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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
#include "builtin/ModuleObject.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/EnumSet.h"
#include "mozilla/ScopeExit.h"
#include "builtin/Promise.h"
#include "builtin/SelfHostingDefines.h"
#include "frontend/ParseNode.h"
#include "frontend/ParserAtom.h" // TaggedParserAtomIndex, ParserAtomsTable, ParserAtom
#include "frontend/SharedContext.h"
#include "frontend/Stencil.h"
#include "gc/GCContext.h"
#include "gc/Tracer.h"
#include "js/ColumnNumber.h" // JS::ColumnNumberOneOrigin, JS::LimitedColumnNumberOneOrigin
#include "js/friend/ErrorMessages.h" // JSMSG_*
#include "js/Modules.h" // JS::GetModulePrivate, JS::ModuleDynamicImportHook, JS::ModuleType
#include "vm/EqualityOperations.h" // js::SameValue
#include "vm/Interpreter.h" // Execute, Lambda, ReportRuntimeLexicalError
#include "vm/ModuleBuilder.h" // js::ModuleBuilder
#include "vm/Modules.h"
#include "vm/PlainObject.h" // js::PlainObject
#include "vm/PromiseObject.h" // js::PromiseObject
#include "vm/SharedStencil.h" // js::GCThingIndex
#include "builtin/HandlerFunction-inl.h" // js::ExtraValueFromHandler, js::NewHandler{,WithExtraValue}, js::TargetFromHandler
#include "gc/GCContext-inl.h"
#include "vm/EnvironmentObject-inl.h" // EnvironmentObject::setAliasedBinding
#include "vm/JSObject-inl.h"
#include "vm/JSScript-inl.h"
#include "vm/List-inl.h"
#include "vm/NativeObject-inl.h"
using namespace js;
using mozilla::Maybe;
using mozilla::Nothing;
using mozilla::Some;
using mozilla::Span;
static_assert(ModuleStatus::Unlinked < ModuleStatus::Linking &&
ModuleStatus::Linking < ModuleStatus::Linked &&
ModuleStatus::Linked < ModuleStatus::Evaluating &&
ModuleStatus::Evaluating < ModuleStatus::EvaluatingAsync &&
ModuleStatus::EvaluatingAsync < ModuleStatus::Evaluated &&
ModuleStatus::Evaluated < ModuleStatus::Evaluated_Error,
"Module statuses are ordered incorrectly");
static Value StringOrNullValue(JSString* maybeString) {
return maybeString ? StringValue(maybeString) : NullValue();
}
#define DEFINE_ATOM_ACCESSOR_METHOD(cls, name, slot) \
JSAtom* cls::name() const { \
Value value = getReservedSlot(slot); \
return &value.toString()->asAtom(); \
}
#define DEFINE_ATOM_OR_NULL_ACCESSOR_METHOD(cls, name, slot) \
JSAtom* cls::name() const { \
Value value = getReservedSlot(slot); \
if (value.isNull()) { \
return nullptr; \
} \
return &value.toString()->asAtom(); \
}
#define DEFINE_UINT32_ACCESSOR_METHOD(cls, name, slot) \
uint32_t cls::name() const { \
Value value = getReservedSlot(slot); \
MOZ_ASSERT(value.toNumber() >= 0); \
if (value.isInt32()) { \
return value.toInt32(); \
} \
return JS::ToUint32(value.toDouble()); \
}
///////////////////////////////////////////////////////////////////////////
// ImportEntry
ImportEntry::ImportEntry(Handle<ModuleRequestObject*> moduleRequest,
Handle<JSAtom*> maybeImportName,
Handle<JSAtom*> localName, uint32_t lineNumber,
JS::ColumnNumberOneOrigin columnNumber)
: moduleRequest_(moduleRequest),
importName_(maybeImportName),
localName_(localName),
lineNumber_(lineNumber),
columnNumber_(columnNumber) {}
void ImportEntry::trace(JSTracer* trc) {
TraceEdge(trc, &moduleRequest_, "ImportEntry::moduleRequest_");
TraceNullableEdge(trc, &importName_, "ImportEntry::importName_");
TraceNullableEdge(trc, &localName_, "ImportEntry::localName_");
}
///////////////////////////////////////////////////////////////////////////
// ExportEntry
ExportEntry::ExportEntry(Handle<JSAtom*> maybeExportName,
Handle<ModuleRequestObject*> moduleRequest,
Handle<JSAtom*> maybeImportName,
Handle<JSAtom*> maybeLocalName, uint32_t lineNumber,
JS::ColumnNumberOneOrigin columnNumber)
: exportName_(maybeExportName),
moduleRequest_(moduleRequest),
importName_(maybeImportName),
localName_(maybeLocalName),
lineNumber_(lineNumber),
columnNumber_(columnNumber) {
// Line and column numbers are optional for export entries since direct
// entries are checked at parse time.
}
void ExportEntry::trace(JSTracer* trc) {
TraceNullableEdge(trc, &exportName_, "ExportEntry::exportName_");
TraceNullableEdge(trc, &moduleRequest_, "ExportEntry::moduleRequest_");
TraceNullableEdge(trc, &importName_, "ExportEntry::importName_");
TraceNullableEdge(trc, &localName_, "ExportEntry::localName_");
}
///////////////////////////////////////////////////////////////////////////
// RequestedModule
/* static */
RequestedModule::RequestedModule(Handle<ModuleRequestObject*> moduleRequest,
uint32_t lineNumber,
JS::ColumnNumberOneOrigin columnNumber)
: moduleRequest_(moduleRequest),
lineNumber_(lineNumber),
columnNumber_(columnNumber) {}
void RequestedModule::trace(JSTracer* trc) {
TraceEdge(trc, &moduleRequest_, "ExportEntry::moduleRequest_");
}
///////////////////////////////////////////////////////////////////////////
// ResolvedBindingObject
/* static */ const JSClass ResolvedBindingObject::class_ = {
"ResolvedBinding",
JSCLASS_HAS_RESERVED_SLOTS(ResolvedBindingObject::SlotCount)};
ModuleObject* ResolvedBindingObject::module() const {
Value value = getReservedSlot(ModuleSlot);
return &value.toObject().as<ModuleObject>();
}
JSAtom* ResolvedBindingObject::bindingName() const {
Value value = getReservedSlot(BindingNameSlot);
return &value.toString()->asAtom();
}
/* static */
bool ResolvedBindingObject::isInstance(HandleValue value) {
return value.isObject() && value.toObject().is<ResolvedBindingObject>();
}
/* static */
ResolvedBindingObject* ResolvedBindingObject::create(
JSContext* cx, Handle<ModuleObject*> module, Handle<JSAtom*> bindingName) {
ResolvedBindingObject* self =
NewObjectWithGivenProto<ResolvedBindingObject>(cx, nullptr);
if (!self) {
return nullptr;
}
self->initReservedSlot(ModuleSlot, ObjectValue(*module));
self->initReservedSlot(BindingNameSlot, StringValue(bindingName));
return self;
}
///////////////////////////////////////////////////////////////////////////
// ModuleRequestObject
/* static */ const JSClass ModuleRequestObject::class_ = {
"ModuleRequest",
JSCLASS_HAS_RESERVED_SLOTS(ModuleRequestObject::SlotCount)};
DEFINE_ATOM_OR_NULL_ACCESSOR_METHOD(ModuleRequestObject, specifier,
SpecifierSlot)
ArrayObject* ModuleRequestObject::attributes() const {
JSObject* obj = getReservedSlot(AttributesSlot).toObjectOrNull();
if (!obj) {
return nullptr;
}
return &obj->as<ArrayObject>();
}
bool ModuleRequestObject::hasAttributes() const {
return !getReservedSlot(ModuleRequestObject::AttributesSlot)
.isNullOrUndefined();
}
/* static */
bool ModuleRequestObject::getModuleType(
JSContext* cx, const Handle<ModuleRequestObject*> moduleRequest,
JS::ModuleType& moduleType) {
if (!moduleRequest->hasAttributes()) {
moduleType = JS::ModuleType::JavaScript;
return true;
}
Rooted<ArrayObject*> attributesArray(cx, moduleRequest->attributes());
RootedObject attributeObject(cx);
RootedId typeId(cx, NameToId(cx->names().type));
RootedValue value(cx);
uint32_t numberOfAttributes = attributesArray->length();
for (uint32_t i = 0; i < numberOfAttributes; i++) {
attributeObject = &attributesArray->getDenseElement(i).toObject();
if (!GetProperty(cx, attributeObject, attributeObject, typeId, &value)) {
continue;
}
int32_t isJsonString;
if (!js::CompareStrings(cx, cx->names().json, value.toString(),
&isJsonString)) {
return false;
}
if (isJsonString == 0) {
moduleType = JS::ModuleType::JSON;
return true;
}
moduleType = JS::ModuleType::Unknown;
return true;
}
moduleType = JS::ModuleType::JavaScript;
return true;
}
/* static */
bool ModuleRequestObject::isInstance(HandleValue value) {
return value.isObject() && value.toObject().is<ModuleRequestObject>();
}
/* static */
ModuleRequestObject* ModuleRequestObject::create(
JSContext* cx, Handle<JSAtom*> specifier,
Handle<ArrayObject*> maybeAttributes) {
ModuleRequestObject* self =
NewObjectWithGivenProto<ModuleRequestObject>(cx, nullptr);
if (!self) {
return nullptr;
}
self->initReservedSlot(SpecifierSlot, StringOrNullValue(specifier));
self->initReservedSlot(AttributesSlot, ObjectOrNullValue(maybeAttributes));
return self;
}
///////////////////////////////////////////////////////////////////////////
// IndirectBindingMap
IndirectBindingMap::Binding::Binding(ModuleEnvironmentObject* environment,
jsid targetName, PropertyInfo prop)
: environment(environment),
#ifdef DEBUG
targetName(targetName),
#endif
prop(prop) {
}
void IndirectBindingMap::trace(JSTracer* trc) {
if (!map_) {
return;
}
for (Map::Enum e(*map_); !e.empty(); e.popFront()) {
Binding& b = e.front().value();
TraceEdge(trc, &b.environment, "module bindings environment");
#ifdef DEBUG
TraceEdge(trc, &b.targetName, "module bindings target name");
#endif
mozilla::DebugOnly<jsid> prev(e.front().key());
TraceEdge(trc, &e.front().mutableKey(), "module bindings binding name");
MOZ_ASSERT(e.front().key() == prev);
}
}
bool IndirectBindingMap::put(JSContext* cx, HandleId name,
Handle<ModuleEnvironmentObject*> environment,
HandleId targetName) {
if (!map_) {
map_.emplace(cx->zone());
}
mozilla::Maybe<PropertyInfo> prop = environment->lookup(cx, targetName);
MOZ_ASSERT(prop.isSome());
if (!map_->put(name, Binding(environment, targetName, *prop))) {
ReportOutOfMemory(cx);
return false;
}
return true;
}
bool IndirectBindingMap::lookup(jsid name, ModuleEnvironmentObject** envOut,
mozilla::Maybe<PropertyInfo>* propOut) const {
if (!map_) {
return false;
}
auto ptr = map_->lookup(name);
if (!ptr) {
return false;
}
const Binding& binding = ptr->value();
MOZ_ASSERT(binding.environment);
MOZ_ASSERT(
binding.environment->containsPure(binding.targetName, binding.prop));
*envOut = binding.environment;
*propOut = Some(binding.prop);
return true;
}
///////////////////////////////////////////////////////////////////////////
// ModuleNamespaceObject
/* static */
const ModuleNamespaceObject::ProxyHandler ModuleNamespaceObject::proxyHandler;
/* static */
bool ModuleNamespaceObject::isInstance(HandleValue value) {
return value.isObject() && value.toObject().is<ModuleNamespaceObject>();
}
/* static */
ModuleNamespaceObject* ModuleNamespaceObject::create(
JSContext* cx, Handle<ModuleObject*> module,
MutableHandle<UniquePtr<ExportNameVector>> exports,
MutableHandle<UniquePtr<IndirectBindingMap>> bindings) {
RootedValue priv(cx, ObjectValue(*module));
ProxyOptions options;
options.setLazyProto(true);
RootedObject object(
cx, NewProxyObject(cx, &proxyHandler, priv, nullptr, options));
if (!object) {
return nullptr;
}
SetProxyReservedSlot(object, ExportsSlot,
PrivateValue(exports.get().release()));
AddCellMemory(object, sizeof(ExportNameVector), MemoryUse::ModuleExports);
SetProxyReservedSlot(object, BindingsSlot,
PrivateValue(bindings.get().release()));
AddCellMemory(object, sizeof(IndirectBindingMap),
MemoryUse::ModuleBindingMap);
return &object->as<ModuleNamespaceObject>();
}
ModuleObject& ModuleNamespaceObject::module() {
return GetProxyPrivate(this).toObject().as<ModuleObject>();
}
const ExportNameVector& ModuleNamespaceObject::exports() const {
Value value = GetProxyReservedSlot(this, ExportsSlot);
auto* exports = static_cast<ExportNameVector*>(value.toPrivate());
MOZ_ASSERT(exports);
return *exports;
}
ExportNameVector& ModuleNamespaceObject::mutableExports() {
// Get a non-const reference for tracing/destruction. Do not actually mutate
// this vector! This would be incorrect without adding barriers.
return const_cast<ExportNameVector&>(exports());
}
IndirectBindingMap& ModuleNamespaceObject::bindings() {
Value value = GetProxyReservedSlot(this, BindingsSlot);
auto* bindings = static_cast<IndirectBindingMap*>(value.toPrivate());
MOZ_ASSERT(bindings);
return *bindings;
}
bool ModuleNamespaceObject::hasExports() const {
// Exports may not be present if we hit OOM in initialization.
return !GetProxyReservedSlot(this, ExportsSlot).isUndefined();
}
bool ModuleNamespaceObject::hasBindings() const {
// Import bindings may not be present if we hit OOM in initialization.
return !GetProxyReservedSlot(this, BindingsSlot).isUndefined();
}
bool ModuleNamespaceObject::addBinding(JSContext* cx,
Handle<JSAtom*> exportedName,
Handle<ModuleObject*> targetModule,
Handle<JSAtom*> targetName) {
Rooted<ModuleEnvironmentObject*> environment(
cx, &targetModule->initialEnvironment());
RootedId exportedNameId(cx, AtomToId(exportedName));
RootedId targetNameId(cx, AtomToId(targetName));
return bindings().put(cx, exportedNameId, environment, targetNameId);
}
const char ModuleNamespaceObject::ProxyHandler::family = 0;
ModuleNamespaceObject::ProxyHandler::ProxyHandler()
: BaseProxyHandler(&family, false) {}
bool ModuleNamespaceObject::ProxyHandler::getPrototype(
JSContext* cx, HandleObject proxy, MutableHandleObject protop) const {
protop.set(nullptr);
return true;
}
bool ModuleNamespaceObject::ProxyHandler::setPrototype(
JSContext* cx, HandleObject proxy, HandleObject proto,
ObjectOpResult& result) const {
if (!proto) {
return result.succeed();
}
return result.failCantSetProto();
}
bool ModuleNamespaceObject::ProxyHandler::getPrototypeIfOrdinary(
JSContext* cx, HandleObject proxy, bool* isOrdinary,
MutableHandleObject protop) const {
*isOrdinary = false;
return true;
}
bool ModuleNamespaceObject::ProxyHandler::setImmutablePrototype(
JSContext* cx, HandleObject proxy, bool* succeeded) const {
*succeeded = true;
return true;
}
bool ModuleNamespaceObject::ProxyHandler::isExtensible(JSContext* cx,
HandleObject proxy,
bool* extensible) const {
*extensible = false;
return true;
}
bool ModuleNamespaceObject::ProxyHandler::preventExtensions(
JSContext* cx, HandleObject proxy, ObjectOpResult& result) const {
result.succeed();
return true;
}
bool ModuleNamespaceObject::ProxyHandler::getOwnPropertyDescriptor(
JSContext* cx, HandleObject proxy, HandleId id,
MutableHandle<mozilla::Maybe<PropertyDescriptor>> desc) const {
Rooted<ModuleNamespaceObject*> ns(cx, &proxy->as<ModuleNamespaceObject>());
if (id.isSymbol()) {
if (id.isWellKnownSymbol(JS::SymbolCode::toStringTag)) {
desc.set(Some(PropertyDescriptor::Data(StringValue(cx->names().Module))));
return true;
}
desc.reset();
return true;
}
const IndirectBindingMap& bindings = ns->bindings();
ModuleEnvironmentObject* env;
mozilla::Maybe<PropertyInfo> prop;
if (!bindings.lookup(id, &env, &prop)) {
// Not found.
desc.reset();
return true;
}
RootedValue value(cx, env->getSlot(prop->slot()));
if (value.isMagic(JS_UNINITIALIZED_LEXICAL)) {
ReportRuntimeLexicalError(cx, JSMSG_UNINITIALIZED_LEXICAL, id);
return false;
}
desc.set(
Some(PropertyDescriptor::Data(value, {JS::PropertyAttribute::Enumerable,
JS::PropertyAttribute::Writable})));
return true;
}
static bool ValidatePropertyDescriptor(
JSContext* cx, Handle<PropertyDescriptor> desc, bool expectedWritable,
bool expectedEnumerable, bool expectedConfigurable,
HandleValue expectedValue, ObjectOpResult& result) {
if (desc.isAccessorDescriptor()) {
return result.fail(JSMSG_CANT_REDEFINE_PROP);
}
if (desc.hasWritable() && desc.writable() != expectedWritable) {
return result.fail(JSMSG_CANT_REDEFINE_PROP);
}
if (desc.hasEnumerable() && desc.enumerable() != expectedEnumerable) {
return result.fail(JSMSG_CANT_REDEFINE_PROP);
}
if (desc.hasConfigurable() && desc.configurable() != expectedConfigurable) {
return result.fail(JSMSG_CANT_REDEFINE_PROP);
}
if (desc.hasValue()) {
bool same;
if (!SameValue(cx, desc.value(), expectedValue, &same)) {
return false;
}
if (!same) {
return result.fail(JSMSG_CANT_REDEFINE_PROP);
}
}
return result.succeed();
}
bool ModuleNamespaceObject::ProxyHandler::defineProperty(
JSContext* cx, HandleObject proxy, HandleId id,
Handle<PropertyDescriptor> desc, ObjectOpResult& result) const {
if (id.isSymbol()) {
if (id.isWellKnownSymbol(JS::SymbolCode::toStringTag)) {
RootedValue value(cx, StringValue(cx->names().Module));
return ValidatePropertyDescriptor(cx, desc, false, false, false, value,
result);
}
return result.fail(JSMSG_CANT_DEFINE_PROP_OBJECT_NOT_EXTENSIBLE);
}
const IndirectBindingMap& bindings =
proxy->as<ModuleNamespaceObject>().bindings();
ModuleEnvironmentObject* env;
mozilla::Maybe<PropertyInfo> prop;
if (!bindings.lookup(id, &env, &prop)) {
return result.fail(JSMSG_CANT_DEFINE_PROP_OBJECT_NOT_EXTENSIBLE);
}
RootedValue value(cx, env->getSlot(prop->slot()));
if (value.isMagic(JS_UNINITIALIZED_LEXICAL)) {
ReportRuntimeLexicalError(cx, JSMSG_UNINITIALIZED_LEXICAL, id);
return false;
}
return ValidatePropertyDescriptor(cx, desc, true, true, false, value, result);
}
bool ModuleNamespaceObject::ProxyHandler::has(JSContext* cx, HandleObject proxy,
HandleId id, bool* bp) const {
Rooted<ModuleNamespaceObject*> ns(cx, &proxy->as<ModuleNamespaceObject>());
if (id.isSymbol()) {
*bp = id.isWellKnownSymbol(JS::SymbolCode::toStringTag);
return true;
}
*bp = ns->bindings().has(id);
return true;
}
bool ModuleNamespaceObject::ProxyHandler::get(JSContext* cx, HandleObject proxy,
HandleValue receiver, HandleId id,
MutableHandleValue vp) const {
Rooted<ModuleNamespaceObject*> ns(cx, &proxy->as<ModuleNamespaceObject>());
if (id.isSymbol()) {
if (id.isWellKnownSymbol(JS::SymbolCode::toStringTag)) {
vp.setString(cx->names().Module);
return true;
}
vp.setUndefined();
return true;
}
ModuleEnvironmentObject* env;
mozilla::Maybe<PropertyInfo> prop;
if (!ns->bindings().lookup(id, &env, &prop)) {
vp.setUndefined();
return true;
}
RootedValue value(cx, env->getSlot(prop->slot()));
if (value.isMagic(JS_UNINITIALIZED_LEXICAL)) {
ReportRuntimeLexicalError(cx, JSMSG_UNINITIALIZED_LEXICAL, id);
return false;
}
vp.set(value);
return true;
}
bool ModuleNamespaceObject::ProxyHandler::set(JSContext* cx, HandleObject proxy,
HandleId id, HandleValue v,
HandleValue receiver,
ObjectOpResult& result) const {
return result.failReadOnly();
}
bool ModuleNamespaceObject::ProxyHandler::delete_(
JSContext* cx, HandleObject proxy, HandleId id,
ObjectOpResult& result) const {
Rooted<ModuleNamespaceObject*> ns(cx, &proxy->as<ModuleNamespaceObject>());
if (id.isSymbol()) {
if (id.isWellKnownSymbol(JS::SymbolCode::toStringTag)) {
return result.failCantDelete();
}
return result.succeed();
}
if (ns->bindings().has(id)) {
return result.failCantDelete();
}
return result.succeed();
}
bool ModuleNamespaceObject::ProxyHandler::ownPropertyKeys(
JSContext* cx, HandleObject proxy, MutableHandleIdVector props) const {
Rooted<ModuleNamespaceObject*> ns(cx, &proxy->as<ModuleNamespaceObject>());
uint32_t count = ns->exports().length();
if (!props.reserve(props.length() + count + 1)) {
return false;
}
for (JSAtom* atom : ns->exports()) {
props.infallibleAppend(AtomToId(atom));
}
props.infallibleAppend(
PropertyKey::Symbol(cx->wellKnownSymbols().toStringTag));
return true;
}
void ModuleNamespaceObject::ProxyHandler::trace(JSTracer* trc,
JSObject* proxy) const {
auto& self = proxy->as<ModuleNamespaceObject>();
if (self.hasExports()) {
self.mutableExports().trace(trc);
}
if (self.hasBindings()) {
self.bindings().trace(trc);
}
}
void ModuleNamespaceObject::ProxyHandler::finalize(JS::GCContext* gcx,
JSObject* proxy) const {
auto& self = proxy->as<ModuleNamespaceObject>();
if (self.hasExports()) {
gcx->delete_(proxy, &self.mutableExports(), MemoryUse::ModuleExports);
}
if (self.hasBindings()) {
gcx->delete_(proxy, &self.bindings(), MemoryUse::ModuleBindingMap);
}
}
///////////////////////////////////////////////////////////////////////////
// SyntheticModuleFields
// The fields of a synthetic module record, as described in:
class js::SyntheticModuleFields {
public:
ExportNameVector exportNames;
public:
void trace(JSTracer* trc);
};
void SyntheticModuleFields::trace(JSTracer* trc) { exportNames.trace(trc); }
///////////////////////////////////////////////////////////////////////////
// CyclicModuleFields
// The fields of a cyclic module record, as described in:
class js::CyclicModuleFields {
public:
ModuleStatus status = ModuleStatus::Unlinked;
bool hasTopLevelAwait : 1;
private:
// Flag bits that determine whether other fields are present.
bool hasDfsIndex : 1;
bool hasDfsAncestorIndex : 1;
bool isAsyncEvaluating : 1;
bool hasPendingAsyncDependencies : 1;
// Fields whose presence is conditional on the flag bits above.
uint32_t dfsIndex = 0;
uint32_t dfsAncestorIndex = 0;
uint32_t asyncEvaluatingPostOrder = 0;
uint32_t pendingAsyncDependencies = 0;
// Fields describing the layout of exportEntries.
uint32_t indirectExportEntriesStart = 0;
uint32_t starExportEntriesStart = 0;
public:
HeapPtr<Value> evaluationError;
HeapPtr<JSObject*> metaObject;
HeapPtr<ScriptSourceObject*> scriptSourceObject;
RequestedModuleVector requestedModules;
ImportEntryVector importEntries;
ExportEntryVector exportEntries;
IndirectBindingMap importBindings;
UniquePtr<FunctionDeclarationVector> functionDeclarations;
HeapPtr<PromiseObject*> topLevelCapability;
HeapPtr<ListObject*> asyncParentModules;
HeapPtr<ModuleObject*> cycleRoot;
public:
CyclicModuleFields();
void trace(JSTracer* trc);
void initExportEntries(MutableHandle<ExportEntryVector> allEntries,
uint32_t localExportCount,
uint32_t indirectExportCount,
uint32_t starExportCount);
Span<const ExportEntry> localExportEntries() const;
Span<const ExportEntry> indirectExportEntries() const;
Span<const ExportEntry> starExportEntries() const;
void setDfsIndex(uint32_t index);
Maybe<uint32_t> maybeDfsIndex() const;
void setDfsAncestorIndex(uint32_t index);
Maybe<uint32_t> maybeDfsAncestorIndex() const;
void clearDfsIndexes();
void setAsyncEvaluating(uint32_t postOrder);
bool getIsAsyncEvaluating() const;
Maybe<uint32_t> maybeAsyncEvaluatingPostOrder() const;
void clearAsyncEvaluatingPostOrder();
void setPendingAsyncDependencies(uint32_t newValue);
Maybe<uint32_t> maybePendingAsyncDependencies() const;
};
CyclicModuleFields::CyclicModuleFields()
: hasTopLevelAwait(false),
hasDfsIndex(false),
hasDfsAncestorIndex(false),
isAsyncEvaluating(false),
hasPendingAsyncDependencies(false) {}
void CyclicModuleFields::trace(JSTracer* trc) {
TraceEdge(trc, &evaluationError, "CyclicModuleFields::evaluationError");
TraceNullableEdge(trc, &metaObject, "CyclicModuleFields::metaObject");
TraceNullableEdge(trc, &scriptSourceObject,
"CyclicModuleFields::scriptSourceObject");
requestedModules.trace(trc);
importEntries.trace(trc);
exportEntries.trace(trc);
importBindings.trace(trc);
TraceNullableEdge(trc, &topLevelCapability,
"CyclicModuleFields::topLevelCapability");
TraceNullableEdge(trc, &asyncParentModules,
"CyclicModuleFields::asyncParentModules");
TraceNullableEdge(trc, &cycleRoot, "CyclicModuleFields::cycleRoot");
}
void CyclicModuleFields::initExportEntries(
MutableHandle<ExportEntryVector> allEntries, uint32_t localExportCount,
uint32_t indirectExportCount, uint32_t starExportCount) {
MOZ_ASSERT(allEntries.length() ==
localExportCount + indirectExportCount + starExportCount);
exportEntries = std::move(allEntries.get());
indirectExportEntriesStart = localExportCount;
starExportEntriesStart = indirectExportEntriesStart + indirectExportCount;
}
Span<const ExportEntry> CyclicModuleFields::localExportEntries() const {
MOZ_ASSERT(indirectExportEntriesStart <= exportEntries.length());
return Span(exportEntries.begin(),
exportEntries.begin() + indirectExportEntriesStart);
}
Span<const ExportEntry> CyclicModuleFields::indirectExportEntries() const {
MOZ_ASSERT(indirectExportEntriesStart <= starExportEntriesStart);
MOZ_ASSERT(starExportEntriesStart <= exportEntries.length());
return Span(exportEntries.begin() + indirectExportEntriesStart,
exportEntries.begin() + starExportEntriesStart);
}
Span<const ExportEntry> CyclicModuleFields::starExportEntries() const {
MOZ_ASSERT(starExportEntriesStart <= exportEntries.length());
return Span(exportEntries.begin() + starExportEntriesStart,
exportEntries.end());
}
void CyclicModuleFields::setDfsIndex(uint32_t index) {
dfsIndex = index;
hasDfsIndex = true;
}
Maybe<uint32_t> CyclicModuleFields::maybeDfsIndex() const {
return hasDfsIndex ? Some(dfsIndex) : Nothing();
}
void CyclicModuleFields::setDfsAncestorIndex(uint32_t index) {
dfsAncestorIndex = index;
hasDfsAncestorIndex = true;
}
Maybe<uint32_t> CyclicModuleFields::maybeDfsAncestorIndex() const {
return hasDfsAncestorIndex ? Some(dfsAncestorIndex) : Nothing();
}
void CyclicModuleFields::clearDfsIndexes() {
dfsIndex = 0;
hasDfsIndex = false;
dfsAncestorIndex = 0;
hasDfsAncestorIndex = false;
}
void CyclicModuleFields::setAsyncEvaluating(uint32_t postOrder) {
isAsyncEvaluating = true;
asyncEvaluatingPostOrder = postOrder;
}
bool CyclicModuleFields::getIsAsyncEvaluating() const {
return isAsyncEvaluating;
}
Maybe<uint32_t> CyclicModuleFields::maybeAsyncEvaluatingPostOrder() const {
if (!isAsyncEvaluating ||
asyncEvaluatingPostOrder == ASYNC_EVALUATING_POST_ORDER_CLEARED) {
return Nothing();
}
return Some(asyncEvaluatingPostOrder);
}
void CyclicModuleFields::clearAsyncEvaluatingPostOrder() {
asyncEvaluatingPostOrder = ASYNC_EVALUATING_POST_ORDER_CLEARED;
}
void CyclicModuleFields::setPendingAsyncDependencies(uint32_t newValue) {
pendingAsyncDependencies = newValue;
hasPendingAsyncDependencies = true;
}
Maybe<uint32_t> CyclicModuleFields::maybePendingAsyncDependencies() const {
return hasPendingAsyncDependencies ? Some(pendingAsyncDependencies)
: Nothing();
}
///////////////////////////////////////////////////////////////////////////
// ModuleObject
/* static */ const JSClassOps ModuleObject::classOps_ = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
ModuleObject::finalize, // finalize
nullptr, // call
nullptr, // construct
ModuleObject::trace, // trace
};
/* static */ const JSClass ModuleObject::class_ = {
"Module",
JSCLASS_HAS_RESERVED_SLOTS(ModuleObject::SlotCount) |
JSCLASS_BACKGROUND_FINALIZE,
&ModuleObject::classOps_};
/* static */
bool ModuleObject::isInstance(HandleValue value) {
return value.isObject() && value.toObject().is<ModuleObject>();
}
bool ModuleObject::hasCyclicModuleFields() const {
// This currently only returns false if we GC during initialization.
return !getReservedSlot(CyclicModuleFieldsSlot).isUndefined();
}
CyclicModuleFields* ModuleObject::cyclicModuleFields() {
void* ptr = getReservedSlot(CyclicModuleFieldsSlot).toPrivate();
MOZ_ASSERT(ptr);
return static_cast<CyclicModuleFields*>(ptr);
}
const CyclicModuleFields* ModuleObject::cyclicModuleFields() const {
return const_cast<ModuleObject*>(this)->cyclicModuleFields();
}
Span<const RequestedModule> ModuleObject::requestedModules() const {
return cyclicModuleFields()->requestedModules;
}
Span<const ImportEntry> ModuleObject::importEntries() const {
return cyclicModuleFields()->importEntries;
}
Span<const ExportEntry> ModuleObject::localExportEntries() const {
return cyclicModuleFields()->localExportEntries();
}
Span<const ExportEntry> ModuleObject::indirectExportEntries() const {
return cyclicModuleFields()->indirectExportEntries();
}
Span<const ExportEntry> ModuleObject::starExportEntries() const {
return cyclicModuleFields()->starExportEntries();
}
const ExportNameVector& ModuleObject::syntheticExportNames() const {
return syntheticModuleFields()->exportNames;
}
void ModuleObject::initFunctionDeclarations(
UniquePtr<FunctionDeclarationVector> decls) {
cyclicModuleFields()->functionDeclarations = std::move(decls);
}
/* static */
ModuleObject* ModuleObject::create(JSContext* cx) {
Rooted<UniquePtr<CyclicModuleFields>> fields(cx);
fields = cx->make_unique<CyclicModuleFields>();
if (!fields) {
return nullptr;
}
Rooted<ModuleObject*> self(
cx, NewObjectWithGivenProto<ModuleObject>(cx, nullptr));
if (!self) {
return nullptr;
}
InitReservedSlot(self, CyclicModuleFieldsSlot, fields.release(),
MemoryUse::ModuleCyclicFields);
return self;
}
/* static */
ModuleObject* ModuleObject::createSynthetic(
JSContext* cx, MutableHandle<ExportNameVector> exportNames) {
Rooted<UniquePtr<SyntheticModuleFields>> syntheticFields(cx);
syntheticFields = cx->make_unique<SyntheticModuleFields>();
if (!syntheticFields) {
return nullptr;
}
Rooted<ModuleObject*> self(
cx, NewObjectWithGivenProto<ModuleObject>(cx, nullptr));
if (!self) {
return nullptr;
}
InitReservedSlot(self, SyntheticModuleFieldsSlot, syntheticFields.release(),
MemoryUse::ModuleSyntheticFields);
self->syntheticModuleFields()->exportNames = std::move(exportNames.get());
return self;
}
/* static */
void ModuleObject::finalize(JS::GCContext* gcx, JSObject* obj) {
ModuleObject* self = &obj->as<ModuleObject>();
if (self->hasCyclicModuleFields()) {
gcx->delete_(obj, self->cyclicModuleFields(),
MemoryUse::ModuleCyclicFields);
}
if (self->hasSyntheticModuleFields()) {
gcx->delete_(obj, self->syntheticModuleFields(),
MemoryUse::ModuleSyntheticFields);
}
}
ModuleEnvironmentObject& ModuleObject::initialEnvironment() const {
Value value = getReservedSlot(EnvironmentSlot);
return value.toObject().as<ModuleEnvironmentObject>();
}
ModuleEnvironmentObject* ModuleObject::environment() const {
// Note that this it's valid to call this even if there was an error
// evaluating the module.
// According to the spec the environment record is created during linking, but
// we create it earlier than that.
if (status() < ModuleStatus::Linked) {
return nullptr;
}
return &initialEnvironment();
}
IndirectBindingMap& ModuleObject::importBindings() {
return cyclicModuleFields()->importBindings;
}
ModuleNamespaceObject* ModuleObject::namespace_() {
Value value = getReservedSlot(NamespaceSlot);
if (value.isUndefined()) {
return nullptr;
}
return &value.toObject().as<ModuleNamespaceObject>();
}
ScriptSourceObject* ModuleObject::scriptSourceObject() const {
return cyclicModuleFields()->scriptSourceObject;
}
void ModuleObject::initAsyncSlots(JSContext* cx, bool hasTopLevelAwait,
Handle<ListObject*> asyncParentModules) {
cyclicModuleFields()->hasTopLevelAwait = hasTopLevelAwait;
cyclicModuleFields()->asyncParentModules = asyncParentModules;
}
static uint32_t NextPostOrder(JSRuntime* rt) {
uint32_t ordinal = rt->moduleAsyncEvaluatingPostOrder;
MOZ_ASSERT(ordinal != ASYNC_EVALUATING_POST_ORDER_CLEARED);
MOZ_ASSERT(ordinal < MAX_UINT32);
rt->moduleAsyncEvaluatingPostOrder++;
return ordinal;
}
// Reset the runtime's moduleAsyncEvaluatingPostOrder counter when the last
// module that was async evaluating is finished.
//
// The graph is not re-entrant and any future modules will be independent from
// this one.
static void MaybeResetPostOrderCounter(JSRuntime* rt,
uint32_t finishedPostOrder) {
if (rt->moduleAsyncEvaluatingPostOrder == finishedPostOrder + 1) {
rt->moduleAsyncEvaluatingPostOrder = ASYNC_EVALUATING_POST_ORDER_INIT;
}
}
void ModuleObject::setAsyncEvaluating() {
MOZ_ASSERT(!isAsyncEvaluating());
uint32_t postOrder = NextPostOrder(runtimeFromMainThread());
cyclicModuleFields()->setAsyncEvaluating(postOrder);
}
void ModuleObject::initScriptSlots(HandleScript script) {
MOZ_ASSERT(script);
MOZ_ASSERT(script->sourceObject());
MOZ_ASSERT(script->filename());
initReservedSlot(ScriptSlot, PrivateGCThingValue(script));
cyclicModuleFields()->scriptSourceObject = script->sourceObject();
}
void ModuleObject::setInitialEnvironment(
Handle<ModuleEnvironmentObject*> initialEnvironment) {
initReservedSlot(EnvironmentSlot, ObjectValue(*initialEnvironment));
}
void ModuleObject::initImportExportData(
MutableHandle<RequestedModuleVector> requestedModules,
MutableHandle<ImportEntryVector> importEntries,
MutableHandle<ExportEntryVector> exportEntries, uint32_t localExportCount,
uint32_t indirectExportCount, uint32_t starExportCount) {
cyclicModuleFields()->requestedModules = std::move(requestedModules.get());
cyclicModuleFields()->importEntries = std::move(importEntries.get());
cyclicModuleFields()->initExportEntries(exportEntries, localExportCount,
indirectExportCount, starExportCount);
}
/* static */
bool ModuleObject::Freeze(JSContext* cx, Handle<ModuleObject*> self) {
return FreezeObject(cx, self);
}
#ifdef DEBUG
/* static */ inline bool ModuleObject::AssertFrozen(
JSContext* cx, Handle<ModuleObject*> self) {
bool frozen = false;
if (!TestIntegrityLevel(cx, self, IntegrityLevel::Frozen, &frozen)) {
return false;
}
MOZ_ASSERT(frozen);
return true;
}
#endif
JSScript* ModuleObject::maybeScript() const {
Value value = getReservedSlot(ScriptSlot);
if (value.isUndefined()) {
return nullptr;
}
BaseScript* script = value.toGCThing()->as<BaseScript>();
MOZ_ASSERT(script->hasBytecode(),
"Module scripts should always have bytecode");
return script->asJSScript();
}
JSScript* ModuleObject::script() const {
JSScript* ptr = maybeScript();
MOZ_RELEASE_ASSERT(ptr);
return ptr;
}
const char* ModuleObject::filename() const {
// The ScriptSlot will be cleared once the module is evaluated, so we try to
// get the filename from cyclicModuleFields().
if (!hasCyclicModuleFields()) {
return "(JSON module)";
}
return cyclicModuleFields()->scriptSourceObject->source()->filename();
}
static inline void AssertValidModuleStatus(ModuleStatus status) {
MOZ_ASSERT(status >= ModuleStatus::Unlinked &&
status <= ModuleStatus::Evaluated_Error);
}
ModuleStatus ModuleObject::status() const {
// Always return `ModuleStatus::Evaluated` so we can assert a module's status
// without checking which kind it is, even though synthetic modules don't have
// this field according to the spec.
if (hasSyntheticModuleFields()) {
return ModuleStatus::Evaluated;
}
ModuleStatus status = cyclicModuleFields()->status;
AssertValidModuleStatus(status);
if (status == ModuleStatus::Evaluated_Error) {
return ModuleStatus::Evaluated;
}
return status;
}
void ModuleObject::setStatus(ModuleStatus newStatus) {
AssertValidModuleStatus(newStatus);
// Note that under OOM conditions we can fail the module linking process even
// after modules have been marked as linked.
MOZ_ASSERT((status() <= ModuleStatus::Linked &&
newStatus == ModuleStatus::Unlinked) ||
newStatus > status(),
"New module status inconsistent with current status");
cyclicModuleFields()->status = newStatus;
}
bool ModuleObject::hasTopLevelAwait() const {
return cyclicModuleFields()->hasTopLevelAwait;
}
bool ModuleObject::isAsyncEvaluating() const {
return cyclicModuleFields()->getIsAsyncEvaluating();
}
Maybe<uint32_t> ModuleObject::maybeDfsIndex() const {
return cyclicModuleFields()->maybeDfsIndex();
}
uint32_t ModuleObject::dfsIndex() const { return maybeDfsIndex().value(); }
void ModuleObject::setDfsIndex(uint32_t index) {
cyclicModuleFields()->setDfsIndex(index);
}
Maybe<uint32_t> ModuleObject::maybeDfsAncestorIndex() const {
return cyclicModuleFields()->maybeDfsAncestorIndex();
}
uint32_t ModuleObject::dfsAncestorIndex() const {
return maybeDfsAncestorIndex().value();
}
void ModuleObject::setDfsAncestorIndex(uint32_t index) {
cyclicModuleFields()->setDfsAncestorIndex(index);
}
void ModuleObject::clearDfsIndexes() {
cyclicModuleFields()->clearDfsIndexes();
}
PromiseObject* ModuleObject::maybeTopLevelCapability() const {
return cyclicModuleFields()->topLevelCapability;
}
PromiseObject* ModuleObject::topLevelCapability() const {
PromiseObject* capability = maybeTopLevelCapability();
MOZ_RELEASE_ASSERT(capability);
return capability;
}
// static
PromiseObject* ModuleObject::createTopLevelCapability(
JSContext* cx, Handle<ModuleObject*> module) {
MOZ_ASSERT(!module->maybeTopLevelCapability());
Rooted<PromiseObject*> resultPromise(cx, CreatePromiseObjectForAsync(cx));
if (!resultPromise) {
return nullptr;
}
module->setInitialTopLevelCapability(resultPromise);
return resultPromise;
}
void ModuleObject::setInitialTopLevelCapability(
Handle<PromiseObject*> capability) {
cyclicModuleFields()->topLevelCapability = capability;
}
ListObject* ModuleObject::asyncParentModules() const {
return cyclicModuleFields()->asyncParentModules;
}
bool ModuleObject::appendAsyncParentModule(JSContext* cx,
Handle<ModuleObject*> self,
Handle<ModuleObject*> parent) {
Rooted<Value> parentValue(cx, ObjectValue(*parent));
return self->asyncParentModules()->append(cx, parentValue);
}
Maybe<uint32_t> ModuleObject::maybePendingAsyncDependencies() const {
return cyclicModuleFields()->maybePendingAsyncDependencies();
}
uint32_t ModuleObject::pendingAsyncDependencies() const {
return maybePendingAsyncDependencies().value();
}
Maybe<uint32_t> ModuleObject::maybeAsyncEvaluatingPostOrder() const {
return cyclicModuleFields()->maybeAsyncEvaluatingPostOrder();
}
uint32_t ModuleObject::getAsyncEvaluatingPostOrder() const {
return cyclicModuleFields()->maybeAsyncEvaluatingPostOrder().value();
}
void ModuleObject::clearAsyncEvaluatingPostOrder() {
MOZ_ASSERT(status() == ModuleStatus::Evaluated);
JSRuntime* rt = runtimeFromMainThread();
MaybeResetPostOrderCounter(rt, getAsyncEvaluatingPostOrder());
cyclicModuleFields()->clearAsyncEvaluatingPostOrder();
}
void ModuleObject::setPendingAsyncDependencies(uint32_t newValue) {
cyclicModuleFields()->setPendingAsyncDependencies(newValue);
}
void ModuleObject::setCycleRoot(ModuleObject* cycleRoot) {
cyclicModuleFields()->cycleRoot = cycleRoot;
}
ModuleObject* ModuleObject::getCycleRoot() const {
MOZ_RELEASE_ASSERT(cyclicModuleFields()->cycleRoot);
return cyclicModuleFields()->cycleRoot;
}
bool ModuleObject::hasSyntheticModuleFields() const {
bool result = !getReservedSlot(SyntheticModuleFieldsSlot).isUndefined();
MOZ_ASSERT_IF(result, !hasCyclicModuleFields());
return result;
}
SyntheticModuleFields* ModuleObject::syntheticModuleFields() {
MOZ_ASSERT(!hasCyclicModuleFields());
void* ptr = getReservedSlot(SyntheticModuleFieldsSlot).toPrivate();
MOZ_ASSERT(ptr);
return static_cast<SyntheticModuleFields*>(ptr);
}
const SyntheticModuleFields* ModuleObject::syntheticModuleFields() const {
return const_cast<ModuleObject*>(this)->syntheticModuleFields();
}
bool ModuleObject::hasTopLevelCapability() const {
return cyclicModuleFields()->topLevelCapability;
}
bool ModuleObject::hadEvaluationError() const {
ModuleStatus fullStatus = cyclicModuleFields()->status;
return fullStatus == ModuleStatus::Evaluated_Error;
}
void ModuleObject::setEvaluationError(HandleValue newValue) {
MOZ_ASSERT(status() != ModuleStatus::Unlinked);
MOZ_ASSERT(!hadEvaluationError());
cyclicModuleFields()->status = ModuleStatus::Evaluated_Error;
cyclicModuleFields()->evaluationError = newValue;
MOZ_ASSERT(status() == ModuleStatus::Evaluated);
MOZ_ASSERT(hadEvaluationError());
}
Value ModuleObject::maybeEvaluationError() const {
return cyclicModuleFields()->evaluationError;
}
Value ModuleObject::evaluationError() const {
MOZ_ASSERT(hadEvaluationError());
return maybeEvaluationError();
}
JSObject* ModuleObject::metaObject() const {
return cyclicModuleFields()->metaObject;
}
void ModuleObject::setMetaObject(JSObject* obj) {
MOZ_ASSERT(obj);
MOZ_ASSERT(!metaObject());
cyclicModuleFields()->metaObject = obj;
}
/* static */
void ModuleObject::trace(JSTracer* trc, JSObject* obj) {
ModuleObject& module = obj->as<ModuleObject>();
if (module.hasCyclicModuleFields()) {
module.cyclicModuleFields()->trace(trc);
}
if (module.hasSyntheticModuleFields()) {
module.syntheticModuleFields()->trace(trc);
}
}
/* static */
bool ModuleObject::instantiateFunctionDeclarations(JSContext* cx,
Handle<ModuleObject*> self) {
#ifdef DEBUG
MOZ_ASSERT(self->status() == ModuleStatus::Linking);
if (!AssertFrozen(cx, self)) {
return false;
}
#endif
// |self| initially manages this vector.
UniquePtr<FunctionDeclarationVector>& funDecls =
self->cyclicModuleFields()->functionDeclarations;
if (!funDecls) {
JS_ReportErrorASCII(
cx, "Module function declarations have already been instantiated");
return false;
}
Rooted<ModuleEnvironmentObject*> env(cx, &self->initialEnvironment());
RootedObject obj(cx);
RootedValue value(cx);
RootedFunction fun(cx);
Rooted<PropertyName*> name(cx);
for (GCThingIndex funIndex : *funDecls) {
fun.set(self->script()->getFunction(funIndex));
obj = Lambda(cx, fun, env);
if (!obj) {
return false;
}
name = fun->fullExplicitName()->asPropertyName();
value = ObjectValue(*obj);
if (!SetProperty(cx, env, name, value)) {
return false;
}
}
// Free the vector, now its contents are no longer needed.
funDecls.reset();
return true;
}
/* static */
bool ModuleObject::execute(JSContext* cx, Handle<ModuleObject*> self) {
#ifdef DEBUG
MOZ_ASSERT(self->status() == ModuleStatus::Evaluating ||
self->status() == ModuleStatus::EvaluatingAsync ||
self->status() == ModuleStatus::Evaluated);
MOZ_ASSERT(!self->hadEvaluationError());
if (!AssertFrozen(cx, self)) {
return false;
}
#endif
RootedScript script(cx, self->script());
auto guardA = mozilla::MakeScopeExit([&] {
if (self->hasTopLevelAwait()) {
// Handled in AsyncModuleExecutionFulfilled and
// AsyncModuleExecutionRejected.
return;
}
ModuleObject::onTopLevelEvaluationFinished(self);
});
Rooted<ModuleEnvironmentObject*> env(cx, self->environment());
if (!env) {
JS_ReportErrorASCII(cx,
"Module declarations have not yet been instantiated");
return false;
}
Rooted<Value> ignored(cx);
return Execute(cx, script, env, &ignored);
}
/* static */
void ModuleObject::onTopLevelEvaluationFinished(ModuleObject* module) {
// ScriptSlot is used by debugger to access environments during evaluating
// the top-level script.
// Clear the reference at exit to prevent us keeping this alive unnecessarily.
module->setReservedSlot(ScriptSlot, UndefinedValue());
}
/* static */
ModuleNamespaceObject* ModuleObject::createNamespace(
JSContext* cx, Handle<ModuleObject*> self,
MutableHandle<UniquePtr<ExportNameVector>> exports) {
MOZ_ASSERT(!self->namespace_());
Rooted<UniquePtr<IndirectBindingMap>> bindings(cx);
bindings = cx->make_unique<IndirectBindingMap>();
if (!bindings) {
return nullptr;
}
auto* ns = ModuleNamespaceObject::create(cx, self, exports, &bindings);
if (!ns) {
return nullptr;
}
self->initReservedSlot(NamespaceSlot, ObjectValue(*ns));
return ns;
}
/* static */
bool ModuleObject::createEnvironment(JSContext* cx,
Handle<ModuleObject*> self) {
Rooted<ModuleEnvironmentObject*> env(
cx, ModuleEnvironmentObject::create(cx, self));
if (!env) {
return false;
}
self->setInitialEnvironment(env);
return true;
}
/*static*/
bool ModuleObject::createSyntheticEnvironment(JSContext* cx,
Handle<ModuleObject*> self,
Handle<GCVector<Value>> values) {
Rooted<ModuleEnvironmentObject*> env(
cx, ModuleEnvironmentObject::createSynthetic(cx, self));
if (!env) {
return false;
}
MOZ_ASSERT(env->shape()->propMapLength() == values.length());
for (uint32_t i = 0; i < values.length(); i++) {
env->setAliasedBinding(env->firstSyntheticValueSlot() + i, values[i]);
}
self->setInitialEnvironment(env);
return true;
}
///////////////////////////////////////////////////////////////////////////
// ModuleBuilder
ModuleBuilder::ModuleBuilder(FrontendContext* fc,
const frontend::EitherParser& eitherParser)
: fc_(fc),
eitherParser_(eitherParser),
requestedModuleSpecifiers_(fc),
importEntries_(fc),
exportEntries_(fc),
exportNames_(fc) {}
bool ModuleBuilder::noteFunctionDeclaration(FrontendContext* fc,
uint32_t funIndex) {
if (!functionDecls_.emplaceBack(funIndex)) {
js::ReportOutOfMemory(fc);
return false;
}
return true;
}
void ModuleBuilder::noteAsync(frontend::StencilModuleMetadata& metadata) {
metadata.isAsync = true;
}
bool ModuleBuilder::buildTables(frontend::StencilModuleMetadata& metadata) {
// 15.2.1.17.1 ParseModule, Steps 4-11.
// Step 4.
metadata.moduleRequests = std::move(moduleRequests_);
metadata.requestedModules = std::move(requestedModules_);
// Step 5.
if (!metadata.importEntries.reserve(importEntries_.count())) {
js::ReportOutOfMemory(fc_);
return false;
}
for (auto r = importEntries_.all(); !r.empty(); r.popFront()) {
frontend::StencilModuleEntry& entry = r.front().value();
metadata.importEntries.infallibleAppend(entry);
}
// Steps 6-11.
for (const frontend::StencilModuleEntry& exp : exportEntries_) {
if (!exp.moduleRequest) {
frontend::StencilModuleEntry* importEntry = importEntryFor(exp.localName);
if (!importEntry) {
if (!metadata.localExportEntries.append(exp)) {
js::ReportOutOfMemory(fc_);
return false;
}
} else {
if (!importEntry->importName) {
if (!metadata.localExportEntries.append(exp)) {
js::ReportOutOfMemory(fc_);
return false;
}
} else {
// All names should have already been marked as used-by-stencil.
auto entry = frontend::StencilModuleEntry::exportFromEntry(
importEntry->moduleRequest, importEntry->importName,
exp.exportName, exp.lineno, exp.column);
if (!metadata.indirectExportEntries.append(entry)) {
js::ReportOutOfMemory(fc_);
return false;
}
}
}
} else if (!exp.importName && !exp.exportName) {
if (!metadata.starExportEntries.append(exp)) {
js::ReportOutOfMemory(fc_);
return false;
}
} else {
if (!metadata.indirectExportEntries.append(exp)) {
js::ReportOutOfMemory(fc_);
return false;
}
}
}
return true;
}
void ModuleBuilder::finishFunctionDecls(
frontend::StencilModuleMetadata& metadata) {
metadata.functionDecls = std::move(functionDecls_);
}
bool frontend::StencilModuleMetadata::createModuleRequestObjects(
JSContext* cx, CompilationAtomCache& atomCache,
MutableHandle<ModuleRequestVector> output) const {
if (!output.reserve(moduleRequests.length())) {
ReportOutOfMemory(cx);
return false;
}
Rooted<ModuleRequestObject*> object(cx);
for (const StencilModuleRequest& request : moduleRequests) {
object = createModuleRequestObject(cx, atomCache, request);
if (!object) {
return false;
}
output.infallibleEmplaceBack(object);
}
return true;
}
ModuleRequestObject* frontend::StencilModuleMetadata::createModuleRequestObject(
JSContext* cx, CompilationAtomCache& atomCache,
const StencilModuleRequest& request) const {
Rooted<ArrayObject*> assertionArray(cx);
uint32_t numberOfAssertions = request.assertions.length();
if (numberOfAssertions > 0) {
assertionArray = NewDenseFullyAllocatedArray(cx, numberOfAssertions);
if (!assertionArray) {
return nullptr;
}
assertionArray->ensureDenseInitializedLength(0, numberOfAssertions);
Rooted<PlainObject*> assertionObject(cx);
RootedId assertionKey(cx);
RootedValue assertionValue(cx);
for (uint32_t j = 0; j < numberOfAssertions; ++j) {
assertionObject = NewPlainObject(cx);
if (!assertionObject) {
return nullptr;
}
JSAtom* jsatom =
atomCache.getExistingAtomAt(cx, request.assertions[j].key);
MOZ_ASSERT(jsatom);
assertionKey = AtomToId(jsatom);
jsatom = atomCache.getExistingAtomAt(cx, request.assertions[j].value);
MOZ_ASSERT(jsatom);
assertionValue = StringValue(jsatom);
if (!DefineDataProperty(cx, assertionObject, assertionKey, assertionValue,
JSPROP_ENUMERATE)) {
return nullptr;
}
assertionArray->initDenseElement(j, ObjectValue(*assertionObject));
}
}
Rooted<JSAtom*> specifier(cx,
atomCache.getExistingAtomAt(cx, request.specifier));
MOZ_ASSERT(specifier);
return ModuleRequestObject::create(cx, specifier, assertionArray);
}
bool frontend::StencilModuleMetadata::createImportEntries(
JSContext* cx, CompilationAtomCache& atomCache,
Handle<ModuleRequestVector> moduleRequests,
MutableHandle<ImportEntryVector> output) const {
if (!output.reserve(importEntries.length())) {
ReportOutOfMemory(cx);
return false;
}
for (const StencilModuleEntry& entry : importEntries) {
Rooted<ModuleRequestObject*> moduleRequest(cx);
moduleRequest = moduleRequests[entry.moduleRequest.value()].get();
MOZ_ASSERT(moduleRequest);
Rooted<JSAtom*> localName(cx);
if (entry.localName) {
localName = atomCache.getExistingAtomAt(cx, entry.localName);
MOZ_ASSERT(localName);
}
Rooted<JSAtom*> importName(cx);
if (entry.importName) {
importName = atomCache.getExistingAtomAt(cx, entry.importName);
MOZ_ASSERT(importName);
}
MOZ_ASSERT(!entry.exportName);
output.infallibleEmplaceBack(moduleRequest, importName, localName,
entry.lineno, entry.column);
}
return true;
}
bool frontend::StencilModuleMetadata::createExportEntries(
JSContext* cx, frontend::CompilationAtomCache& atomCache,
Handle<ModuleRequestVector> moduleRequests,
const frontend::StencilModuleMetadata::EntryVector& input,
MutableHandle<ExportEntryVector> output) const {
if (!output.reserve(output.length() + input.length())) {
ReportOutOfMemory(cx);
return false;
}
for (const frontend::StencilModuleEntry& entry : input) {
Rooted<JSAtom*> exportName(cx);
if (entry.exportName) {
exportName = atomCache.getExistingAtomAt(cx, entry.exportName);
MOZ_ASSERT(exportName);
}
Rooted<ModuleRequestObject*> moduleRequestObject(cx);
if (entry.moduleRequest) {
moduleRequestObject = moduleRequests[entry.moduleRequest.value()].get();
MOZ_ASSERT(moduleRequestObject);
}
Rooted<JSAtom*> localName(cx);
if (entry.localName) {
localName = atomCache.getExistingAtomAt(cx, entry.localName);
MOZ_ASSERT(localName);
}
Rooted<JSAtom*> importName(cx);
if (entry.importName) {
importName = atomCache.getExistingAtomAt(cx, entry.importName);
MOZ_ASSERT(importName);
}
output.infallibleEmplaceBack(exportName, moduleRequestObject, importName,
localName, entry.lineno, entry.column);
}
return true;
}
bool frontend::StencilModuleMetadata::createRequestedModules(
JSContext* cx, CompilationAtomCache& atomCache,
Handle<ModuleRequestVector> moduleRequests,
MutableHandle<RequestedModuleVector> output) const {
if (!output.reserve(requestedModules.length())) {
ReportOutOfMemory(cx);
return false;
}
for (const frontend::StencilModuleEntry& entry : requestedModules) {
Rooted<ModuleRequestObject*> moduleRequest(cx);
moduleRequest = moduleRequests[entry.moduleRequest.value()].get();
MOZ_ASSERT(moduleRequest);
MOZ_ASSERT(!entry.localName);
MOZ_ASSERT(!entry.importName);
MOZ_ASSERT(!entry.exportName);
output.infallibleEmplaceBack(moduleRequest, entry.lineno, entry.column);
}
return true;
}
// Use StencilModuleMetadata data to fill in ModuleObject
bool frontend::StencilModuleMetadata::initModule(
JSContext* cx, FrontendContext* fc,
frontend::CompilationAtomCache& atomCache,
JS::Handle<ModuleObject*> module) const {
Rooted<ModuleRequestVector> moduleRequestsVector(cx);
if (!createModuleRequestObjects(cx, atomCache, &moduleRequestsVector)) {
return false;
}
Rooted<RequestedModuleVector> requestedModulesVector(cx);
if (!createRequestedModules(cx, atomCache, moduleRequestsVector,
&requestedModulesVector)) {
return false;
}
Rooted<ImportEntryVector> importEntriesVector(cx);
if (!createImportEntries(cx, atomCache, moduleRequestsVector,
&importEntriesVector)) {
return false;
}
Rooted<ExportEntryVector> exportEntriesVector(cx);
if (!createExportEntries(cx, atomCache, moduleRequestsVector,
localExportEntries, &exportEntriesVector)) {
return false;
}
Rooted<ExportEntryVector> indirectExportEntriesVector(cx);
if (!createExportEntries(cx, atomCache, moduleRequestsVector,
indirectExportEntries, &exportEntriesVector)) {
return false;
}
Rooted<ExportEntryVector> starExportEntriesVector(cx);
if (!createExportEntries(cx, atomCache, moduleRequestsVector,
starExportEntries, &exportEntriesVector)) {
return false;
}
// Copy the vector of declarations to the ModuleObject.
auto functionDeclsCopy = MakeUnique<FunctionDeclarationVector>();
if (!functionDeclsCopy || !functionDeclsCopy->appendAll(functionDecls)) {
js::ReportOutOfMemory(fc);
return false;
}
module->initFunctionDeclarations(std::move(functionDeclsCopy));
Rooted<ListObject*> asyncParentModulesList(cx, ListObject::create(cx));
if (!asyncParentModulesList) {
return false;
}
module->initAsyncSlots(cx, isAsync, asyncParentModulesList);
module->initImportExportData(
&requestedModulesVector, &importEntriesVector, &exportEntriesVector,
localExportEntries.length(), indirectExportEntries.length(),
starExportEntries.length());
return true;
}
bool ModuleBuilder::isAssertionSupported(frontend::TaggedParserAtomIndex key) {
if (!key.isWellKnownAtomId()) {
return false;
}
return key.toWellKnownAtomId() == WellKnownAtomId::type;
}
bool ModuleBuilder::processAssertions(frontend::StencilModuleRequest& request,
frontend::ListNode* assertionList) {
using namespace js::frontend;
for (ParseNode* assertionItem : assertionList->contents()) {
BinaryNode* assertion = &assertionItem->as<BinaryNode>();
MOZ_ASSERT(assertion->isKind(ParseNodeKind::ImportAttribute));
auto key = assertion->left()->as<NameNode>().atom();
auto value = assertion->right()->as<NameNode>().atom();
if (isAssertionSupported(key)) {
markUsedByStencil(key);
markUsedByStencil(value);
StencilModuleAssertion assertionStencil(key, value);
if (!request.assertions.append(assertionStencil)) {
js::ReportOutOfMemory(fc_);
return false;
}
}
}
return true;
}
bool ModuleBuilder::processImport(frontend::BinaryNode* importNode) {
using namespace js::frontend;
MOZ_ASSERT(importNode->isKind(ParseNodeKind::ImportDecl));
auto* specList = &importNode->left()->as<ListNode>();
MOZ_ASSERT(specList->isKind(ParseNodeKind::ImportSpecList));
auto* moduleRequest = &importNode->right()->as<BinaryNode>();
MOZ_ASSERT(moduleRequest->isKind(ParseNodeKind::ImportModuleRequest));
auto* moduleSpec = &moduleRequest->left()->as<NameNode>();
MOZ_ASSERT(moduleSpec->isKind(ParseNodeKind::StringExpr));
auto* assertionList = &moduleRequest->right()->as<ListNode>();
MOZ_ASSERT(assertionList->isKind(ParseNodeKind::ImportAttributeList));
auto specifier = moduleSpec->atom();
MaybeModuleRequestIndex moduleRequestIndex =
appendModuleRequest(specifier, assertionList);
if (!moduleRequestIndex.isSome()) {
return false;
}
if (!maybeAppendRequestedModule(moduleRequestIndex, moduleSpec)) {
return false;
}
for (ParseNode* item : specList->contents()) {
uint32_t line;
JS::LimitedColumnNumberOneOrigin column;
eitherParser_.computeLineAndColumn(item->pn_pos.begin, &line, &column);
StencilModuleEntry entry;
TaggedParserAtomIndex localName;
if (item->isKind(ParseNodeKind::ImportSpec)) {
auto* spec = &item->as<BinaryNode>();
auto* importNameNode = &spec->left()->as<NameNode>();
auto* localNameNode = &spec->right()->as<NameNode>();
auto importName = importNameNode->atom();
localName = localNameNode->atom();
markUsedByStencil(localName);
markUsedByStencil(importName);
entry = StencilModuleEntry::importEntry(
moduleRequestIndex, localName, importName, line,
JS::ColumnNumberOneOrigin(column));
} else {
MOZ_ASSERT(item->isKind(ParseNodeKind::ImportNamespaceSpec));
auto* spec = &item->as<UnaryNode>();
auto* localNameNode = &spec->kid()->as<NameNode>();
localName = localNameNode->atom();
markUsedByStencil(localName);
entry = StencilModuleEntry::importNamespaceEntry(
moduleRequestIndex, localName, line,
JS::ColumnNumberOneOrigin(column));
}
if (!importEntries_.put(localName, entry)) {
return false;
}
}
return true;
}
bool ModuleBuilder::processExport(frontend::ParseNode* exportNode) {
using namespace js::frontend;
MOZ_ASSERT(exportNode->isKind(ParseNodeKind::ExportStmt) ||
exportNode->isKind(ParseNodeKind::ExportDefaultStmt));
bool isDefault = exportNode->isKind(ParseNodeKind::ExportDefaultStmt);
ParseNode* kid = isDefault ? exportNode->as<BinaryNode>().left()
: exportNode->as<UnaryNode>().kid();
if (isDefault && exportNode->as<BinaryNode>().right()) {
// This is an export default containing an expression.
auto localName = TaggedParserAtomIndex::WellKnown::default_();
auto exportName = TaggedParserAtomIndex::WellKnown::default_();
return appendExportEntry(exportName, localName);
}
switch (kid->getKind()) {
case ParseNodeKind::ExportSpecList: {
MOZ_ASSERT(!isDefault);
for (ParseNode* item : kid->as<ListNode>().contents()) {
BinaryNode* spec = &item->as<BinaryNode>();
MOZ_ASSERT(spec->isKind(ParseNodeKind::ExportSpec));
NameNode* localNameNode = &spec->left()->as<NameNode>();
NameNode* exportNameNode = &spec->right()->as<NameNode>();
auto localName = localNameNode->atom();
auto exportName = exportNameNode->atom();
if (!appendExportEntry(exportName, localName, spec)) {
return false;
}
}
break;
}
case ParseNodeKind::ClassDecl: {
const ClassNode& cls = kid->as<ClassNode>();
MOZ_ASSERT(cls.names());
auto localName = cls.names()->innerBinding()->atom();
auto exportName =
isDefault ? TaggedParserAtomIndex::WellKnown::default_() : localName;
if (!appendExportEntry(exportName, localName)) {
return false;
}
break;
}
case ParseNodeKind::VarStmt:
case ParseNodeKind::ConstDecl:
case ParseNodeKind::LetDecl: {
for (ParseNode* binding : kid->as<ListNode>().contents()) {
if (binding->isKind(ParseNodeKind::AssignExpr)) {
binding = binding->as<AssignmentNode>().left();
} else {
MOZ_ASSERT(binding->isKind(ParseNodeKind::Name));
}
if (binding->isKind(ParseNodeKind::Name)) {
auto localName = binding->as<NameNode>().atom();
auto exportName = isDefault
? TaggedParserAtomIndex::WellKnown::default_()
: localName;
if (!appendExportEntry(exportName, localName)) {
return false;
}
} else if (binding->isKind(ParseNodeKind::ArrayExpr)) {
if (!processExportArrayBinding(&binding->as<ListNode>())) {
return false;
}
} else {
MOZ_ASSERT(binding->isKind(ParseNodeKind::ObjectExpr));
if (!processExportObjectBinding(&binding->as<ListNode>())) {
return false;
}
}
}
break;
}
case ParseNodeKind::Function: {
FunctionBox* box = kid->as<FunctionNode>().funbox();
MOZ_ASSERT(!box->isArrow());
auto localName = box->explicitName();
auto exportName =
isDefault ? TaggedParserAtomIndex::WellKnown::default_() : localName;
if (!appendExportEntry(exportName, localName)) {
return false;
}
break;
}
default:
MOZ_CRASH("Unexpected parse node");
}
return true;
}
bool ModuleBuilder::processExportBinding(frontend::ParseNode* binding) {
using namespace js::frontend;
if (binding->isKind(ParseNodeKind::Name)) {
auto name = binding->as<NameNode>().atom();
return appendExportEntry(name, name);
}
if (binding->isKind(ParseNodeKind::ArrayExpr)) {
return processExportArrayBinding(&binding->as<ListNode>());
}
MOZ_ASSERT(binding->isKind(ParseNodeKind::ObjectExpr));
return processExportObjectBinding(&binding->as<ListNode>());
}
bool ModuleBuilder::processExportArrayBinding(frontend::ListNode* array) {
using namespace js::frontend;
MOZ_ASSERT(array->isKind(ParseNodeKind::ArrayExpr));
for (ParseNode* node : array->contents()) {
if (node->isKind(ParseNodeKind::Elision)) {
continue;
}
if (node->isKind(ParseNodeKind::Spread)) {
node = node->as<UnaryNode>().kid();
} else if (node->isKind(ParseNodeKind::AssignExpr)) {
node = node->as<AssignmentNode>().left();
}
if (!processExportBinding(node)) {
return false;
}
}
return true;
}
bool ModuleBuilder::processExportObjectBinding(frontend::ListNode* obj) {
using namespace js::frontend;
MOZ_ASSERT(obj->isKind(ParseNodeKind::ObjectExpr));
for (ParseNode* node : obj->contents()) {
MOZ_ASSERT(node->isKind(ParseNodeKind::MutateProto) ||
node->isKind(ParseNodeKind::PropertyDefinition) ||
node->isKind(ParseNodeKind::Shorthand) ||
node->isKind(ParseNodeKind::Spread));
ParseNode* target;
if (node->isKind(ParseNodeKind::Spread)) {
target = node->as<UnaryNode>().kid();
} else {
if (node->isKind(ParseNodeKind::MutateProto)) {
target = node->as<UnaryNode>().kid();
} else {
target = node->as<BinaryNode>().right();
}
if (target->isKind(ParseNodeKind::AssignExpr)) {
target = target->as<AssignmentNode>().left();
}
}
if (!processExportBinding(target)) {
return false;
}
}
return true;
}
bool ModuleBuilder::processExportFrom(frontend::BinaryNode* exportNode) {
using namespace js::frontend;
MOZ_ASSERT(exportNode->isKind(ParseNodeKind::ExportFromStmt));
auto* specList = &exportNode->left()->as<ListNode>();
MOZ_ASSERT(specList->isKind(ParseNodeKind::ExportSpecList));
auto* moduleRequest = &exportNode->right()->as<BinaryNode>();
MOZ_ASSERT(moduleRequest->isKind(ParseNodeKind::ImportModuleRequest));
auto* moduleSpec = &moduleRequest->left()->as<NameNode>();
MOZ_ASSERT(moduleSpec->isKind(ParseNodeKind::StringExpr));
auto* assertionList = &moduleRequest->right()->as<ListNode>();
MOZ_ASSERT(assertionList->isKind(ParseNodeKind::ImportAttributeList));
auto specifier = moduleSpec->atom();
MaybeModuleRequestIndex moduleRequestIndex =
appendModuleRequest(specifier, assertionList);
if (!moduleRequestIndex.isSome()) {
return false;
}
if (!maybeAppendRequestedModule(moduleRequestIndex, moduleSpec)) {
return false;
}
for (ParseNode* spec : specList->contents()) {
uint32_t line;
JS::LimitedColumnNumberOneOrigin column;
eitherParser_.computeLineAndColumn(spec->pn_pos.begin, &line, &column);
StencilModuleEntry entry;
TaggedParserAtomIndex exportName;
if (spec->isKind(ParseNodeKind::ExportSpec)) {
auto* importNameNode = &spec->as<BinaryNode>().left()->as<NameNode>();
auto* exportNameNode = &spec->as<BinaryNode>().right()->as<NameNode>();
auto importName = importNameNode->atom();
exportName = exportNameNode->atom();
markUsedByStencil(importName);
markUsedByStencil(exportName);
entry = StencilModuleEntry::exportFromEntry(
moduleRequestIndex, importName, exportName, line,
JS::ColumnNumberOneOrigin(column));
} else if (spec->isKind(ParseNodeKind::ExportNamespaceSpec)) {
auto* exportNameNode = &spec->as<UnaryNode>().kid()->as<NameNode>();
exportName = exportNameNode->atom();
markUsedByStencil(exportName);
entry = StencilModuleEntry::exportNamespaceFromEntry(
moduleRequestIndex, exportName, line,
JS::ColumnNumberOneOrigin(column));
} else {
MOZ_ASSERT(spec->isKind(ParseNodeKind::ExportBatchSpecStmt));
entry = StencilModuleEntry::exportBatchFromEntry(
moduleRequestIndex, line, JS::ColumnNumberOneOrigin(column));
}
if (!exportEntries_.append(entry)) {
return false;
}
if (exportName && !exportNames_.put(exportName)) {
return false;
}
}
return true;
}
frontend::StencilModuleEntry* ModuleBuilder::importEntryFor(
frontend::TaggedParserAtomIndex localName) const {
MOZ_ASSERT(localName);
auto ptr = importEntries_.lookup(localName);
if (!ptr) {
return nullptr;
}
return &ptr->value();
}
bool ModuleBuilder::hasExportedName(
frontend::TaggedParserAtomIndex name) const {
MOZ_ASSERT(name);
return exportNames_.has(name);
}
bool ModuleBuilder::appendExportEntry(
frontend::TaggedParserAtomIndex exportName,
frontend::TaggedParserAtomIndex localName, frontend::ParseNode* node) {
uint32_t line = 0;
JS::LimitedColumnNumberOneOrigin column;
if (node) {
eitherParser_.computeLineAndColumn(node->pn_pos.begin, &line, &column);
}
markUsedByStencil(localName);
markUsedByStencil(exportName);
auto entry = frontend::StencilModuleEntry::exportAsEntry(
localName, exportName, line, JS::ColumnNumberOneOrigin(column));
if (!exportEntries_.append(entry)) {
return false;
}
if (!exportNames_.put(exportName)) {
return false;
}
return true;
}
frontend::MaybeModuleRequestIndex ModuleBuilder::appendModuleRequest(
frontend::TaggedParserAtomIndex specifier,
frontend::ListNode* assertionList) {
markUsedByStencil(specifier);
auto request = frontend::StencilModuleRequest(specifier);
if (!processAssertions(request, assertionList)) {
return MaybeModuleRequestIndex();
}
uint32_t index = moduleRequests_.length();
if (!moduleRequests_.append(request)) {
js::ReportOutOfMemory(fc_);
return MaybeModuleRequestIndex();
}
return MaybeModuleRequestIndex(index);
}
bool ModuleBuilder::maybeAppendRequestedModule(
MaybeModuleRequestIndex moduleRequest, frontend::ParseNode* node) {
auto specifier = moduleRequests_[moduleRequest.value()].specifier;
if (requestedModuleSpecifiers_.has(specifier)) {
return true;
}
uint32_t line;
JS::LimitedColumnNumberOneOrigin column;
eitherParser_.computeLineAndColumn(node->pn_pos.begin, &line, &column);
auto entry = frontend::StencilModuleEntry::requestedModule(
moduleRequest, line, JS::ColumnNumberOneOrigin(column));
if (!requestedModules_.append(entry)) {
js::ReportOutOfMemory(fc_);
return false;
}
return requestedModuleSpecifiers_.put(specifier);
}
void ModuleBuilder::markUsedByStencil(frontend::TaggedParserAtomIndex name) {
// Imported/exported identifiers must be atomized.
eitherParser_.parserAtoms().markUsedByStencil(
name, frontend::ParserAtom::Atomize::Yes);
}
JSObject* js::GetOrCreateModuleMetaObject(JSContext* cx,
HandleObject moduleArg) {
Handle<ModuleObject*> module = moduleArg.as<ModuleObject>();
if (JSObject* obj = module->metaObject()) {
return obj;
}
RootedObject metaObject(cx, NewPlainObjectWithProto(cx, nullptr));
if (!metaObject) {
return nullptr;
}
JS::ModuleMetadataHook func = cx->runtime()->moduleMetadataHook;
if (!func) {
JS_ReportErrorASCII(cx, "Module metadata hook not set");
return nullptr;
}
RootedValue modulePrivate(cx, JS::GetModulePrivate(module));
if (!func(cx, modulePrivate, metaObject)) {
return nullptr;
}
module->setMetaObject(metaObject);
return metaObject;
}
ModuleObject* js::CallModuleResolveHook(JSContext* cx,
HandleValue referencingPrivate,
HandleObject moduleRequest) {
JS::ModuleResolveHook moduleResolveHook = cx->runtime()->moduleResolveHook;
if (!moduleResolveHook) {
JS_ReportErrorASCII(cx, "Module resolve hook not set");
return nullptr;
}
RootedObject result(cx,
moduleResolveHook(cx, referencingPrivate, moduleRequest));
if (!result) {
return nullptr;
}
if (!result->is<ModuleObject>()) {
JS_ReportErrorASCII(cx, "Module resolve hook did not return Module object");
return nullptr;
}
return &result->as<ModuleObject>();
}
bool ModuleObject::topLevelCapabilityResolve(JSContext* cx,
Handle<ModuleObject*> module) {
RootedValue rval(cx);
Rooted<PromiseObject*> promise(
cx, &module->topLevelCapability()->as<PromiseObject>());
return AsyncFunctionReturned(cx, promise, rval);
}
bool ModuleObject::topLevelCapabilityReject(JSContext* cx,
Handle<ModuleObject*> module,
HandleValue error) {
Rooted<PromiseObject*> promise(
cx, &module->topLevelCapability()->as<PromiseObject>());
return AsyncFunctionThrown(cx, promise, error);
}
// NOTE: The caller needs to handle the promise.
static bool EvaluateDynamicImportOptions(
JSContext* cx, HandleValue optionsArg,
MutableHandle<ArrayObject*> assertionArrayArg) {
// Step 10. If options is not undefined, then.
if (optionsArg.isUndefined()) {
return true;
}
// Step 10.a. If Type(options) is not Object,
if (!optionsArg.isObject()) {
JS_ReportErrorNumberASCII(
cx, GetErrorMessage, nullptr, JSMSG_NOT_EXPECTED_TYPE, "import",
"object or undefined", InformalValueTypeName(optionsArg));
return false;
}
RootedObject assertWrapperObject(cx, &optionsArg.toObject());
RootedValue assertValue(cx);
// Step 10.b. Let attributesObj be Completion(Get(options, "with")).
RootedId withId(cx, NameToId(cx->names().with));
if (!GetProperty(cx, assertWrapperObject, assertWrapperObject, withId,
&assertValue)) {
return false;
}
if (assertValue.isUndefined() &&
cx->options().importAttributesAssertSyntax()) {
// Step 10.b. Let assertionsObj be Get(options, "assert").
RootedId assertId(cx, NameToId(cx->names().assert_));
if (!GetProperty(cx, assertWrapperObject, assertWrapperObject, assertId,
&assertValue)) {
return false;
}
}
// Step 10.d. If assertionsObj is not undefined.
if (assertValue.isUndefined()) {
return true;
}
// Step 10.d.i. If Type(assertionsObj) is not Object.
if (!assertValue.isObject()) {
JS_ReportErrorNumberASCII(
cx, GetErrorMessage, nullptr, JSMSG_NOT_EXPECTED_TYPE, "import",
"object or undefined", InformalValueTypeName(assertValue));
return false;
}
// Step 10.d.i. Let keys be EnumerableOwnPropertyNames(assertionsObj, key).
RootedObject assertObject(cx, &assertValue.toObject());
RootedIdVector assertions(cx);
if (!GetPropertyKeys(cx, assertObject, JSITER_OWNONLY, &assertions)) {
return false;
}
uint32_t numberOfAssertions = assertions.length();
if (numberOfAssertions == 0) {
return true;
}
// Step 9 (reordered). Let assertions be a new empty List.
Rooted<ArrayObject*> assertionArray(
cx, NewDenseFullyAllocatedArray(cx, numberOfAssertions));
if (!assertionArray) {
return false;
}
assertionArray->ensureDenseInitializedLength(0, numberOfAssertions);
// Step 10.d.iv. Let supportedAssertions be
// !HostGetSupportedImportAssertions().
// Note: This should be driven by a host hook, howver the infrastructure of
// said host hook is deeply unclear, and so right now embedders will
// not have the ability to alter or extend the set of supported
// assertion types.
size_t numberOfValidAssertions = 0;
// Step 10.d.v. For each String key of keys,
RootedId key(cx);
for (size_t i = 0; i < numberOfAssertions; i++) {
key = assertions[i];
// Step 10.d.v.1. Let value be Get(assertionsObj, key).
RootedValue value(cx);
if (!GetProperty(cx, assertObject, assertObject, key, &value)) {
return false;
}
// Step 10.d.v.3. If Type(value) is not String, then.
if (!value.isString()) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
JSMSG_NOT_EXPECTED_TYPE, "import", "string",
InformalValueTypeName(value));
return false;
}
// Step 10.d.v.4. If supportedAssertions contains key, then Append {
// [[Key]]: key, [[Value]]: value } to assertions.
// Note: We only currently support the "type" assertion; this will need
// extension
bool supported = key.isAtom() ? key.toAtom() == cx->names().type : false;
if (supported) {
Rooted<PlainObject*> assertionObj(cx, NewPlainObject(cx));
if (!assertionObj) {
return false;
}
if (!DefineDataProperty(cx, assertionObj, key, value, JSPROP_ENUMERATE)) {
return false;
}
assertionArray->initDenseElement(numberOfValidAssertions,
ObjectValue(*assertionObj));
++numberOfValidAssertions;
}
}
if (numberOfValidAssertions == 0) {
return true;
}
assertionArray->setLength(numberOfValidAssertions);
assertionArrayArg.set(assertionArray);
return true;
}
// ShadowRealmImportValue duplicates some of this, so be sure to keep these in
// sync.
JSObject* js::StartDynamicModuleImport(JSContext* cx, HandleScript script,
HandleValue specifierArg,
HandleValue optionsArg) {
RootedObject promiseConstructor(cx, JS::GetPromiseConstructor(cx));
if (!promiseConstructor) {
return nullptr;
}
RootedObject promiseObject(cx, JS::NewPromiseObject(cx, nullptr));
if (!promiseObject) {
return nullptr;
}
Handle<PromiseObject*> promise = promiseObject.as<PromiseObject>();
JS::ModuleDynamicImportHook importHook =
cx->runtime()->moduleDynamicImportHook;
if (!importHook) {
// Dynamic import can be disabled by a pref and is not supported in all
// contexts (e.g. web workers).
JS_ReportErrorASCII(
cx,
"Dynamic module import is disabled or not supported in this context");
if (!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
RootedString specifier(cx, ToString(cx, specifierArg));
if (!specifier) {
if (!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
Rooted<JSAtom*> specifierAtom(cx, AtomizeString(cx, specifier));
if (!specifierAtom) {
if (!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
Rooted<ArrayObject*> assertionArray(cx);
if (!EvaluateDynamicImportOptions(cx, optionsArg, &assertionArray)) {
if (!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
RootedObject moduleRequest(
cx, ModuleRequestObject::create(cx, specifierAtom, assertionArray));
if (!moduleRequest) {
if (!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
RootedValue referencingPrivate(cx, script->sourceObject()->getPrivate());
if (!importHook(cx, referencingPrivate, moduleRequest, promise)) {
// If there's no exception pending then the script is terminating
// anyway, so just return nullptr.
if (!cx->isExceptionPending() ||
!RejectPromiseWithPendingError(cx, promise)) {
return nullptr;
}
return promise;
}
return promise;
}
static bool OnRootModuleRejected(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
HandleValue error = args.get(0);
ReportExceptionClosure reportExn(error);
PrepareScriptEnvironmentAndInvoke(cx, cx->global(), reportExn);
args.rval().setUndefined();
return true;
};
bool js::OnModuleEvaluationFailure(JSContext* cx,
HandleObject evaluationPromise,
JS::ModuleErrorBehaviour errorBehaviour) {
if (evaluationPromise == nullptr) {
return false;
}
// To allow module evaluation to happen synchronously throw the error
// immediately. This assumes that any error will already have caused the
// promise to be rejected, and doesn't support top-level await.
if (errorBehaviour == JS::ThrowModuleErrorsSync) {
JS::PromiseState state = JS::GetPromiseState(evaluationPromise);
MOZ_DIAGNOSTIC_ASSERT(state == JS::PromiseState::Rejected ||
state == JS::PromiseState::Fulfilled);
JS::SetSettledPromiseIsHandled(cx, evaluationPromise);
if (state == JS::PromiseState::Fulfilled) {
return true;
}
RootedValue error(cx, JS::GetPromiseResult(evaluationPromise));
JS_SetPendingException(cx, error);
return false;
}
RootedFunction onRejected(
cx, NewHandler(cx, OnRootModuleRejected, evaluationPromise));
if (!onRejected) {
return false;
}
return JS::AddPromiseReactions(cx, evaluationPromise, nullptr, onRejected);
}
// This is used to marshal some of the arguments to FinishDynamicModuleImport
// and pass them through to the promise resolve and reject callbacks. It holds a
// reference to the referencing private to keep it alive until it is needed.
class DynamicImportContextObject : public NativeObject {
public:
enum { ReferencingPrivateSlot = 0, SpecifierSlot, SlotCount };
static const JSClass class_;
static const JSClassOps classOps_;
[[nodiscard]] static DynamicImportContextObject* create(
JSContext* cx, Handle<Value> referencingPrivate,
Handle<JSString*> specifier);
Value referencingPrivate() const;
JSString* specifier() const;
static void clearReferencingPrivate(JSRuntime* runtime,
DynamicImportContextObject* ic);
static void finalize(JS::GCContext* gcx, JSObject* obj);
};
/* static */
const JSClass DynamicImportContextObject::class_ = {
"DynamicImportContextObject",
JSCLASS_HAS_RESERVED_SLOTS(DynamicImportContextObject::SlotCount) |
JSCLASS_SLOT0_IS_NSISUPPORTS | JSCLASS_FOREGROUND_FINALIZE,
&DynamicImportContextObject::classOps_};
static_assert(DynamicImportContextObject::ReferencingPrivateSlot == 0);
/* static */
const JSClassOps DynamicImportContextObject::classOps_ = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
DynamicImportContextObject::finalize, // finalize
nullptr, // call
nullptr, // construct
nullptr, // trace
};
/* static */
DynamicImportContextObject* DynamicImportContextObject::create(
JSContext* cx, Handle<Value> referencingPrivate,
Handle<JSString*> specifier) {
Rooted<DynamicImportContextObject*> self(
cx, NewObjectWithGivenProto<DynamicImportContextObject>(cx, nullptr));
if (!self) {
return nullptr;
}
cx->runtime()->addRefScriptPrivate(referencingPrivate);
self->initReservedSlot(ReferencingPrivateSlot, referencingPrivate);
self->initReservedSlot(SpecifierSlot, StringValue(specifier));
return self;
}
Value DynamicImportContextObject::referencingPrivate() const {
return getReservedSlot(ReferencingPrivateSlot);
}
JSString* DynamicImportContextObject::specifier() const {
Value value = getReservedSlot(SpecifierSlot);
if (value.isUndefined()) {
return nullptr;
}
return value.toString();
}
/* static */
void DynamicImportContextObject::finalize(JS::GCContext* gcx, JSObject* obj) {
auto* context = &obj->as<DynamicImportContextObject>();
clearReferencingPrivate(gcx->runtime(), context);
}
/* static */
void DynamicImportContextObject::clearReferencingPrivate(
JSRuntime* runtime, DynamicImportContextObject* context) {
Value value = context->referencingPrivate();
if (!value.isUndefined()) {
context->setReservedSlot(ReferencingPrivateSlot, UndefinedValue());
runtime->releaseScriptPrivate(value);
}
}
// Adjustment for Top-level await;
static bool OnResolvedDynamicModule(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
MOZ_ASSERT(args.get(0).isUndefined());
Rooted<DynamicImportContextObject*> context(
cx, ExtraFromHandler<DynamicImportContextObject>(args));
auto clearRef = mozilla::MakeScopeExit([&] {
DynamicImportContextObject::clearReferencingPrivate(cx->runtime(), context);
});
RootedValue referencingPrivate(cx, context->referencingPrivate());
Rooted<JSAtom*> specifier(cx, AtomizeString(cx, context->specifier()));
if (!specifier) {
return false;
}
Rooted<PromiseObject*> promise(cx, TargetFromHandler<PromiseObject>(args));
RootedObject moduleRequest(
cx, ModuleRequestObject::create(cx, specifier, nullptr));
if (!moduleRequest) {
return RejectPromiseWithPendingError(cx, promise);
}
RootedObject result(
cx, CallModuleResolveHook(cx, referencingPrivate, moduleRequest));
if (!result) {
return RejectPromiseWithPendingError(cx, promise);
}
Rooted<ModuleObject*> module(cx, &result->as<ModuleObject>());
if (module->status() != ModuleStatus::EvaluatingAsync &&
module->status() != ModuleStatus::Evaluated) {
JS_ReportErrorASCII(
cx, "Unevaluated or errored module returned by module resolve hook");
return RejectPromiseWithPendingError(cx, promise);
}
MOZ_ASSERT_IF(module->hasCyclicModuleFields(),
module->getCycleRoot()
->topLevelCapability()
->as<PromiseObject>()
.state() == JS::PromiseState::Fulfilled);
RootedObject ns(cx, GetOrCreateModuleNamespace(cx, module));
if (!ns) {
return RejectPromiseWithPendingError(cx, promise);
}
args.rval().setUndefined();
RootedValue value(cx, ObjectValue(*ns));
return PromiseObject::resolve(cx, promise, value);
};
static bool OnRejectedDynamicModule(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
HandleValue error = args.get(0);
Rooted<DynamicImportContextObject*> context(
cx, ExtraFromHandler<DynamicImportContextObject>(args));
auto clearRef = mozilla::MakeScopeExit([&] {
DynamicImportContextObject::clearReferencingPrivate(cx->runtime(), context);
});
RootedValue referencingPrivate(cx, context->referencingPrivate());
Rooted<PromiseObject*> promise(cx, TargetFromHandler<PromiseObject>(args));
args.rval().setUndefined();
return PromiseObject::reject(cx, promise, error);
};
bool js::FinishDynamicModuleImport(JSContext* cx,
HandleObject evaluationPromise,
HandleValue referencingPrivate,
HandleObject moduleRequest,
HandleObject promise) {
// If we do not have an evaluation promise or a module request for the module,
// we can assume that evaluation has failed or been interrupted -- we can
// reject the dynamic module.
if (!evaluationPromise || !moduleRequest) {
return RejectPromiseWithPendingError(cx, promise.as<PromiseObject>());
}
Rooted<JSString*> specifier(
cx, moduleRequest->as<ModuleRequestObject>().specifier());
Rooted<DynamicImportContextObject*> context(
cx,
DynamicImportContextObject::create(cx, referencingPrivate, specifier));
if (!context) {
return false;
}
Rooted<Value> contextValue(cx, ObjectValue(*context));
RootedFunction onResolved(
cx, NewHandlerWithExtraValue(cx, OnResolvedDynamicModule, promise,
contextValue));
if (!onResolved) {
return false;
}
RootedFunction onRejected(
cx, NewHandlerWithExtraValue(cx, OnRejectedDynamicModule, promise,
contextValue));
if (!onRejected) {
return false;
}
if (!JS::AddPromiseReactionsIgnoringUnhandledRejection(
cx, evaluationPromise, onResolved, onRejected)) {
return false;
}
return true;
}