get]]
Rooted<JSAtom*> name(cx);
Rooted<Value> resolution(cx);
Rooted<ResolvedBindingObject*> binding(cx);
Rooted<ModuleObject*> importedModule(cx);
Rooted<ModuleNamespaceObject*> importedNamespace(cx);
Rooted<JSAtom*> bindingName(cx);
for (JSAtom* atom : ns->exports()) {
name = atom;
if (!ModuleResolveExport(cx, module, name, &resolution)) {
return nullptr;
}
MOZ_ASSERT(IsResolvedBinding(cx, resolution));
binding = &resolution.toObject().as<ResolvedBindingObject>();
importedModule = binding->module();
bindingName = binding->bindingName();
if (bindingName == cx->names().star_namespace_star_) {
importedNamespace = GetOrCreateModuleNamespace(cx, importedModule);
if (!importedNamespace) {
return nullptr;
}
// The spec uses an immutable binding here but we have already generated
// bytecode for an indirect binding. Instead, use an indirect binding to
// "*namespace*" slot of the target environment.
Rooted<ModuleEnvironmentObject*> env(
cx, &importedModule->initialEnvironment());
InitNamespaceBinding(cx, env, bindingName, importedNamespace);
}
if (!ns->addBinding(cx, name, importedModule, bindingName)) {
return nullptr;
}
}
// Step 10. Return M.
return ns;
}
void ModuleErrorInfo::setImportedModule(JSContext* cx,
ModuleObject* importedModule) {
imported = importedModule->filename();
}
void ModuleErrorInfo::setCircularImport(JSContext* cx,
ModuleObject* importedModule) {
setImportedModule(cx, importedModule);
isCircular = true;
}
void ModuleErrorInfo::setForAmbiguousImport(JSContext* cx,
ModuleObject* importedModule,
ModuleObject* module1,
ModuleObject* module2) {
setImportedModule(cx, importedModule);
entry1 = module1->filename();
entry2 = module2->filename();
}
static void CreateErrorNumberMessageUTF8(JSContext* cx, unsigned errorNumber,
JSErrorReport* reportOut, ...) {
va_list ap;
va_start(ap, reportOut);
AutoReportFrontendContext fc(cx);
if (!ExpandErrorArgumentsVA(&fc, GetErrorMessage, nullptr, errorNumber,
ArgumentsAreUTF8, reportOut, ap)) {
ReportOutOfMemory(cx);
return;
}
va_end(ap);
}
static void ThrowResolutionError(JSContext* cx, Handle<ModuleObject*> module,
Handle<Value> resolution, Handle<JSAtom*> name,
ModuleErrorInfo* errorInfo) {
MOZ_ASSERT(errorInfo);
auto chars = StringToNewUTF8CharsZ(cx, *name);
if (!chars) {
ReportOutOfMemory(cx);
return;
}
bool isAmbiguous = resolution == StringValue(cx->names().ambiguous);
unsigned errorNumber;
if (errorInfo->isCircular) {
errorNumber = JSMSG_MODULE_CIRCULAR_IMPORT;
} else if (isAmbiguous) {
errorNumber = JSMSG_MODULE_AMBIGUOUS;
} else {
errorNumber = JSMSG_MODULE_NO_EXPORT;
}
JSErrorReport report;
report.isWarning_ = false;
report.errorNumber = errorNumber;
if (errorNumber == JSMSG_MODULE_AMBIGUOUS) {
CreateErrorNumberMessageUTF8(cx, errorNumber, &report, errorInfo->imported,
chars.get(), errorInfo->entry1,
errorInfo->entry2);
} else {
CreateErrorNumberMessageUTF8(cx, errorNumber, &report, errorInfo->imported,
chars.get());
}
Rooted<JSString*> message(cx, report.newMessageString(cx));
if (!message) {
ReportOutOfMemory(cx);
return;
}
const char* file = module->filename();
RootedString filename(
cx, JS_NewStringCopyUTF8Z(cx, JS::ConstUTF8CharsZ(file, strlen(file))));
if (!filename) {
ReportOutOfMemory(cx);
return;
}
RootedValue error(cx);
if (!JS::CreateError(cx, JSEXN_SYNTAXERR, nullptr, filename,
errorInfo->lineNumber, errorInfo->columnNumber, nullptr,
message, JS::NothingHandleValue, &error)) {
ReportOutOfMemory(cx);
return;
}
cx->setPendingException(error, nullptr);
}
// ES2023 16.2.1.6.4 InitializeEnvironment
static bool ModuleInitializeEnvironment(JSContext* cx,
Handle<ModuleObject*> module) {
MOZ_ASSERT(module->status() == ModuleStatus::Linking);
// Step 1. For each ExportEntry Record e of module.[[IndirectExportEntries]],
// do:
Rooted<JSAtom*> exportName(cx);
Rooted<Value> resolution(cx);
for (const ExportEntry& e : module->indirectExportEntries()) {
// Step 1.a. Assert: e.[[ExportName]] is not null.
MOZ_ASSERT(e.exportName());
// Step 1.b. Let resolution be ? module.ResolveExport(e.[[ExportName]]).
exportName = e.exportName();
ModuleErrorInfo errorInfo{e.lineNumber(), e.columnNumber()};
if (!ModuleResolveExport(cx, module, exportName, &resolution, &errorInfo)) {
return false;
}
// Step 1.c. If resolution is either null or AMBIGUOUS, throw a SyntaxError
// exception.
if (!IsResolvedBinding(cx, resolution)) {
ThrowResolutionError(cx, module, resolution, exportName, &errorInfo);
return false;
}
}
// Step 5. Let env be NewModuleEnvironment(realm.[[GlobalEnv]]).
// Step 6. Set module.[[Environment]] to env.
// Note that we have already created the environment by this point.
Rooted<ModuleEnvironmentObject*> env(cx, &module->initialEnvironment());
// Step 7. For each ImportEntry Record in of module.[[ImportEntries]], do:
Rooted<ModuleRequestObject*> moduleRequest(cx);
Rooted<ModuleObject*> importedModule(cx);
Rooted<JSAtom*> importName(cx);
Rooted<JSAtom*> localName(cx);
Rooted<ModuleObject*> sourceModule(cx);
Rooted<JSAtom*> bindingName(cx);
for (const ImportEntry& in : module->importEntries()) {
// Step 7.a. Let importedModule be ! HostResolveImportedModule(module,
// in.[[ModuleRequest]]).
moduleRequest = in.moduleRequest();
importedModule = HostResolveImportedModule(cx, module, moduleRequest,
ModuleStatus::Linking);
if (!importedModule) {
return false;
}
localName = in.localName();
importName = in.importName();
// Step 7.c. If in.[[ImportName]] is namespace-object, then:
if (!importName) {
// Step 7.c.i. Let namespace be ? GetModuleNamespace(importedModule).
Rooted<ModuleNamespaceObject*> ns(
cx, GetOrCreateModuleNamespace(cx, importedModule));
if (!ns) {
return false;
}
// Step 7.c.ii. Perform ! env.CreateImmutableBinding(in.[[LocalName]],
// true). This happens when the environment is created.
// Step 7.c.iii. Perform ! env.InitializeBinding(in.[[LocalName]],
// namespace).
InitNamespaceBinding(cx, env, localName, ns);
} else {
// Step 7.d. Else:
// Step 7.d.i. Let resolution be ?
// importedModule.ResolveExport(in.[[ImportName]]).
ModuleErrorInfo errorInfo{in.lineNumber(), in.columnNumber()};
if (!ModuleResolveExport(cx, importedModule, importName, &resolution,
&errorInfo)) {
return false;
}
// Step 7.d.ii. If resolution is null or ambiguous, throw a SyntaxError
// exception.
if (!IsResolvedBinding(cx, resolution)) {
ThrowResolutionError(cx, module, resolution, importName, &errorInfo);
return false;
}
auto* binding = &resolution.toObject().as<ResolvedBindingObject>();
sourceModule = binding->module();
bindingName = binding->bindingName();
// Step 7.d.iii. If resolution.[[BindingName]] is namespace, then:
if (bindingName == cx->names().star_namespace_star_) {
// Step 7.d.iii.1. Let namespace be ?
// GetModuleNamespace(resolution.[[Module]]).
Rooted<ModuleNamespaceObject*> ns(
cx, GetOrCreateModuleNamespace(cx, sourceModule));
if (!ns) {
return false;
}
// Step 7.d.iii.2. Perform !
// env.CreateImmutableBinding(in.[[LocalName]], true).
// Step 7.d.iii.3. Perform ! env.InitializeBinding(in.[[LocalName]],
// namespace).
//
// This should be InitNamespaceBinding, but we have already generated
// bytecode assuming an indirect binding. Instead, ensure a special
// "*namespace*"" binding exists on the target module's environment. We
// then generate an indirect binding to this synthetic binding.
Rooted<ModuleEnvironmentObject*> sourceEnv(
cx, &sourceModule->initialEnvironment());
InitNamespaceBinding(cx, sourceEnv, bindingName, ns);
if (!env->createImportBinding(cx, localName, sourceModule,
bindingName)) {
return false;
}
} else {
// Step 7.d.iv. Else:
// Step 7.d.iv.1. 1. Perform env.CreateImportBinding(in.[[LocalName]],
// resolution.[[Module]], resolution.[[BindingName]]).
if (!env->createImportBinding(cx, localName, sourceModule,
bindingName)) {
return false;
}
}
}
}
// Steps 8-26.
//
// Some of these do not need to happen for practical purposes. For steps
// 21-23, the bindings that can be handled in a similar way to regulars
// scripts are done separately. Function Declarations are special due to
// hoisting and are handled within this function. See ModuleScope and
// ModuleEnvironmentObject for further details.
// Step 24. For each element d of lexDeclarations, do:
// Step 24.a. For each element dn of the BoundNames of d, do:
// Step 24.a.iii. If d is a FunctionDeclaration, a GeneratorDeclaration, an
// AsyncFunctionDeclaration, or an AsyncGeneratorDeclaration,
// then:
// Step 24.a.iii.1 Let fo be InstantiateFunctionObject of d with arguments env
// and privateEnv.
// Step 24.a.iii.2. Perform ! env.InitializeBinding(dn, fo).
return ModuleObject::instantiateFunctionDeclarations(cx, module);
}
// ES2023 16.2.1.5.1 Link
static bool ModuleLink(JSContext* cx, Handle<ModuleObject*> module) {
// Step 1. Assert: module.[[Status]] is not linking or evaluating.
ModuleStatus status = module->status();
if (status == ModuleStatus::Linking || status == ModuleStatus::Evaluating) {
ThrowUnexpectedModuleStatus(cx, status);
return false;
}
// Step 2. Let stack be a new empty List.
Rooted<ModuleVector> stack(cx);
// Step 3. Let result be Completion(InnerModuleLinking(module, stack, 0)).
size_t ignored;
bool ok = InnerModuleLinking(cx, module, &stack, 0, &ignored);
// Step 4. If result is an abrupt completion, then:
if (!ok) {
// Step 4.a. For each Cyclic Module Record m of stack, do:
for (ModuleObject* m : stack) {
// Step 4.a.i. Assert: m.[[Status]] is linking.
MOZ_ASSERT(m->status() == ModuleStatus::Linking);
// Step 4.a.ii. Set m.[[Status]] to unlinked.
m->setStatus(ModuleStatus::Unlinked);
m->clearDfsIndexes();
}
// Step 4.b. Assert: module.[[Status]] is unlinked.
MOZ_ASSERT(module->status() == ModuleStatus::Unlinked);
// Step 4.c.
return false;
}
// Step 5. Assert: module.[[Status]] is linked, evaluating-async, or
// evaluated.
MOZ_ASSERT(module->status() == ModuleStatus::Linked ||
module->status() == ModuleStatus::EvaluatingAsync ||
module->status() == ModuleStatus::Evaluated);
// Step 6. Assert: stack is empty.
MOZ_ASSERT(stack.empty());
// Step 7. Return unused.
return true;
}
// ES2023 16.2.1.5.1.1 InnerModuleLinking
static bool InnerModuleLinking(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> stack, size_t index,
size_t* indexOut) {
// Step 1. If module is not a Cyclic Module Record, then
if (!module->hasCyclicModuleFields()) {
// Step 1.a. Perform ? module.Link(). (Skipped)
// Step 2.b. Return index.
*indexOut = index;
return true;
}
// Step 2. If module.[[Status]] is linking, linked, evaluating-async, or
// evaluated, then:
if (module->status() == ModuleStatus::Linking ||
module->status() == ModuleStatus::Linked ||
module->status() == ModuleStatus::EvaluatingAsync ||
module->status() == ModuleStatus::Evaluated) {
// Step 2.a. Return index.
*indexOut = index;
return true;
}
// Step 3. Assert: module.[[Status]] is unlinked.
if (module->status() != ModuleStatus::Unlinked) {
ThrowUnexpectedModuleStatus(cx, module->status());
return false;
}
// Step 8. Append module to stack.
// Do this before changing the status so that we can recover on failure.
if (!stack.append(module)) {
ReportOutOfMemory(cx);
return false;
}
// Step 4. Set module.[[Status]] to linking.
module->setStatus(ModuleStatus::Linking);
// Step 5. Set module.[[DFSIndex]] to index.
module->setDfsIndex(index);
// Step 6. Set module.[[DFSAncestorIndex]] to index.
module->setDfsAncestorIndex(index);
// Step 7. Set index to index + 1.
index++;
// Step 9. For each String required that is an element of
// module.[[RequestedModules]], do:
Rooted<ModuleRequestObject*> moduleRequest(cx);
Rooted<ModuleObject*> requiredModule(cx);
for (const RequestedModule& request : module->requestedModules()) {
moduleRequest = request.moduleRequest();
// According to the spec, this should be in InnerModuleLoading, but
// currently, our module code is not aligned with the spec text.
if (moduleRequest->hasFirstUnsupportedAttributeKey()) {
UniqueChars printableKey = AtomToPrintableString(
cx, moduleRequest->getFirstUnsupportedAttributeKey());
JS_ReportErrorNumberASCII(
cx, GetErrorMessage, nullptr,
JSMSG_IMPORT_ATTRIBUTES_STATIC_IMPORT_UNSUPPORTED_ATTRIBUTE,
printableKey ? printableKey.get() : "");
return false;
}
// Step 9.a. Let requiredModule be ? HostResolveImportedModule(module,
// required).
requiredModule = HostResolveImportedModule(cx, module, moduleRequest,
ModuleStatus::Unlinked);
if (!requiredModule) {
return false;
}
// Step 9.b. Set index to ? InnerModuleLinking(requiredModule, stack,
// index).
if (!InnerModuleLinking(cx, requiredModule, stack, index, &index)) {
return false;
}
// Step 9.c. If requiredModule is a Cyclic Module Record, then:
if (requiredModule->hasCyclicModuleFields()) {
// Step 9.c.i. Assert: requiredModule.[[Status]] is either linking,
// linked,
// evaluating-async, or evaluated.
MOZ_ASSERT(requiredModule->status() == ModuleStatus::Linking ||
requiredModule->status() == ModuleStatus::Linked ||
requiredModule->status() == ModuleStatus::EvaluatingAsync ||
requiredModule->status() == ModuleStatus::Evaluated);
// Step 9.c.ii. Assert: requiredModule.[[Status]] is linking if and only
// if
// requiredModule is in stack.
MOZ_ASSERT((requiredModule->status() == ModuleStatus::Linking) ==
ContainsElement(stack, requiredModule));
// Step 9.c.iii. If requiredModule.[[Status]] is linking, then:
if (requiredModule->status() == ModuleStatus::Linking) {
// Step 9.c.iii.1. Set module.[[DFSAncestorIndex]] to
// min(module.[[DFSAncestorIndex]],
// requiredModule.[[DFSAncestorIndex]]).
module->setDfsAncestorIndex(std::min(
module->dfsAncestorIndex(), requiredModule->dfsAncestorIndex()));
}
}
}
// Step 10. Perform ? module.InitializeEnvironment().
if (!ModuleInitializeEnvironment(cx, module)) {
return false;
}
// Step 11. Assert: module occurs exactly once in stack.
MOZ_ASSERT(CountElements(stack, module) == 1);
// Step 12. Assert: module.[[DFSAncestorIndex]] <= module.[[DFSIndex]].
MOZ_ASSERT(module->dfsAncestorIndex() <= module->dfsIndex());
// Step 13. If module.[[DFSAncestorIndex]] = module.[[DFSIndex]], then
if (module->dfsAncestorIndex() == module->dfsIndex()) {
// Step 13.a.
bool done = false;
// Step 13.b. Repeat, while done is false:
while (!done) {
// Step 13.b.i. Let requiredModule be the last element in stack.
// Step 13.b.ii. Remove the last element of stack.
requiredModule = stack.popCopy();
// Step 13.b.iv. Set requiredModule.[[Status]] to linked.
requiredModule->setStatus(ModuleStatus::Linked);
// Step 13.b.v. If requiredModule and module are the same Module Record,
// set done to true.
done = requiredModule == module;
}
}
// Step 14. Return index.
*indexOut = index;
return true;
}
static bool SyntheticModuleEvaluate(JSContext* cx,
Handle<ModuleObject*> moduleArg,
MutableHandle<Value> result) {
// Steps 1-12 happens elsewhere in the engine.
// Step 13. Let pc be ! NewPromiseCapability(%Promise%).
Rooted<PromiseObject*> resultPromise(cx, CreatePromiseObjectForAsync(cx));
if (!resultPromise) {
return false;
}
// Step 14. IfAbruptRejectPromise(result, pc) (Skipped)
// 15. Perform ! pc.[[Resolve]](result).
if (!AsyncFunctionReturned(cx, resultPromise, result)) {
return false;
}
// 16. Return pc.[[Promise]].
result.set(ObjectValue(*resultPromise));
return true;
}
// ES2023 16.2.1.5.2 Evaluate
static bool ModuleEvaluate(JSContext* cx, Handle<ModuleObject*> moduleArg,
MutableHandle<Value> result) {
Rooted<ModuleObject*> module(cx, moduleArg);
// Step 2. Assert: module.[[Status]] is linked, evaluating-async, or
// evaluated.
ModuleStatus status = module->status();
if (status != ModuleStatus::Linked &&
status != ModuleStatus::EvaluatingAsync &&
status != ModuleStatus::Evaluated) {
ThrowUnexpectedModuleStatus(cx, status);
return false;
}
// Note: we return early in the error case, as the spec assumes we can get the
// cycle root of |module| which may not be available.
if (module->hadEvaluationError()) {
Rooted<PromiseObject*> capability(cx);
if (!module->hasTopLevelCapability()) {
capability = ModuleObject::createTopLevelCapability(cx, module);
if (!capability) {
return false;
}
Rooted<Value> error(cx, module->evaluationError());
if (!ModuleObject::topLevelCapabilityReject(cx, module, error)) {
return false;
}
}
capability = module->topLevelCapability();
MOZ_ASSERT(JS::GetPromiseState(capability) == JS::PromiseState::Rejected);
MOZ_ASSERT(JS::GetPromiseResult(capability) == module->evaluationError());
result.set(ObjectValue(*capability));
return true;
}
// Step 3. If module.[[Status]] is evaluating-async or evaluated, set module
// to module.[[CycleRoot]].
if (module->status() == ModuleStatus::EvaluatingAsync ||
module->status() == ModuleStatus::Evaluated) {
module = module->getCycleRoot();
}
// Step 4. If module.[[TopLevelCapability]] is not empty, then:
if (module->hasTopLevelCapability()) {
// Step 4.a. Return module.[[TopLevelCapability]].[[Promise]].
result.set(ObjectValue(*module->topLevelCapability()));
return true;
}
// Step 5. Let stack be a new empty List.
Rooted<ModuleVector> stack(cx);
// Step 6. Let capability be ! NewPromiseCapability(%Promise%).
// Step 7. Set module.[[TopLevelCapability]] to capability.
Rooted<PromiseObject*> capability(
cx, ModuleObject::createTopLevelCapability(cx, module));
if (!capability) {
return false;
}
// Step 8. Let result be Completion(InnerModuleEvaluation(module, stack, 0)).
size_t ignored;
bool ok = InnerModuleEvaluation(cx, module, &stack, 0, &ignored);
// Step 9. f result is an abrupt completion, then:
if (!ok) {
// Attempt to take any pending exception, but make sure we still handle
// uncatchable exceptions.
Rooted<Value> error(cx);
if (cx->isExceptionPending()) {
std::ignore = cx->getPendingException(&error);
cx->clearPendingException();
}
// Step 9.a. For each Cyclic Module Record m of stack, do
for (ModuleObject* m : stack) {
// Step 9.a.i. Assert: m.[[Status]] is evaluating.
MOZ_ASSERT(m->status() == ModuleStatus::Evaluating);
// Step 9.a.ii. Set m.[[Status]] to evaluated.
// Step 9.a.iii. Set m.[[EvaluationError]] to result.
m->setEvaluationError(error);
}
// Handle OOM when appending to the stack or over-recursion errors.
if (stack.empty() && !module->hadEvaluationError()) {
module->setEvaluationError(error);
}
// Step 9.b. Assert: module.[[Status]] is evaluated.
MOZ_ASSERT(module->status() == ModuleStatus::Evaluated);
// Step 9.c. Assert: module.[[EvaluationError]] is result.
MOZ_ASSERT(module->evaluationError() == error);
// Step 9.d. Perform ! Call(capability.[[Reject]], undefined,
// result.[[Value]]).
if (!ModuleObject::topLevelCapabilityReject(cx, module, error)) {
return false;
}
} else {
// Step 10. Else:
// Step 10.a. Assert: module.[[Status]] is evaluating-async or evaluated.
MOZ_ASSERT(module->status() == ModuleStatus::EvaluatingAsync ||
module->status() == ModuleStatus::Evaluated);
// Step 10.b. Assert: module.[[EvaluationError]] is empty.
MOZ_ASSERT(!module->hadEvaluationError());
// Step 10.c. If module.[[AsyncEvaluation]] is false, then:
if (module->status() == ModuleStatus::Evaluated) {
// Step 10.c.ii. Perform ! Call(capability.[[Resolve]], undefined,
// undefined).
if (!ModuleObject::topLevelCapabilityResolve(cx, module)) {
return false;
}
}
// Step 10.d. Assert: stack is empty.
MOZ_ASSERT(stack.empty());
}
// Step 11. Return capability.[[Promise]].
result.set(ObjectValue(*capability));
return true;
}
// 16.2.1.5.2.1 InnerModuleEvaluation
static bool InnerModuleEvaluation(JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> stack,
size_t index, size_t* indexOut) {
// Step 1: If module is not a Cyclic Module Record, then
if (!module->hasCyclicModuleFields()) {
// Step 1.a. Let promise be ! module.Evaluate(). (Skipped)
// Step 1.b. Assert: promise.[[PromiseState]] is not pending. (Skipped)
// Step 1.c. If promise.[[PromiseState]] is rejected, then (Skipped)
// Step 1.c.i Return ThrowCompletion(promise.[[PromiseResult]]). (Skipped)
// Step 1.d. Return index.
*indexOut = index;
return true;
}
// Step 2. If module.[[Status]] is evaluating-async or evaluated, then:
if (module->status() == ModuleStatus::EvaluatingAsync ||
module->status() == ModuleStatus::Evaluated) {
// Step 2.a. If module.[[EvaluationError]] is empty, return index.
if (!module->hadEvaluationError()) {
*indexOut = index;
return true;
}
// Step 2.b. Otherwise, return ? module.[[EvaluationError]].
Rooted<Value> error(cx, module->evaluationError());
cx->setPendingException(error, ShouldCaptureStack::Maybe);
return false;
}
// Step 3. If module.[[Status]] is evaluating, return index.
if (module->status() == ModuleStatus::Evaluating) {
*indexOut = index;
return true;
}
// Step 4. Assert: module.[[Status]] is linked.
MOZ_ASSERT(module->status() == ModuleStatus::Linked);
// Step 10. Append module to stack.
// Do this before changing the status so that we can recover on failure.
if (!stack.append(module)) {
ReportOutOfMemory(cx);
return false;
}
// Step 5. Set module.[[Status]] to evaluating.
module->setStatus(ModuleStatus::Evaluating);
// Step 6. Set module.[[DFSIndex]] to index.
module->setDfsIndex(index);
// Step 7. Set module.[[DFSAncestorIndex]] to index.
module->setDfsAncestorIndex(index);
// Step 8. Set module.[[PendingAsyncDependencies]] to 0.
module->setPendingAsyncDependencies(0);
// Step 9. Set index to index + 1.
index++;
// Step 11. For each String required of module.[[RequestedModules]], do:
Rooted<ModuleRequestObject*> required(cx);
Rooted<ModuleObject*> requiredModule(cx);
for (const RequestedModule& request : module->requestedModules()) {
required = request.moduleRequest();
// Step 11.a. Let requiredModule be ! HostResolveImportedModule(module,
// required).
// Step 11.b. NOTE: Link must be completed successfully prior to invoking
// this method, so every requested module is guaranteed to
// resolve successfully.
requiredModule =
HostResolveImportedModule(cx, module, required, ModuleStatus::Linked);
if (!requiredModule) {
return false;
}
// Step 11.c. Set index to ? InnerModuleEvaluation(requiredModule, stack,
// index).
if (!InnerModuleEvaluation(cx, requiredModule, stack, index, &index)) {
return false;
}
// Step 11.d. If requiredModule is a Cyclic Module Record, then:
if (requiredModule->hasCyclicModuleFields()) {
// Step 11.d.i. Assert: requiredModule.[[Status]] is either evaluating,
// evaluating-async, or evaluated.
MOZ_ASSERT(requiredModule->status() == ModuleStatus::Evaluating ||
requiredModule->status() == ModuleStatus::EvaluatingAsync ||
requiredModule->status() == ModuleStatus::Evaluated);
// Step 11.d.ii. Assert: requiredModule.[[Status]] is evaluating if and
// only if requiredModule is in stack.
MOZ_ASSERT((requiredModule->status() == ModuleStatus::Evaluating) ==
ContainsElement(stack, requiredModule));
// Step 11.d.iii. If requiredModule.[[Status]] is evaluating, then:
if (requiredModule->status() == ModuleStatus::Evaluating) {
// Step 11.d.iii.1. Set module.[[DFSAncestorIndex]] to
// min(module.[[DFSAncestorIndex]],
// requiredModule.[[DFSAncestorIndex]]).
module->setDfsAncestorIndex(std::min(
module->dfsAncestorIndex(), requiredModule->dfsAncestorIndex()));
} else {
// Step 11.d.iv. Else:
// Step 11.d.iv.1. Set requiredModule to requiredModule.[[CycleRoot]].
requiredModule = requiredModule->getCycleRoot();
// Step 11.d.iv.2. Assert: requiredModule.[[Status]] is evaluating-async
// or evaluated.
MOZ_ASSERT(requiredModule->status() >= ModuleStatus::EvaluatingAsync ||
requiredModule->status() == ModuleStatus::Evaluated);
// Step 11.d.iv.3. If requiredModule.[[EvaluationError]] is not empty,
// return ? requiredModule.[[EvaluationError]].
if (requiredModule->hadEvaluationError()) {
Rooted<Value> error(cx, requiredModule->evaluationError());
cx->setPendingException(error, ShouldCaptureStack::Maybe);
return false;
}
}
// Step 11.d.v. If requiredModule.[[AsyncEvaluation]] is true, then:
if (requiredModule->isAsyncEvaluating() &&
requiredModule->status() != ModuleStatus::Evaluated) {
// Step 11.d.v.2. Append module to
// requiredModule.[[AsyncParentModules]].
if (!ModuleObject::appendAsyncParentModule(cx, requiredModule,
module)) {
return false;
}
// Step 11.d.v.1. Set module.[[PendingAsyncDependencies]] to
// module.[[PendingAsyncDependencies]] + 1.
module->setPendingAsyncDependencies(module->pendingAsyncDependencies() +
1);
}
}
}
// Step 12. If module.[[PendingAsyncDependencies]] > 0 or module.[[HasTLA]] is
// true, then:
if (module->pendingAsyncDependencies() > 0 || module->hasTopLevelAwait()) {
// Step 12.a. Assert: module.[[AsyncEvaluation]] is false and was never
// previously set to true.
MOZ_ASSERT(!module->isAsyncEvaluating());
// Step 12.b. Set module.[[AsyncEvaluation]] to true.
// Step 12.c. NOTE: The order in which module records have their
// [[AsyncEvaluation]] fields transition to true is
// significant. (See 16.2.1.5.2.4.)
module->setAsyncEvaluating();
// Step 12.d. If module.[[PendingAsyncDependencies]] is 0, perform
// ExecuteAsyncModule(module).
if (module->pendingAsyncDependencies() == 0) {
if (!ExecuteAsyncModule(cx, module)) {
return false;
}
}
} else {
// Step 13. Otherwise, perform ? module.ExecuteModule().
if (!ModuleObject::execute(cx, module)) {
return false;
}
}
// Step 14. Assert: module occurs exactly once in stack.
MOZ_ASSERT(CountElements(stack, module) == 1);
// Step 15. Assert: module.[[DFSAncestorIndex]] <= module.[[DFSIndex]].
MOZ_ASSERT(module->dfsAncestorIndex() <= module->dfsIndex());
// Step 16. If module.[[DFSAncestorIndex]] = module.[[DFSIndex]], then:
if (module->dfsAncestorIndex() == module->dfsIndex()) {
// Step 16.a. Let done be false.
bool done = false;
// Step 16.b. Repeat, while done is false:
while (!done) {
// Step 16.b.i. Let requiredModule be the last element in stack.
// Step 16.b.ii. Remove the last element of stack.
requiredModule = stack.popCopy();
// Step 16.b.iv. If requiredModule.[[AsyncEvaluation]] is false, set
// requiredModule.[[Status]] to evaluated.
if (!requiredModule->isAsyncEvaluating()) {
requiredModule->setStatus(ModuleStatus::Evaluated);
} else {
// Step 16.b.v. Otherwise, set requiredModule.[[Status]] to
// evaluating-async.
requiredModule->setStatus(ModuleStatus::EvaluatingAsync);
}
// Step 16.b.vi. If requiredModule and module are the same Module Record,
// set done to true.
done = requiredModule == module;
// Step 16.b.vii. Set requiredModule.[[CycleRoot]] to module.
requiredModule->setCycleRoot(module);
}
}
// Step 17. Return index.
*indexOut = index;
return true;
}
// ES2023 16.2.1.5.2.2 ExecuteAsyncModule
static bool ExecuteAsyncModule(JSContext* cx, Handle<ModuleObject*> module) {
// Step 1. Assert: module.[[Status]] is evaluating or evaluating-async.
MOZ_ASSERT(module->status() == ModuleStatus::Evaluating ||
module->status() == ModuleStatus::EvaluatingAsync);
// Step 2. Assert: module.[[HasTLA]] is true.
MOZ_ASSERT(module->hasTopLevelAwait());
// Steps 3 - 8 are performed by the AsyncAwait opcode.
// Step 9. Perform ! module.ExecuteModule(capability).
// Step 10. Return unused.
return ModuleObject::execute(cx, module);
}
// ES2023 16.2.1.5.2.3 GatherAvailableAncestors
static bool GatherAvailableModuleAncestors(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<ModuleVector> execList) {
MOZ_ASSERT(module->status() == ModuleStatus::EvaluatingAsync);
// Step 1. For each Cyclic Module Record m of module.[[AsyncParentModules]],
// do:
Rooted<ListObject*> asyncParentModules(cx, module->asyncParentModules());
Rooted<ModuleObject*> m(cx);
for (uint32_t i = 0; i != asyncParentModules->length(); i++) {
m = &asyncParentModules->getDenseElement(i).toObject().as<ModuleObject>();
// Step 1.a. If execList does not contain m and
// m.[[CycleRoot]].[[EvaluationError]] is empty, then:
//
// Note: we also check whether m.[[EvaluationError]] is empty since an error
// in synchronous execution can prevent the CycleRoot field from being set.
if (!m->hadEvaluationError() && !m->getCycleRoot()->hadEvaluationError() &&
!ContainsElement(execList, m)) {
// Step 1.a.i. Assert: m.[[Status]] is evaluating-async.
MOZ_ASSERT(m->status() == ModuleStatus::EvaluatingAsync);
// Step 1.a.ii. Assert: m.[[EvaluationError]] is empty.
MOZ_ASSERT(!m->hadEvaluationError());
// Step 1.a.iii. Assert: m.[[AsyncEvaluation]] is true.
MOZ_ASSERT(m->isAsyncEvaluating());
// Step 1.a.iv. Assert: m.[[PendingAsyncDependencies]] > 0.
MOZ_ASSERT(m->pendingAsyncDependencies() > 0);
// Step 1.a.v. Set m.[[PendingAsyncDependencies]] to
// m.[[PendingAsyncDependencies]] - 1.
m->setPendingAsyncDependencies(m->pendingAsyncDependencies() - 1);
// Step 1.a.vi. If m.[[PendingAsyncDependencies]] = 0, then:
if (m->pendingAsyncDependencies() == 0) {
// Step 1.a.vi.1. Append m to execList.
if (!execList.append(m)) {
return false;
}
// Step 1.a.vi.2. If m.[[HasTLA]] is false, perform
// GatherAvailableAncestors(m, execList).
if (!m->hasTopLevelAwait() &&
!GatherAvailableModuleAncestors(cx, m, execList)) {
return false;
}
}
}
}
// Step 2. Return unused.
return true;
}
struct EvalOrderComparator {
bool operator()(ModuleObject* a, ModuleObject* b, bool* lessOrEqualp) {
int32_t result = int32_t(a->getAsyncEvaluatingPostOrder()) -
int32_t(b->getAsyncEvaluatingPostOrder());
*lessOrEqualp = (result <= 0);
return true;
}
};
static void RejectExecutionWithPendingException(JSContext* cx,
Handle<ModuleObject*> module) {
// If there is no exception pending then we have been interrupted or have
// OOM'd and all bets are off. We reject the execution by throwing
// undefined. Not much more we can do.
RootedValue exception(cx);
if (cx->isExceptionPending()) {
std::ignore = cx->getPendingException(&exception);
}
cx->clearPendingException();
AsyncModuleExecutionRejected(cx, module, exception);
}
// ES2023 16.2.1.5.2.4 AsyncModuleExecutionFulfilled
void js::AsyncModuleExecutionFulfilled(JSContext* cx,
Handle<ModuleObject*> module) {
// Step 1. If module.[[Status]] is evaluated, then:
if (module->status() == ModuleStatus::Evaluated) {
// Step 1.a. Assert: module.[[EvaluationError]] is not empty.
MOZ_ASSERT(module->hadEvaluationError());
// Step 1.b. Return unused.
return;
}
// Step 2. Assert: module.[[Status]] is evaluating-async.
MOZ_ASSERT(module->status() == ModuleStatus::EvaluatingAsync);
// Step 3. Assert: module.[[AsyncEvaluation]] is true.
MOZ_ASSERT(module->isAsyncEvaluating());
// Step 4. Assert: module.[[EvaluationError]] is empty.
MOZ_ASSERT(!module->hadEvaluationError());
// The following steps are performed in a different order from the
// spec. Gather available module ancestors before mutating the module object
// as this can fail in our implementation.
// Step 8. Let execList be a new empty List.
Rooted<ModuleVector> execList(cx);
// Step 9. Perform GatherAvailableAncestors(module, execList).
if (!GatherAvailableModuleAncestors(cx, module, &execList)) {
RejectExecutionWithPendingException(cx, module);
return;
}
// Step 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.
Rooted<ModuleVector> scratch(cx);
if (!scratch.resize(execList.length())) {
ReportOutOfMemory(cx);
RejectExecutionWithPendingException(cx, module);
return;
}
MOZ_ALWAYS_TRUE(MergeSort(execList.begin(), execList.length(),
scratch.begin(), EvalOrderComparator()));
// Step 11. Assert: All elements of sortedExecList have their
// [[AsyncEvaluation]] field set to true,
// [[PendingAsyncDependencies]] field set to 0, and
// [[EvaluationError]] field set to empty.
#ifdef DEBUG
for (ModuleObject* m : execList) {
MOZ_ASSERT(m->isAsyncEvaluating());
MOZ_ASSERT(m->pendingAsyncDependencies() == 0);
MOZ_ASSERT(!m->hadEvaluationError());
}
#endif
// Return to original order of steps.
ModuleObject::onTopLevelEvaluationFinished(module);
// Step 6. Set module.[[Status]] to evaluated.
module->setStatus(ModuleStatus::Evaluated);
module->clearAsyncEvaluatingPostOrder();
// Step 7. If module.[[TopLevelCapability]] is not empty, then:
if (module->hasTopLevelCapability()) {
// Step 7.a. Assert: module.[[CycleRoot]] is module.
MOZ_ASSERT(module->getCycleRoot() == module);
// Step 7.b. Perform ! Call(module.[[TopLevelCapability]].[[Resolve]],
// undefined, undefined).
if (!ModuleObject::topLevelCapabilityResolve(cx, module)) {
// If Resolve fails, there's nothing more we can do here.
cx->clearPendingException();
}
}
// Step 12. For each Cyclic Module Record m of sortedExecList, do:
Rooted<ModuleObject*> m(cx);
for (ModuleObject* obj : execList) {
m = obj;
// Step 12.a. If m.[[Status]] is evaluated, then:
if (m->status() == ModuleStatus::Evaluated) {
// Step 12.a.i. Assert: m.[[EvaluationError]] is not empty.
MOZ_ASSERT(m->hadEvaluationError());
} else if (m->hasTopLevelAwait()) {
// Step 12.b. Else if m.[[HasTLA]] is true, then:
// Step 12.b.i. Perform ExecuteAsyncModule(m).
if (!ExecuteAsyncModule(cx, m)) {
MOZ_ASSERT(cx->isThrowingOutOfMemory() || cx->isThrowingOverRecursed());
cx->clearPendingException();
}
} else {
// Step 12.c. Else:
// Step 12.c.i. Let result be m.ExecuteModule().
bool ok = ModuleObject::execute(cx, m);
// Step 12.c.ii. If result is an abrupt completion, then:
if (!ok) {
// Step 12.c.ii.1. Perform AsyncModuleExecutionRejected(m,
// result.[[Value]]).
RejectExecutionWithPendingException(cx, m);
} else {
// Step 12.c.iii. Else:
// Step 12.c.iii.1. Set m.[[Status]] to evaluated.
m->setStatus(ModuleStatus::Evaluated);
m->clearAsyncEvaluatingPostOrder();
// Step 12.c.iii.2. If m.[[TopLevelCapability]] is not empty, then:
if (m->hasTopLevelCapability()) {
// Step 12.c.iii.2.a. Assert: m.[[CycleRoot]] is m.
MOZ_ASSERT(m->getCycleRoot() == m);
// Step 12.c.iii.2.b. Perform !
// Call(m.[[TopLevelCapability]].[[Resolve]],
// undefined, undefined).
if (!ModuleObject::topLevelCapabilityResolve(cx, m)) {
// If Resolve fails, there's nothing more we can do here.
cx->clearPendingException();
}
}
}
}
}
// Step 13. Return unused.
}
// ES2023 16.2.1.5.2.5 AsyncModuleExecutionRejected
void js::AsyncModuleExecutionRejected(JSContext* cx,
Handle<ModuleObject*> module,
HandleValue error) {
// Step 1. If module.[[Status]] is evaluated, then:
if (module->status() == ModuleStatus::Evaluated) {
// Step 1.a. Assert: module.[[EvaluationError]] is not empty
MOZ_ASSERT(module->hadEvaluationError());
// Step 1.b. Return unused.
return;
}
// Step 2. Assert: module.[[Status]] is evaluating-async.
MOZ_ASSERT(module->status() == ModuleStatus::EvaluatingAsync);
// Step 3. Assert: module.[[AsyncEvaluation]] is true.
MOZ_ASSERT(module->isAsyncEvaluating());
// Step 4. 4. Assert: module.[[EvaluationError]] is empty.
MOZ_ASSERT(!module->hadEvaluationError());
ModuleObject::onTopLevelEvaluationFinished(module);
// Step 5. Set module.[[EvaluationError]] to ThrowCompletion(error).
module->setEvaluationError(error);
// Step 6. Set module.[[Status]] to evaluated.
MOZ_ASSERT(module->status() == ModuleStatus::Evaluated);
module->clearAsyncEvaluatingPostOrder();
// Step 7. For each Cyclic Module Record m of module.[[AsyncParentModules]],
// do:
Rooted<ListObject*> parents(cx, module->asyncParentModules());
Rooted<ModuleObject*> parent(cx);
for (uint32_t i = 0; i < parents->length(); i++) {
parent = &parents->get(i).toObject().as<ModuleObject>();
// Step 7.a. Perform AsyncModuleExecutionRejected(m, error).
AsyncModuleExecutionRejected(cx, parent, error);
}
// Step 8. If module.[[TopLevelCapability]] is not empty, then:
if (module->hasTopLevelCapability()) {
// Step 8.a. Assert: module.[[CycleRoot]] is module.
MOZ_ASSERT(module->getCycleRoot() == module);
// Step 8.b. Perform ! Call(module.[[TopLevelCapability]].[[Reject]],
// undefined, error).
if (!ModuleObject::topLevelCapabilityReject(cx, module, error)) {
// If Reject fails, there's nothing more we can do here.
cx->clearPendingException();
}
}
// Step 9. Return unused.
}