/* -*- 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 iterators. */ #include "vm/Iteration.h" #include "mozilla/ArrayUtils.h" #include "mozilla/DebugOnly.h" #include "mozilla/Likely.h" #include "mozilla/Maybe.h" #include "mozilla/MemoryReporting.h" #include "mozilla/PodOperations.h" #include "mozilla/Unused.h" #include #include #include "jstypes.h" #include "builtin/Array.h" #include "builtin/SelfHostingDefines.h" #include "ds/Sort.h" #include "gc/FreeOp.h" #include "gc/Marking.h" #include "js/friend/ErrorMessages.h" // js::GetErrorMessage, JSMSG_* #include "js/PropertySpec.h" #include "js/Proxy.h" #include "util/DifferentialTesting.h" #include "util/Poison.h" #include "vm/BytecodeUtil.h" #include "vm/GlobalObject.h" #include "vm/Interpreter.h" #include "vm/JSAtom.h" #include "vm/JSContext.h" #include "vm/JSObject.h" #include "vm/JSScript.h" #include "vm/NativeObject.h" // js::PlainObject #include "vm/Shape.h" #include "vm/TypedArrayObject.h" #include "vm/Compartment-inl.h" #include "vm/JSScript-inl.h" #include "vm/NativeObject-inl.h" #include "vm/PlainObject-inl.h" // js::PlainObject::createWithTemplate #include "vm/ReceiverGuard-inl.h" #include "vm/Stack-inl.h" #include "vm/StringType-inl.h" using namespace js; using mozilla::ArrayEqual; using mozilla::DebugOnly; using mozilla::Maybe; using mozilla::PodCopy; using RootedPropertyIteratorObject = Rooted; static const gc::AllocKind ITERATOR_FINALIZE_KIND = gc::AllocKind::OBJECT2_BACKGROUND; // Beware! This function may have to trace incompletely-initialized // |NativeIterator| allocations if the |IdToString| in that constructor recurs // into this code. void NativeIterator::trace(JSTracer* trc) { TraceNullableEdge(trc, &objectBeingIterated_, "objectBeingIterated_"); TraceNullableEdge(trc, &iterObj_, "iterObj"); // The limits below are correct at every instant of |NativeIterator| // initialization, with the end-pointer incremented as each new guard is // created, so they're safe to use here. std::for_each(guardsBegin(), guardsEnd(), [trc](HeapReceiverGuard& guard) { guard.trace(trc); }); // But as properties must be created *before* guards, |propertiesBegin()| // that depends on |guardsEnd()| having its final value can't safely be // used. Until this is fully initialized, use |propertyCursor_| instead, // which points at the start of properties even in partially initialized // |NativeIterator|s. (|propertiesEnd()| is safe at all times with respect // to the properly-chosen beginning.) // // Note that we must trace all properties (not just those not yet visited, // or just visited, due to |NativeIterator::previousPropertyWas|) for // |NativeIterator|s to be reusable. GCPtrLinearString* begin = MOZ_LIKELY(isInitialized()) ? propertiesBegin() : propertyCursor_; std::for_each(begin, propertiesEnd(), [trc](GCPtrLinearString& prop) { // Properties begin life non-null and never *become* // null. (Deletion-suppression will shift trailing // properties over a deleted property in the properties // array, but it doesn't null them out.) TraceEdge(trc, &prop, "prop"); }); } using IdSet = GCHashSet>; template static inline bool Enumerate(JSContext* cx, HandleObject pobj, jsid id, bool enumerable, unsigned flags, MutableHandle visited, MutableHandleIdVector props) { if (CheckForDuplicates) { // If we've already seen this, we definitely won't add it. IdSet::AddPtr p = visited.lookupForAdd(id); if (MOZ_UNLIKELY(!!p)) { return true; } // It's not necessary to add properties to the hash set at the end of // the prototype chain, but custom enumeration behaviors might return // duplicated properties, so always add in such cases. if (pobj->is() || pobj->staticPrototype() || pobj->getClass()->getNewEnumerate()) { if (!visited.add(p, id)) { return false; } } } if (!enumerable && !(flags & JSITER_HIDDEN)) { return true; } // Symbol-keyed properties and nonenumerable properties are skipped unless // the caller specifically asks for them. A caller can also filter out // non-symbols by asking for JSITER_SYMBOLSONLY. PrivateName symbols are // skipped unless JSITER_PRIVATE is passed. if (JSID_IS_SYMBOL(id)) { if (!(flags & JSITER_SYMBOLS)) { return true; } if (!(flags & JSITER_PRIVATE) && id.isPrivateName()) { return true; } } else { if ((flags & JSITER_SYMBOLSONLY)) { return true; } } return props.append(id); } static bool EnumerateExtraProperties(JSContext* cx, HandleObject obj, unsigned flags, MutableHandle visited, MutableHandleIdVector props) { MOZ_ASSERT(obj->getClass()->getNewEnumerate()); RootedIdVector properties(cx); bool enumerableOnly = !(flags & JSITER_HIDDEN); if (!obj->getClass()->getNewEnumerate()(cx, obj, &properties, enumerableOnly)) { return false; } RootedId id(cx); for (size_t n = 0; n < properties.length(); n++) { id = properties[n]; // The enumerate hook does not indicate whether the properties // it returns are enumerable or not. Since we already passed // `enumerableOnly` to the hook to filter out non-enumerable // properties, it doesn't really matter what we pass here. bool enumerable = true; if (!Enumerate(cx, obj, id, enumerable, flags, visited, props)) { return false; } } return true; } static bool SortComparatorIntegerIds(jsid a, jsid b, bool* lessOrEqualp) { uint32_t indexA, indexB; MOZ_ALWAYS_TRUE(IdIsIndex(a, &indexA)); MOZ_ALWAYS_TRUE(IdIsIndex(b, &indexB)); *lessOrEqualp = (indexA <= indexB); return true; } template static bool EnumerateNativeProperties(JSContext* cx, HandleNativeObject pobj, unsigned flags, MutableHandle visited, MutableHandleIdVector props) { bool enumerateSymbols; if (flags & JSITER_SYMBOLSONLY) { enumerateSymbols = true; } else { // Collect any dense elements from this object. size_t firstElemIndex = props.length(); size_t initlen = pobj->getDenseInitializedLength(); const Value* vp = pobj->getDenseElements(); bool hasHoles = false; for (size_t i = 0; i < initlen; ++i, ++vp) { if (vp->isMagic(JS_ELEMENTS_HOLE)) { hasHoles = true; } else { // Dense arrays never get so large that i would not fit into an // integer id. if (!Enumerate(cx, pobj, INT_TO_JSID(i), /* enumerable = */ true, flags, visited, props)) { return false; } } } // Collect any typed array or shared typed array elements from this // object. if (pobj->is()) { size_t len = pobj->as().length().get(); // Fail early if the typed array is enormous, because this will be very // slow and will likely report OOM. This also means we don't need to // handle indices greater than JSID_INT_MAX in the loop below. static_assert(JSID_INT_MAX == INT32_MAX); if (len > INT32_MAX) { ReportOutOfMemory(cx); return false; } for (size_t i = 0; i < len; i++) { if (!Enumerate(cx, pobj, INT_TO_JSID(i), /* enumerable = */ true, flags, visited, props)) { return false; } } } // Collect any sparse elements from this object. bool isIndexed = pobj->isIndexed(); if (isIndexed) { // If the dense elements didn't have holes, we don't need to include // them in the sort. if (!hasHoles) { firstElemIndex = props.length(); } for (Shape::Range r(pobj->lastProperty()); !r.empty(); r.popFront()) { Shape& shape = r.front(); jsid id = shape.propid(); uint32_t dummy; if (IdIsIndex(id, &dummy)) { if (!Enumerate(cx, pobj, id, shape.enumerable(), flags, visited, props)) { return false; } } } MOZ_ASSERT(firstElemIndex <= props.length()); jsid* ids = props.begin() + firstElemIndex; size_t n = props.length() - firstElemIndex; RootedIdVector tmp(cx); if (!tmp.resize(n)) { return false; } PodCopy(tmp.begin(), ids, n); if (!MergeSort(ids, n, tmp.begin(), SortComparatorIntegerIds)) { return false; } } size_t initialLength = props.length(); /* Collect all unique property names from this object's shape. */ bool symbolsFound = false; Shape::Range r(pobj->lastProperty()); for (; !r.empty(); r.popFront()) { Shape& shape = r.front(); jsid id = shape.propid(); if (JSID_IS_SYMBOL(id)) { symbolsFound = true; continue; } uint32_t dummy; if (isIndexed && IdIsIndex(id, &dummy)) { continue; } if (!Enumerate(cx, pobj, id, shape.enumerable(), flags, visited, props)) { return false; } } std::reverse(props.begin() + initialLength, props.end()); enumerateSymbols = symbolsFound && (flags & JSITER_SYMBOLS); } if (enumerateSymbols) { // Do a second pass to collect symbols. ES6 draft rev 25 (2014 May 22) // 9.1.12 requires that all symbols appear after all strings in the // result. size_t initialLength = props.length(); for (Shape::Range r(pobj->lastProperty()); !r.empty(); r.popFront()) { Shape& shape = r.front(); jsid id = shape.propid(); if (JSID_IS_SYMBOL(id)) { if (!Enumerate(cx, pobj, id, shape.enumerable(), flags, visited, props)) { return false; } } } std::reverse(props.begin() + initialLength, props.end()); } return true; } static bool EnumerateNativeProperties(JSContext* cx, HandleNativeObject pobj, unsigned flags, MutableHandle visited, MutableHandleIdVector props, bool checkForDuplicates) { if (checkForDuplicates) { return EnumerateNativeProperties(cx, pobj, flags, visited, props); } return EnumerateNativeProperties(cx, pobj, flags, visited, props); } template static bool EnumerateProxyProperties(JSContext* cx, HandleObject pobj, unsigned flags, MutableHandle visited, MutableHandleIdVector props) { MOZ_ASSERT(pobj->is()); RootedIdVector proxyProps(cx); if (flags & JSITER_HIDDEN || flags & JSITER_SYMBOLS) { // This gets all property keys, both strings and symbols. The call to // Enumerate in the loop below will filter out unwanted keys, per the // flags. if (!Proxy::ownPropertyKeys(cx, pobj, &proxyProps)) { return false; } Rooted desc(cx); for (size_t n = 0, len = proxyProps.length(); n < len; n++) { bool enumerable = false; // We need to filter, if the caller just wants enumerable symbols. if (!(flags & JSITER_HIDDEN)) { if (!Proxy::getOwnPropertyDescriptor(cx, pobj, proxyProps[n], &desc)) { return false; } enumerable = desc.enumerable(); } if (!Enumerate(cx, pobj, proxyProps[n], enumerable, flags, visited, props)) { return false; } } return true; } // Returns enumerable property names (no symbols). if (!Proxy::getOwnEnumerablePropertyKeys(cx, pobj, &proxyProps)) { return false; } for (size_t n = 0, len = proxyProps.length(); n < len; n++) { if (!Enumerate(cx, pobj, proxyProps[n], true, flags, visited, props)) { return false; } } return true; } #ifdef DEBUG struct SortComparatorIds { JSContext* const cx; explicit SortComparatorIds(JSContext* cx) : cx(cx) {} bool operator()(jsid aArg, jsid bArg, bool* lessOrEqualp) { RootedId a(cx, aArg); RootedId b(cx, bArg); // Pick an arbitrary order on jsids that is as stable as possible // across executions. if (a == b) { *lessOrEqualp = true; return true; } size_t ta = JSID_BITS(a.get()) & JSID_TYPE_MASK; size_t tb = JSID_BITS(b.get()) & JSID_TYPE_MASK; if (ta != tb) { *lessOrEqualp = (ta <= tb); return true; } if (JSID_IS_INT(a)) { *lessOrEqualp = (JSID_TO_INT(a) <= JSID_TO_INT(b)); return true; } RootedString astr(cx), bstr(cx); if (JSID_IS_SYMBOL(a)) { MOZ_ASSERT(JSID_IS_SYMBOL(b)); JS::SymbolCode ca = JSID_TO_SYMBOL(a)->code(); JS::SymbolCode cb = JSID_TO_SYMBOL(b)->code(); if (ca != cb) { *lessOrEqualp = uint32_t(ca) <= uint32_t(cb); return true; } MOZ_ASSERT(ca == JS::SymbolCode::InSymbolRegistry || ca == JS::SymbolCode::UniqueSymbol); astr = JSID_TO_SYMBOL(a)->description(); bstr = JSID_TO_SYMBOL(b)->description(); if (!astr || !bstr) { *lessOrEqualp = !astr; return true; } // Fall through to string comparison on the descriptions. The sort // order is nondeterministic if two different unique symbols have // the same description. } else { astr = IdToString(cx, a); if (!astr) { return false; } bstr = IdToString(cx, b); if (!bstr) { return false; } } int32_t result; if (!CompareStrings(cx, astr, bstr, &result)) { return false; } *lessOrEqualp = (result <= 0); return true; } }; #endif /* DEBUG */ static bool Snapshot(JSContext* cx, HandleObject pobj_, unsigned flags, MutableHandleIdVector props) { Rooted visited(cx, IdSet(cx)); RootedObject pobj(cx, pobj_); // Don't check for duplicates if we're only interested in own properties. // This does the right thing for most objects: native objects don't have // duplicate property ids and we allow the [[OwnPropertyKeys]] proxy trap to // return duplicates. // // The only special case is when the object has a newEnumerate hook: it // can return duplicate properties and we have to filter them. This is // handled below. bool checkForDuplicates = !(flags & JSITER_OWNONLY); do { if (pobj->getClass()->getNewEnumerate()) { if (!EnumerateExtraProperties(cx, pobj, flags, &visited, props)) { return false; } if (pobj->isNative()) { if (!EnumerateNativeProperties(cx, pobj.as(), flags, &visited, props, true)) { return false; } } } else if (pobj->isNative()) { // Give the object a chance to resolve all lazy properties if (JSEnumerateOp enumerate = pobj->getClass()->getEnumerate()) { if (!enumerate(cx, pobj.as())) { return false; } } if (!EnumerateNativeProperties(cx, pobj.as(), flags, &visited, props, checkForDuplicates)) { return false; } } else if (pobj->is()) { if (checkForDuplicates) { if (!EnumerateProxyProperties(cx, pobj, flags, &visited, props)) { return false; } } else { if (!EnumerateProxyProperties(cx, pobj, flags, &visited, props)) { return false; } } } else { MOZ_CRASH("non-native objects must have an enumerate op"); } if (flags & JSITER_OWNONLY) { break; } if (!GetPrototype(cx, pobj, &pobj)) { return false; } // The [[Prototype]] chain might be cyclic. if (!CheckForInterrupt(cx)) { return false; } } while (pobj != nullptr); #ifdef DEBUG if (js::SupportDifferentialTesting()) { /* * In some cases the enumeration order for an object depends on the * execution mode (interpreter vs. JIT), especially for native objects * with a class enumerate hook (where resolving a property changes the * resulting enumeration order). These aren't really bugs, but the * differences can change the generated output and confuse correctness * fuzzers, so we sort the ids if such a fuzzer is running. * * We don't do this in the general case because (a) doing so is slow, * and (b) it also breaks the web, which expects enumeration order to * follow the order in which properties are added, in certain cases. * Since ECMA does not specify an enumeration order for objects, both * behaviors are technically correct to do. */ jsid* ids = props.begin(); size_t n = props.length(); RootedIdVector tmp(cx); if (!tmp.resize(n)) { return false; } PodCopy(tmp.begin(), ids, n); if (!MergeSort(ids, n, tmp.begin(), SortComparatorIds(cx))) { return false; } } #endif return true; } JS_FRIEND_API bool js::GetPropertyKeys(JSContext* cx, HandleObject obj, unsigned flags, MutableHandleIdVector props) { return Snapshot(cx, obj, flags & (JSITER_OWNONLY | JSITER_HIDDEN | JSITER_SYMBOLS | JSITER_SYMBOLSONLY | JSITER_PRIVATE), props); } static inline void RegisterEnumerator(ObjectRealm& realm, NativeIterator* ni) { // Register non-escaping native enumerators (for-in) with the current // context. ni->link(realm.enumerators); MOZ_ASSERT(!ni->isActive()); ni->markActive(); } static PropertyIteratorObject* NewPropertyIteratorObject(JSContext* cx) { RootedObjectGroup group( cx, ObjectGroup::defaultNewGroup(cx, &PropertyIteratorObject::class_, TaggedProto(nullptr))); if (!group) { return nullptr; } const JSClass* clasp = &PropertyIteratorObject::class_; RootedShape shape(cx, EmptyShape::getInitialShape(cx, clasp, TaggedProto(nullptr), ITERATOR_FINALIZE_KIND)); if (!shape) { return nullptr; } JSObject* obj; JS_TRY_VAR_OR_RETURN_NULL( cx, obj, NativeObject::create(cx, ITERATOR_FINALIZE_KIND, GetInitialHeap(GenericObject, group), shape, group)); PropertyIteratorObject* res = &obj->as(); // CodeGenerator::visitIteratorStartO assumes the iterator object is not // inside the nursery when deciding whether a barrier is necessary. MOZ_ASSERT(!js::gc::IsInsideNursery(res)); MOZ_ASSERT(res->numFixedSlots() == PropertyIteratorObject::NUM_FIXED_SLOTS); return res; } static inline size_t ExtraStringCount(size_t propertyCount, size_t guardCount) { static_assert(sizeof(ReceiverGuard) == 2 * sizeof(GCPtrLinearString), "NativeIterators are allocated in space for 1) themselves, " "2) the properties a NativeIterator iterates (as " "GCPtrLinearStrings), and 3) |numGuards| HeapReceiverGuard " "objects; the additional-length calculation below assumes " "this size-relationship when determining the extra space to " "allocate"); return propertyCount + guardCount * 2; } static inline size_t AllocationSize(size_t propertyCount, size_t guardCount) { return sizeof(NativeIterator) + (ExtraStringCount(propertyCount, guardCount) * sizeof(GCPtrLinearString)); } static PropertyIteratorObject* CreatePropertyIterator( JSContext* cx, Handle objBeingIterated, HandleIdVector props, uint32_t numGuards, uint32_t guardKey) { if (props.length() > NativeIterator::PropCountLimit) { ReportAllocationOverflow(cx); return nullptr; } Rooted propIter(cx, NewPropertyIteratorObject(cx)); if (!propIter) { return nullptr; } void* mem = cx->pod_malloc_with_extra( ExtraStringCount(props.length(), numGuards)); if (!mem) { return nullptr; } // This also registers |ni| with |propIter|. bool hadError = false; NativeIterator* ni = new (mem) NativeIterator( cx, propIter, objBeingIterated, props, numGuards, guardKey, &hadError); if (hadError) { return nullptr; } ObjectRealm& realm = objBeingIterated ? ObjectRealm::get(objBeingIterated) : ObjectRealm::get(propIter); RegisterEnumerator(realm, ni); return propIter; } /** * Initialize a sentinel NativeIterator whose purpose is only to act as the * start/end of the circular linked list of NativeIterators in * ObjectRealm::enumerators. */ NativeIterator::NativeIterator() { // Do our best to enforce that nothing in |this| except the two fields set // below is ever observed. AlwaysPoison(static_cast(this), JS_NEW_NATIVE_ITERATOR_PATTERN, sizeof(*this), MemCheckKind::MakeUndefined); // These are the only two fields in sentinel NativeIterators that are // examined, in ObjectRealm::traceWeakNativeIterators. Everything else is // only examined *if* it's a NativeIterator being traced by a // PropertyIteratorObject that owns it, and nothing owns this iterator. prev_ = next_ = this; } NativeIterator* NativeIterator::allocateSentinel(JSContext* cx) { NativeIterator* ni = js_new(); if (!ni) { ReportOutOfMemory(cx); return nullptr; } return ni; } /** * Initialize a fresh NativeIterator. * * This definition is a bit tricky: some parts of initializing are fallible, so * as we initialize, we must carefully keep this in GC-safe state (see * NativeIterator::trace). */ NativeIterator::NativeIterator(JSContext* cx, Handle propIter, Handle objBeingIterated, HandleIdVector props, uint32_t numGuards, uint32_t guardKey, bool* hadError) : objectBeingIterated_(objBeingIterated), iterObj_(propIter), // NativeIterator initially acts (before full initialization) as if it // contains no guards... guardsEnd_(guardsBegin()), // ...and no properties. propertyCursor_( reinterpret_cast(guardsBegin() + numGuards)), propertiesEnd_(propertyCursor_), guardKey_(guardKey), flagsAndCount_( initialFlagsAndCount(props.length())) // note: no Flags::Initialized { MOZ_ASSERT(!*hadError); // NOTE: This must be done first thing: The caller can't free `this` on error // because it has GCPtr fields whose barriers have already fired; the // store buffer has pointers to them. Only the GC can free `this` (via // PropertyIteratorObject::finalize). propIter->setNativeIterator(this); // The GC asserts on finalization that `this->allocationSize()` matches the // `nbytes` passed to `AddCellMemory`. So once these lines run, we must make // `this->allocationSize()` correct. That means infallibly initializing the // guards. It's OK for the constructor to fail after that. size_t nbytes = AllocationSize(props.length(), numGuards); AddCellMemory(propIter, nbytes, MemoryUse::NativeIterator); if (numGuards > 0) { // Construct guards into the guard array. Also recompute the guard key, // which incorporates Shape* and ObjectGroup* addresses that could have // changed during a GC triggered in (among other places) |IdToString| // above. JSObject* pobj = objBeingIterated; #ifdef DEBUG uint32_t i = 0; #endif uint32_t key = 0; do { ReceiverGuard guard(pobj); new (guardsEnd_) HeapReceiverGuard(guard); guardsEnd_++; #ifdef DEBUG i++; #endif key = mozilla::AddToHash(key, guard.hash()); // The one caller of this method that passes |numGuards > 0|, does // so only if the entire chain consists of cacheable objects (that // necessarily have static prototypes). pobj = pobj->staticPrototype(); } while (pobj); guardKey_ = key; MOZ_ASSERT(i == numGuards); } MOZ_ASSERT(static_cast(guardsEnd_) == propertyCursor_); for (size_t i = 0, len = props.length(); i < len; i++) { JSLinearString* str = IdToString(cx, props[i]); if (!str) { *hadError = true; return; } new (propertiesEnd_) GCPtrLinearString(str); propertiesEnd_++; } markInitialized(); MOZ_ASSERT(!*hadError); } inline size_t NativeIterator::allocationSize() const { size_t numGuards = guardsEnd() - guardsBegin(); return AllocationSize(initialPropertyCount(), numGuards); } /* static */ bool IteratorHashPolicy::match(PropertyIteratorObject* obj, const Lookup& lookup) { NativeIterator* ni = obj->getNativeIterator(); if (ni->guardKey() != lookup.key || ni->guardCount() != lookup.numGuards) { return false; } return ArrayEqual(reinterpret_cast(ni->guardsBegin()), lookup.guards, ni->guardCount()); } static inline bool CanCompareIterableObjectToCache(JSObject* obj) { if (obj->isNative()) { return obj->as().getDenseInitializedLength() == 0; } return false; } using ReceiverGuardVector = Vector; static MOZ_ALWAYS_INLINE PropertyIteratorObject* LookupInIteratorCache( JSContext* cx, JSObject* obj, uint32_t* numGuards) { MOZ_ASSERT(*numGuards == 0); ReceiverGuardVector guards(cx); uint32_t key = 0; JSObject* pobj = obj; do { if (!CanCompareIterableObjectToCache(pobj)) { return nullptr; } ReceiverGuard guard(pobj); key = mozilla::AddToHash(key, guard.hash()); if (MOZ_UNLIKELY(!guards.append(guard))) { cx->recoverFromOutOfMemory(); return nullptr; } pobj = pobj->staticPrototype(); } while (pobj); MOZ_ASSERT(!guards.empty()); *numGuards = guards.length(); IteratorHashPolicy::Lookup lookup(guards.begin(), guards.length(), key); auto p = ObjectRealm::get(obj).iteratorCache.lookup(lookup); if (!p) { return nullptr; } PropertyIteratorObject* iterobj = *p; MOZ_ASSERT(iterobj->compartment() == cx->compartment()); NativeIterator* ni = iterobj->getNativeIterator(); if (!ni->isReusable()) { return nullptr; } return iterobj; } static bool CanStoreInIteratorCache(JSObject* obj) { do { MOZ_ASSERT(obj->isNative()); MOZ_ASSERT(obj->as().getDenseInitializedLength() == 0); // Typed arrays have indexed properties not captured by the Shape guard. // Enumerate hooks may add extra properties. const JSClass* clasp = obj->getClass(); if (MOZ_UNLIKELY(IsTypedArrayClass(clasp))) { return false; } if (MOZ_UNLIKELY(clasp->getNewEnumerate() || clasp->getEnumerate())) { return false; } obj = obj->staticPrototype(); } while (obj); return true; } static MOZ_MUST_USE bool StoreInIteratorCache(JSContext* cx, JSObject* obj, PropertyIteratorObject* iterobj) { MOZ_ASSERT(CanStoreInIteratorCache(obj)); NativeIterator* ni = iterobj->getNativeIterator(); MOZ_ASSERT(ni->guardCount() > 0); IteratorHashPolicy::Lookup lookup( reinterpret_cast(ni->guardsBegin()), ni->guardCount(), ni->guardKey()); ObjectRealm::IteratorCache& cache = ObjectRealm::get(obj).iteratorCache; bool ok; auto p = cache.lookupForAdd(lookup); if (MOZ_LIKELY(!p)) { ok = cache.add(p, iterobj); } else { // If we weren't able to use an existing cached iterator, just // replace it. cache.remove(p); ok = cache.relookupOrAdd(p, lookup, iterobj); } if (!ok) { ReportOutOfMemory(cx); return false; } return true; } bool js::EnumerateProperties(JSContext* cx, HandleObject obj, MutableHandleIdVector props) { MOZ_ASSERT(props.empty()); if (MOZ_UNLIKELY(obj->is())) { return Proxy::enumerate(cx, obj, props); } return Snapshot(cx, obj, 0, props); } #ifdef DEBUG static bool PrototypeMayHaveIndexedProperties(NativeObject* nobj) { JSObject* proto = nobj->staticPrototype(); if (!proto) { return false; } if (proto->is() && proto->as().getDenseInitializedLength() > 0) { return true; } return ObjectMayHaveExtraIndexedProperties(proto); } #endif static JSObject* GetIterator(JSContext* cx, HandleObject obj) { MOZ_ASSERT(!obj->is()); MOZ_ASSERT(cx->compartment() == obj->compartment(), "We may end up allocating shapes in the wrong zone!"); uint32_t numGuards = 0; if (PropertyIteratorObject* iterobj = LookupInIteratorCache(cx, obj, &numGuards)) { NativeIterator* ni = iterobj->getNativeIterator(); ni->changeObjectBeingIterated(*obj); RegisterEnumerator(ObjectRealm::get(obj), ni); return iterobj; } if (numGuards > 0 && !CanStoreInIteratorCache(obj)) { numGuards = 0; } RootedIdVector keys(cx); if (!EnumerateProperties(cx, obj, &keys)) { return nullptr; } // If the object has dense elements, mark the dense elements as // maybe-in-iteration. // // The iterator is a snapshot so if indexed properties are added after this // point we don't need to do anything. However, the object might have sparse // elements now that can be densified later. To account for this, we set the // maybe-in-iteration flag also in NativeObject::maybeDensifySparseElements. // // In debug builds, AssertDenseElementsNotIterated is used to check the flag // is set correctly. if (obj->is() && obj->as().getDenseInitializedLength() > 0) { obj->as().markDenseElementsMaybeInIteration(); } PropertyIteratorObject* iterobj = CreatePropertyIterator(cx, obj, keys, numGuards, 0); if (!iterobj) { return nullptr; } cx->check(iterobj); #ifdef DEBUG if (obj->is()) { if (PrototypeMayHaveIndexedProperties(&obj->as())) { iterobj->getNativeIterator()->setMaybeHasIndexedPropertiesFromProto(); } } #endif // Cache the iterator object. if (numGuards > 0) { if (!StoreInIteratorCache(cx, obj, iterobj)) { return nullptr; } } return iterobj; } PropertyIteratorObject* js::LookupInIteratorCache(JSContext* cx, HandleObject obj) { uint32_t numGuards = 0; return LookupInIteratorCache(cx, obj, &numGuards); } // ES 2017 draft 7.4.7. PlainObject* js::CreateIterResultObject(JSContext* cx, HandleValue value, bool done) { // Step 1 (implicit). // Step 2. Rooted templateObject( cx, cx->realm()->getOrCreateIterResultTemplateObject(cx)); if (!templateObject) { return nullptr; } PlainObject* resultObj; JS_TRY_VAR_OR_RETURN_NULL( cx, resultObj, PlainObject::createWithTemplate(cx, templateObject)); // Step 3. resultObj->setSlot(Realm::IterResultObjectValueSlot, value); // Step 4. resultObj->setSlot(Realm::IterResultObjectDoneSlot, done ? TrueHandleValue : FalseHandleValue); // Step 5. return resultObj; } PlainObject* Realm::getOrCreateIterResultTemplateObject(JSContext* cx) { MOZ_ASSERT(cx->realm() == this); if (iterResultTemplate_) { return iterResultTemplate_; } PlainObject* templateObj = createIterResultTemplateObject(cx, WithObjectPrototype::Yes); iterResultTemplate_.set(templateObj); return iterResultTemplate_; } PlainObject* Realm::getOrCreateIterResultWithoutPrototypeTemplateObject( JSContext* cx) { MOZ_ASSERT(cx->realm() == this); if (iterResultWithoutPrototypeTemplate_) { return iterResultWithoutPrototypeTemplate_; } PlainObject* templateObj = createIterResultTemplateObject(cx, WithObjectPrototype::No); iterResultWithoutPrototypeTemplate_.set(templateObj); return iterResultWithoutPrototypeTemplate_; } PlainObject* Realm::createIterResultTemplateObject( JSContext* cx, WithObjectPrototype withProto) { // Create template plain object Rooted templateObject( cx, withProto == WithObjectPrototype::Yes ? NewTenuredBuiltinClassInstance(cx) : NewObjectWithGivenProto(cx, nullptr)); if (!templateObject) { return nullptr; } // Set dummy `value` property if (!NativeDefineDataProperty(cx, templateObject, cx->names().value, UndefinedHandleValue, JSPROP_ENUMERATE)) { return nullptr; } // Set dummy `done` property if (!NativeDefineDataProperty(cx, templateObject, cx->names().done, TrueHandleValue, JSPROP_ENUMERATE)) { return nullptr; } // Make sure that the properties are in the right slots. DebugOnly shape = templateObject->lastProperty(); MOZ_ASSERT(shape->previous()->slot() == Realm::IterResultObjectValueSlot && shape->previous()->propidRef() == NameToId(cx->names().value)); MOZ_ASSERT(shape->slot() == Realm::IterResultObjectDoneSlot && shape->propidRef() == NameToId(cx->names().done)); return templateObject; } /*** Iterator objects *******************************************************/ size_t PropertyIteratorObject::sizeOfMisc( mozilla::MallocSizeOf mallocSizeOf) const { return mallocSizeOf(getPrivate()); } void PropertyIteratorObject::trace(JSTracer* trc, JSObject* obj) { if (NativeIterator* ni = obj->as().getNativeIterator()) { ni->trace(trc); } } void PropertyIteratorObject::finalize(JSFreeOp* fop, JSObject* obj) { if (NativeIterator* ni = obj->as().getNativeIterator()) { fop->free_(obj, ni, ni->allocationSize(), MemoryUse::NativeIterator); } } const JSClassOps PropertyIteratorObject::classOps_ = { nullptr, // addProperty nullptr, // delProperty nullptr, // enumerate nullptr, // newEnumerate nullptr, // resolve nullptr, // mayResolve finalize, // finalize nullptr, // call nullptr, // hasInstance nullptr, // construct trace, // trace }; const JSClass PropertyIteratorObject::class_ = { "Iterator", JSCLASS_HAS_PRIVATE | JSCLASS_BACKGROUND_FINALIZE, &PropertyIteratorObject::classOps_}; static const JSClass ArrayIteratorPrototypeClass = {"Array Iterator", 0}; enum { ArrayIteratorSlotIteratedObject, ArrayIteratorSlotNextIndex, ArrayIteratorSlotItemKind, ArrayIteratorSlotCount }; const JSClass ArrayIteratorObject::class_ = { "Array Iterator", JSCLASS_HAS_RESERVED_SLOTS(ArrayIteratorSlotCount)}; ArrayIteratorObject* js::NewArrayIteratorTemplate(JSContext* cx) { RootedObject proto( cx, GlobalObject::getOrCreateArrayIteratorPrototype(cx, cx->global())); if (!proto) { return nullptr; } return NewTenuredObjectWithGivenProto(cx, proto); } ArrayIteratorObject* js::NewArrayIterator(JSContext* cx) { RootedObject proto( cx, GlobalObject::getOrCreateArrayIteratorPrototype(cx, cx->global())); if (!proto) { return nullptr; } return NewObjectWithGivenProto(cx, proto); } static const JSFunctionSpec array_iterator_methods[] = { JS_SELF_HOSTED_FN("next", "ArrayIteratorNext", 0, 0), JS_FS_END}; static const JSClass StringIteratorPrototypeClass = {"String Iterator", 0}; enum { StringIteratorSlotIteratedObject, StringIteratorSlotNextIndex, StringIteratorSlotCount }; const JSClass StringIteratorObject::class_ = { "String Iterator", JSCLASS_HAS_RESERVED_SLOTS(StringIteratorSlotCount)}; static const JSFunctionSpec string_iterator_methods[] = { JS_SELF_HOSTED_FN("next", "StringIteratorNext", 0, 0), JS_FS_END}; StringIteratorObject* js::NewStringIteratorTemplate(JSContext* cx) { RootedObject proto( cx, GlobalObject::getOrCreateStringIteratorPrototype(cx, cx->global())); if (!proto) { return nullptr; } return NewTenuredObjectWithGivenProto(cx, proto); } StringIteratorObject* js::NewStringIterator(JSContext* cx) { RootedObject proto( cx, GlobalObject::getOrCreateStringIteratorPrototype(cx, cx->global())); if (!proto) { return nullptr; } return NewObjectWithGivenProto(cx, proto); } static const JSClass RegExpStringIteratorPrototypeClass = { "RegExp String Iterator", 0}; enum { // The regular expression used for iteration. May hold the original RegExp // object when it is reused instead of a new RegExp object. RegExpStringIteratorSlotRegExp, // The String value being iterated upon. RegExpStringIteratorSlotString, // The source string of the original RegExp object. Used to validate we can // reuse the original RegExp object for matching. RegExpStringIteratorSlotSource, // The flags of the original RegExp object. RegExpStringIteratorSlotFlags, // When non-negative, this slot holds the current lastIndex position when // reusing the original RegExp object for matching. When set to |-1|, the // iterator has finished. When set to any other negative value, the // iterator is not yet exhausted and we're not on the fast path and we're // not reusing the input RegExp object. RegExpStringIteratorSlotLastIndex, RegExpStringIteratorSlotCount }; static_assert(RegExpStringIteratorSlotRegExp == REGEXP_STRING_ITERATOR_REGEXP_SLOT, "RegExpStringIteratorSlotRegExp must match self-hosting define " "for regexp slot."); static_assert(RegExpStringIteratorSlotString == REGEXP_STRING_ITERATOR_STRING_SLOT, "RegExpStringIteratorSlotString must match self-hosting define " "for string slot."); static_assert(RegExpStringIteratorSlotSource == REGEXP_STRING_ITERATOR_SOURCE_SLOT, "RegExpStringIteratorSlotString must match self-hosting define " "for source slot."); static_assert(RegExpStringIteratorSlotFlags == REGEXP_STRING_ITERATOR_FLAGS_SLOT, "RegExpStringIteratorSlotFlags must match self-hosting define " "for flags slot."); static_assert(RegExpStringIteratorSlotLastIndex == REGEXP_STRING_ITERATOR_LASTINDEX_SLOT, "RegExpStringIteratorSlotLastIndex must match self-hosting " "define for lastIndex slot."); const JSClass RegExpStringIteratorObject::class_ = { "RegExp String Iterator", JSCLASS_HAS_RESERVED_SLOTS(RegExpStringIteratorSlotCount)}; static const JSFunctionSpec regexp_string_iterator_methods[] = { JS_SELF_HOSTED_FN("next", "RegExpStringIteratorNext", 0, 0), JS_FS_END}; RegExpStringIteratorObject* js::NewRegExpStringIteratorTemplate(JSContext* cx) { RootedObject proto(cx, GlobalObject::getOrCreateRegExpStringIteratorPrototype( cx, cx->global())); if (!proto) { return nullptr; } return NewTenuredObjectWithGivenProto(cx, proto); } RegExpStringIteratorObject* js::NewRegExpStringIterator(JSContext* cx) { RootedObject proto(cx, GlobalObject::getOrCreateRegExpStringIteratorPrototype( cx, cx->global())); if (!proto) { return nullptr; } return NewObjectWithGivenProto(cx, proto); } JSObject* js::ValueToIterator(JSContext* cx, HandleValue vp) { RootedObject obj(cx); if (vp.isObject()) { /* Common case. */ obj = &vp.toObject(); } else if (vp.isNullOrUndefined()) { /* * Enumerating over null and undefined gives an empty enumerator, so * that |for (var p in ) ;| never executes * , per ES5 12.6.4. */ RootedIdVector props(cx); // Empty return CreatePropertyIterator(cx, nullptr, props, 0, 0); } else { obj = ToObject(cx, vp); if (!obj) { return nullptr; } } return GetIterator(cx, obj); } void js::CloseIterator(JSObject* obj) { if (obj->is()) { /* Remove enumerators from the active list, which is a stack. */ NativeIterator* ni = obj->as().getNativeIterator(); ni->unlink(); MOZ_ASSERT(ni->isActive()); ni->markInactive(); // Reset the enumerator; it may still be in the cached iterators for // this thread and can be reused. ni->resetPropertyCursorForReuse(); } } bool js::IteratorCloseForException(JSContext* cx, HandleObject obj) { MOZ_ASSERT(cx->isExceptionPending()); bool isClosingGenerator = cx->isClosingGenerator(); JS::AutoSaveExceptionState savedExc(cx); // Implements IteratorClose (ES 7.4.6) for exception unwinding. See // also the bytecode generated by BytecodeEmitter::emitIteratorClose. // Step 3. // // Get the "return" method. RootedValue returnMethod(cx); if (!GetProperty(cx, obj, obj, cx->names().return_, &returnMethod)) { return false; } // Step 4. // // Do nothing if "return" is null or undefined. Throw a TypeError if the // method is not IsCallable. if (returnMethod.isNullOrUndefined()) { return true; } if (!IsCallable(returnMethod)) { return ReportIsNotFunction(cx, returnMethod); } // Step 5, 6, 8. // // Call "return" if it is not null or undefined. RootedValue rval(cx); bool ok = Call(cx, returnMethod, obj, &rval); if (isClosingGenerator) { // Closing an iterator is implemented as an exception, but in spec // terms it is a Completion value with [[Type]] return. In this case // we *do* care if the call threw and if it returned an object. if (!ok) { return false; } if (!rval.isObject()) { return ThrowCheckIsObject(cx, CheckIsObjectKind::IteratorReturn); } } else { // We don't care if the call threw or that it returned an Object, as // Step 6 says if IteratorClose is being called during a throw, the // original throw has primacy. savedExc.restore(); } return true; } void js::UnwindIteratorForUncatchableException(JSObject* obj) { if (obj->is()) { NativeIterator* ni = obj->as().getNativeIterator(); ni->unlink(); } } static bool SuppressDeletedProperty(JSContext* cx, NativeIterator* ni, HandleObject obj, Handle str) { if (ni->objectBeingIterated() != obj) { return true; } // Optimization for the following common case: // // for (var p in o) { // delete o[p]; // } // // Note that usually both strings will be atoms so we only check for pointer // equality here. if (ni->previousPropertyWas(str)) { return true; } while (true) { bool restart = false; // Check whether id is still to come. GCPtrLinearString* const cursor = ni->nextProperty(); GCPtrLinearString* const end = ni->propertiesEnd(); for (GCPtrLinearString* idp = cursor; idp < end; ++idp) { // Common case: both strings are atoms. if ((*idp)->isAtom() && str->isAtom()) { if (*idp != str) { continue; } } else { if (!EqualStrings(*idp, str)) { continue; } } // Check whether another property along the prototype chain became // visible as a result of this deletion. RootedObject proto(cx); if (!GetPrototype(cx, obj, &proto)) { return false; } if (proto) { RootedId id(cx); RootedValue idv(cx, StringValue(*idp)); if (!PrimitiveValueToId(cx, idv, &id)) { return false; } Rooted desc(cx); if (!GetPropertyDescriptor(cx, proto, id, &desc)) { return false; } if (desc.object() && desc.enumerable()) { continue; } } // If GetPropertyDescriptor above removed a property from ni, start // over. if (end != ni->propertiesEnd() || cursor != ni->nextProperty()) { restart = true; break; } // No property along the prototype chain stepped in to take the // property's place, so go ahead and delete id from the list. // If it is the next property to be enumerated, just skip it. if (idp == cursor) { ni->incCursor(); } else { for (GCPtrLinearString* p = idp; p + 1 != end; p++) { *p = *(p + 1); } ni->trimLastProperty(); } ni->markHasUnvisitedPropertyDeletion(); return true; } if (!restart) { return true; } } } /* * Suppress enumeration of deleted properties. This function must be called * when a property is deleted and there might be active enumerators. * * We maintain a list of active non-escaping for-in enumerators. To suppress * a property, we check whether each active enumerator contains the (obj, id) * pair and has not yet enumerated |id|. If so, and |id| is the next property, * we simply advance the cursor. Otherwise, we delete |id| from the list. * * We do not suppress enumeration of a property deleted along an object's * prototype chain. Only direct deletions on the object are handled. */ static bool SuppressDeletedPropertyHelper(JSContext* cx, HandleObject obj, Handle str) { NativeIterator* enumeratorList = ObjectRealm::get(obj).enumerators; NativeIterator* ni = enumeratorList->next(); while (ni != enumeratorList) { if (!SuppressDeletedProperty(cx, ni, obj, str)) { return false; } ni = ni->next(); } return true; } bool js::SuppressDeletedProperty(JSContext* cx, HandleObject obj, jsid id) { if (MOZ_LIKELY(!ObjectRealm::get(obj).objectMaybeInIteration(obj))) { return true; } if (JSID_IS_SYMBOL(id)) { return true; } Rooted str(cx, IdToString(cx, id)); if (!str) { return false; } return SuppressDeletedPropertyHelper(cx, obj, str); } bool js::SuppressDeletedElement(JSContext* cx, HandleObject obj, uint32_t index) { if (MOZ_LIKELY(!ObjectRealm::get(obj).objectMaybeInIteration(obj))) { return true; } RootedId id(cx); if (!IndexToId(cx, index, &id)) { return false; } Rooted str(cx, IdToString(cx, id)); if (!str) { return false; } return SuppressDeletedPropertyHelper(cx, obj, str); } #ifdef DEBUG void js::AssertDenseElementsNotIterated(NativeObject* obj) { // Search for active iterators for |obj| and assert they don't contain any // property keys that are dense elements. This is used to check correctness // of the MAYBE_IN_ITERATION flag on ObjectElements. // // Ignore iterators that may contain indexed properties from objects on the // prototype chain, as that can result in false positives. See bug 1656744. // Limit the number of properties we check to avoid slowing down debug builds // too much. static constexpr uint32_t MaxPropsToCheck = 10; uint32_t propsChecked = 0; NativeIterator* enumeratorList = ObjectRealm::get(obj).enumerators; NativeIterator* ni = enumeratorList->next(); while (ni != enumeratorList) { if (ni->objectBeingIterated() == obj && !ni->maybeHasIndexedPropertiesFromProto()) { for (GCPtrLinearString* idp = ni->nextProperty(); idp < ni->propertiesEnd(); ++idp) { uint32_t index; if (idp->get()->isIndex(&index)) { MOZ_ASSERT(!obj->containsDenseElement(index)); } if (++propsChecked > MaxPropsToCheck) { return; } } } ni = ni->next(); } } #endif static const JSFunctionSpec iterator_methods[] = { JS_SELF_HOSTED_SYM_FN(iterator, "IteratorIdentity", 0, 0), JS_FS_END}; static const JSFunctionSpec iterator_static_methods[] = { JS_SELF_HOSTED_FN("from", "IteratorFrom", 1, 0), JS_FS_END}; // These methods are only attached to Iterator.prototype when the // Iterator Helpers feature is enabled. static const JSFunctionSpec iterator_methods_with_helpers[] = { JS_SELF_HOSTED_FN("map", "IteratorMap", 1, 0), JS_SELF_HOSTED_FN("filter", "IteratorFilter", 1, 0), JS_SELF_HOSTED_FN("take", "IteratorTake", 1, 0), JS_SELF_HOSTED_FN("drop", "IteratorDrop", 1, 0), JS_SELF_HOSTED_FN("asIndexedPairs", "IteratorAsIndexedPairs", 0, 0), JS_SELF_HOSTED_FN("flatMap", "IteratorFlatMap", 1, 0), JS_SELF_HOSTED_FN("reduce", "IteratorReduce", 1, 0), JS_SELF_HOSTED_FN("toArray", "IteratorToArray", 0, 0), JS_SELF_HOSTED_FN("forEach", "IteratorForEach", 1, 0), JS_SELF_HOSTED_FN("some", "IteratorSome", 1, 0), JS_SELF_HOSTED_FN("every", "IteratorEvery", 1, 0), JS_SELF_HOSTED_FN("find", "IteratorFind", 1, 0), JS_SELF_HOSTED_SYM_FN(iterator, "IteratorIdentity", 0, 0), JS_FS_END}; /* static */ bool GlobalObject::initIteratorProto(JSContext* cx, Handle global) { if (global->getReservedSlot(ITERATOR_PROTO).isObject()) { return true; } RootedObject proto( cx, GlobalObject::createBlankPrototype(cx, global)); if (!proto) { return false; } // %IteratorPrototype%.map.[[Prototype]] is %Generator% and // %Generator%.prototype.[[Prototype]] is %IteratorPrototype%. // Populate the slot early, to prevent runaway mutual recursion. global->setReservedSlot(ITERATOR_PROTO, ObjectValue(*proto)); if (!DefinePropertiesAndFunctions(cx, proto, nullptr, iterator_methods)) { // In this case, we leave a partially initialized object in the // slot. There's no obvious way to do better, since this object may already // be in the prototype chain of %GeneratorPrototype%. return false; } return true; } /* static */ template bool GlobalObject::initObjectIteratorProto(JSContext* cx, Handle global, HandleAtom tag) { if (global->getReservedSlot(Slot).isObject()) { return true; } RootedObject iteratorProto( cx, GlobalObject::getOrCreateIteratorPrototype(cx, global)); if (!iteratorProto) { return false; } RootedObject proto(cx, GlobalObject::createBlankPrototypeInheriting( cx, ProtoClass, iteratorProto)); if (!proto || !DefinePropertiesAndFunctions(cx, proto, nullptr, Methods) || (tag && !DefineToStringTag(cx, proto, tag))) { return false; } global->setReservedSlot(Slot, ObjectValue(*proto)); return true; } /* static */ NativeObject* GlobalObject::getOrCreateArrayIteratorPrototype( JSContext* cx, Handle global) { return MaybeNativeObject(getOrCreateObject( cx, global, ARRAY_ITERATOR_PROTO, cx->names().ArrayIterator.toHandle(), initObjectIteratorProto)); } /* static */ JSObject* GlobalObject::getOrCreateStringIteratorPrototype( JSContext* cx, Handle global) { return getOrCreateObject( cx, global, STRING_ITERATOR_PROTO, cx->names().StringIterator.toHandle(), initObjectIteratorProto); } /* static */ JSObject* GlobalObject::getOrCreateRegExpStringIteratorPrototype( JSContext* cx, Handle global) { return getOrCreateObject( cx, global, REGEXP_STRING_ITERATOR_PROTO, cx->names().RegExpStringIterator.toHandle(), initObjectIteratorProto); } // Iterator Helper Proposal 2.1.3.1 Iterator() // https://tc39.es/proposal-iterator-helpers/#sec-iterator as of revision // ed6e15a static bool IteratorConstructor(JSContext* cx, unsigned argc, Value* vp) { CallArgs args = CallArgsFromVp(argc, vp); // Step 1. if (!ThrowIfNotConstructing(cx, args, js_Iterator_str)) { return false; } // Throw TypeError if NewTarget is the active function object, preventing the // Iterator constructor from being used directly. if (args.callee() == args.newTarget().toObject()) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_BOGUS_CONSTRUCTOR, js_Iterator_str); return false; } // Step 2. RootedObject proto(cx); if (!GetPrototypeFromBuiltinConstructor(cx, args, JSProto_Iterator, &proto)) { return false; } JSObject* obj = NewObjectWithClassProto(cx, proto); if (!obj) { return false; } args.rval().setObject(*obj); return true; } static const ClassSpec IteratorObjectClassSpec = { GenericCreateConstructor, GenericCreatePrototype, iterator_static_methods, nullptr, iterator_methods_with_helpers, nullptr, nullptr, }; const JSClass IteratorObject::class_ = { js_Iterator_str, JSCLASS_HAS_CACHED_PROTO(JSProto_Iterator), JS_NULL_CLASS_OPS, &IteratorObjectClassSpec, }; const JSClass IteratorObject::protoClass_ = { "Iterator.prototype", JSCLASS_HAS_CACHED_PROTO(JSProto_Iterator), JS_NULL_CLASS_OPS, &IteratorObjectClassSpec, }; // Set up WrapForValidIteratorObject class and its prototype. static const JSFunctionSpec wrap_for_valid_iterator_methods[] = { JS_SELF_HOSTED_FN("next", "WrapForValidIteratorNext", 1, 0), JS_SELF_HOSTED_FN("return", "WrapForValidIteratorReturn", 1, 0), JS_SELF_HOSTED_FN("throw", "WrapForValidIteratorThrow", 1, 0), JS_FS_END, }; static const JSClass WrapForValidIteratorPrototypeClass = { "Wrap For Valid Iterator", 0}; const JSClass WrapForValidIteratorObject::class_ = { "Wrap For Valid Iterator", JSCLASS_HAS_RESERVED_SLOTS(WrapForValidIteratorObject::SlotCount), }; /* static */ NativeObject* GlobalObject::getOrCreateWrapForValidIteratorPrototype( JSContext* cx, Handle global) { return MaybeNativeObject(getOrCreateObject( cx, global, WRAP_FOR_VALID_ITERATOR_PROTO, HandleAtom(nullptr), initObjectIteratorProto)); } WrapForValidIteratorObject* js::NewWrapForValidIterator(JSContext* cx) { RootedObject proto(cx, GlobalObject::getOrCreateWrapForValidIteratorPrototype( cx, cx->global())); if (!proto) { return nullptr; } return NewObjectWithGivenProto(cx, proto); } // Common iterator object returned by Iterator Helper methods. static const JSFunctionSpec iterator_helper_methods[] = { JS_SELF_HOSTED_FN("next", "IteratorHelperNext", 1, 0), JS_SELF_HOSTED_FN("return", "IteratorHelperReturn", 1, 0), JS_SELF_HOSTED_FN("throw", "IteratorHelperThrow", 1, 0), JS_FS_END}; static const JSClass IteratorHelperPrototypeClass = {"Iterator Helper", 0}; const JSClass IteratorHelperObject::class_ = { "Iterator Helper", JSCLASS_HAS_RESERVED_SLOTS(IteratorHelperObject::SlotCount), }; /* static */ NativeObject* GlobalObject::getOrCreateIteratorHelperPrototype( JSContext* cx, Handle global) { return MaybeNativeObject( getOrCreateObject(cx, global, ITERATOR_HELPER_PROTO, HandleAtom(nullptr), initObjectIteratorProto)); } IteratorHelperObject* js::NewIteratorHelper(JSContext* cx) { RootedObject proto( cx, GlobalObject::getOrCreateIteratorHelperPrototype(cx, cx->global())); if (!proto) { return nullptr; } return NewObjectWithGivenProto(cx, proto); }