/* -*- 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/. */ #include "builtin/MapObject.h" #include "jsapi.h" #include "ds/OrderedHashTable.h" #include "gc/GCContext.h" #include "jit/InlinableNatives.h" #include "js/MapAndSet.h" #include "js/PropertyAndElement.h" // JS_DefineFunctions #include "js/PropertySpec.h" #include "js/Utility.h" #include "vm/BigIntType.h" #include "vm/EqualityOperations.h" // js::SameValue #include "vm/GlobalObject.h" #include "vm/Interpreter.h" #include "vm/JSContext.h" #include "vm/JSObject.h" #include "vm/SelfHosting.h" #include "vm/SymbolType.h" #ifdef ENABLE_RECORD_TUPLE # include "vm/RecordType.h" # include "vm/TupleType.h" #endif #include "gc/GCContext-inl.h" #include "gc/Marking-inl.h" #include "vm/GeckoProfiler-inl.h" #include "vm/NativeObject-inl.h" using namespace js; using mozilla::NumberEqualsInt32; /*** HashableValue **********************************************************/ static PreBarriered NormalizeDoubleValue(double d) { int32_t i; if (NumberEqualsInt32(d, &i)) { // Normalize int32_t-valued doubles to int32_t for faster hashing and // testing. Note: we use NumberEqualsInt32 here instead of NumberIsInt32 // because we want -0 and 0 to be normalized to the same thing. return Int32Value(i); } // Normalize the sign bit of a NaN. return JS::CanonicalizedDoubleValue(d); } bool HashableValue::setValue(JSContext* cx, HandleValue v) { if (v.isString()) { // Atomize so that hash() and operator==() are fast and infallible. JSString* str = AtomizeString(cx, v.toString()); if (!str) { return false; } value = StringValue(str); } else if (v.isDouble()) { value = NormalizeDoubleValue(v.toDouble()); #ifdef ENABLE_RECORD_TUPLE } else if (v.isExtendedPrimitive()) { JSObject& obj = v.toExtendedPrimitive(); if (obj.is()) { if (!obj.as().ensureAtomized(cx)) { return false; } } else { MOZ_ASSERT(obj.is()); if (!obj.as().ensureAtomized(cx)) { return false; } } value = v; #endif } else { value = v; } MOZ_ASSERT(value.isUndefined() || value.isNull() || value.isBoolean() || value.isNumber() || value.isString() || value.isSymbol() || value.isObject() || value.isBigInt() || IF_RECORD_TUPLE(value.isExtendedPrimitive(), false)); return true; } static HashNumber HashValue(const Value& v, const mozilla::HashCodeScrambler& hcs) { // HashableValue::setValue normalizes values so that the SameValue relation // on HashableValues is the same as the == relationship on // value.asRawBits(). So why not just return that? Security. // // To avoid revealing GC of atoms, string-based hash codes are computed // from the string contents rather than any pointer; to avoid revealing // addresses, pointer-based hash codes are computed using the // HashCodeScrambler. if (v.isString()) { return v.toString()->asAtom().hash(); } if (v.isSymbol()) { return v.toSymbol()->hash(); } if (v.isBigInt()) { return MaybeForwarded(v.toBigInt())->hash(); } #ifdef ENABLE_RECORD_TUPLE if (v.isExtendedPrimitive()) { JSObject* obj = MaybeForwarded(&v.toExtendedPrimitive()); auto hasher = [&hcs](const Value& v) { return HashValue( v.isDouble() ? NormalizeDoubleValue(v.toDouble()).get() : v, hcs); }; if (obj->is()) { return obj->as().hash(hasher); } MOZ_ASSERT(obj->is()); return obj->as().hash(hasher); } #endif if (v.isObject()) { return hcs.scramble(v.asRawBits()); } MOZ_ASSERT(!v.isGCThing(), "do not reveal pointers via hash codes"); return mozilla::HashGeneric(v.asRawBits()); } HashNumber HashableValue::hash(const mozilla::HashCodeScrambler& hcs) const { return HashValue(value, hcs); } #ifdef ENABLE_RECORD_TUPLE inline bool SameExtendedPrimitiveType(const PreBarriered& a, const PreBarriered& b) { return a.toExtendedPrimitive().getClass() == b.toExtendedPrimitive().getClass(); } #endif bool HashableValue::equals(const HashableValue& other) const { // Two HashableValues are equal if they have equal bits. bool b = (value.asRawBits() == other.value.asRawBits()); if (!b && (value.type() == other.value.type())) { if (value.isBigInt()) { // BigInt values are considered equal if they represent the same // mathematical value. b = BigInt::equal(value.toBigInt(), other.value.toBigInt()); } #ifdef ENABLE_RECORD_TUPLE else if (value.isExtendedPrimitive() && SameExtendedPrimitiveType(value, other.value)) { b = js::SameValueZeroLinear(value, other.value); } #endif } #ifdef DEBUG bool same; JSContext* cx = TlsContext.get(); RootedValue valueRoot(cx, value); RootedValue otherRoot(cx, other.value); MOZ_ASSERT(SameValueZero(cx, valueRoot, otherRoot, &same)); MOZ_ASSERT(same == b); #endif return b; } /*** MapIterator ************************************************************/ namespace {} /* anonymous namespace */ static const JSClassOps MapIteratorObjectClassOps = { nullptr, // addProperty nullptr, // delProperty nullptr, // enumerate nullptr, // newEnumerate nullptr, // resolve nullptr, // mayResolve MapIteratorObject::finalize, // finalize nullptr, // call nullptr, // construct nullptr, // trace }; static const ClassExtension MapIteratorObjectClassExtension = { MapIteratorObject::objectMoved, // objectMovedOp }; const JSClass MapIteratorObject::class_ = { "Map Iterator", JSCLASS_HAS_RESERVED_SLOTS(MapIteratorObject::SlotCount) | JSCLASS_FOREGROUND_FINALIZE | JSCLASS_SKIP_NURSERY_FINALIZE, &MapIteratorObjectClassOps, JS_NULL_CLASS_SPEC, &MapIteratorObjectClassExtension}; const JSFunctionSpec MapIteratorObject::methods[] = { JS_SELF_HOSTED_FN("next", "MapIteratorNext", 0, 0), JS_FS_END}; static inline ValueMap::Range* MapIteratorObjectRange(NativeObject* obj) { MOZ_ASSERT(obj->is()); return obj->maybePtrFromReservedSlot( MapIteratorObject::RangeSlot); } inline MapObject::IteratorKind MapIteratorObject::kind() const { int32_t i = getReservedSlot(KindSlot).toInt32(); MOZ_ASSERT(i == MapObject::Keys || i == MapObject::Values || i == MapObject::Entries); return MapObject::IteratorKind(i); } /* static */ bool GlobalObject::initMapIteratorProto(JSContext* cx, Handle global) { Rooted base( cx, GlobalObject::getOrCreateIteratorPrototype(cx, global)); if (!base) { return false; } Rooted proto( cx, GlobalObject::createBlankPrototypeInheriting(cx, base)); if (!proto) { return false; } if (!JS_DefineFunctions(cx, proto, MapIteratorObject::methods) || !DefineToStringTag(cx, proto, cx->names().MapIterator)) { return false; } global->initBuiltinProto(ProtoKind::MapIteratorProto, proto); return true; } template static inline bool HasNurseryMemory(TableObject* t) { return t->getReservedSlot(TableObject::HasNurseryMemorySlot).toBoolean(); } template static inline void SetHasNurseryMemory(TableObject* t, bool b) { t->setReservedSlot(TableObject::HasNurseryMemorySlot, JS::BooleanValue(b)); } MapIteratorObject* MapIteratorObject::create(JSContext* cx, HandleObject obj, const ValueMap* data, MapObject::IteratorKind kind) { Handle mapobj(obj.as()); Rooted global(cx, &mapobj->global()); Rooted proto( cx, GlobalObject::getOrCreateMapIteratorPrototype(cx, global)); if (!proto) { return nullptr; } MapIteratorObject* iterobj = NewObjectWithGivenProto(cx, proto); if (!iterobj) { return nullptr; } iterobj->init(mapobj, kind); constexpr size_t BufferSize = RoundUp(sizeof(ValueMap::Range), gc::CellAlignBytes); Nursery& nursery = cx->nursery(); void* buffer = nursery.allocateBufferSameLocation(iterobj, BufferSize); if (!buffer) { // Retry with |iterobj| and |buffer| forcibly tenured. iterobj = NewTenuredObjectWithGivenProto(cx, proto); if (!iterobj) { return nullptr; } iterobj->init(mapobj, kind); buffer = nursery.allocateBufferSameLocation(iterobj, BufferSize); if (!buffer) { ReportOutOfMemory(cx); return nullptr; } } bool insideNursery = IsInsideNursery(iterobj); MOZ_ASSERT(insideNursery == nursery.isInside(buffer)); if (insideNursery && !HasNurseryMemory(mapobj.get())) { if (!cx->nursery().addMapWithNurseryMemory(mapobj)) { ReportOutOfMemory(cx); return nullptr; } SetHasNurseryMemory(mapobj.get(), true); } auto range = data->createRange(buffer, insideNursery); iterobj->setReservedSlot(RangeSlot, PrivateValue(range)); return iterobj; } void MapIteratorObject::finalize(JS::GCContext* gcx, JSObject* obj) { MOZ_ASSERT(gcx->onMainThread()); MOZ_ASSERT(!IsInsideNursery(obj)); auto range = MapIteratorObjectRange(&obj->as()); MOZ_ASSERT(!gcx->runtime()->gc.nursery().isInside(range)); // Bug 1560019: Malloc memory associated with MapIteratorObjects is not // currently tracked. gcx->deleteUntracked(range); } size_t MapIteratorObject::objectMoved(JSObject* obj, JSObject* old) { if (!IsInsideNursery(old)) { return 0; } MapIteratorObject* iter = &obj->as(); ValueMap::Range* range = MapIteratorObjectRange(iter); if (!range) { return 0; } Nursery& nursery = iter->runtimeFromMainThread()->gc.nursery(); if (!nursery.isInside(range)) { nursery.removeMallocedBufferDuringMinorGC(range); return 0; } AutoEnterOOMUnsafeRegion oomUnsafe; auto newRange = iter->zone()->new_(*range); if (!newRange) { oomUnsafe.crash( "MapIteratorObject failed to allocate Range data while tenuring."); } range->~Range(); iter->setReservedSlot(MapIteratorObject::RangeSlot, PrivateValue(newRange)); return sizeof(ValueMap::Range); } template static void DestroyRange(JSObject* iterator, Range* range) { range->~Range(); if (!IsInsideNursery(iterator)) { js_free(range); } } bool MapIteratorObject::next(MapIteratorObject* mapIterator, ArrayObject* resultPairObj) { // IC code calls this directly. AutoUnsafeCallWithABI unsafe; // Check invariants for inlined GetNextMapEntryForIterator. // The array should be tenured, so that post-barrier can be done simply. MOZ_ASSERT(resultPairObj->isTenured()); // The array elements should be fixed. MOZ_ASSERT(resultPairObj->hasFixedElements()); MOZ_ASSERT(resultPairObj->getDenseInitializedLength() == 2); MOZ_ASSERT(resultPairObj->getDenseCapacity() >= 2); ValueMap::Range* range = MapIteratorObjectRange(mapIterator); if (!range) { return true; } if (range->empty()) { DestroyRange(mapIterator, range); mapIterator->setReservedSlot(RangeSlot, PrivateValue(nullptr)); return true; } switch (mapIterator->kind()) { case MapObject::Keys: resultPairObj->setDenseElement(0, range->front().key.get()); break; case MapObject::Values: resultPairObj->setDenseElement(1, range->front().value); break; case MapObject::Entries: { resultPairObj->setDenseElement(0, range->front().key.get()); resultPairObj->setDenseElement(1, range->front().value); break; } } range->popFront(); return false; } /* static */ JSObject* MapIteratorObject::createResultPair(JSContext* cx) { Rooted resultPairObj( cx, NewDenseFullyAllocatedArray(cx, 2, TenuredObject)); if (!resultPairObj) { return nullptr; } resultPairObj->setDenseInitializedLength(2); resultPairObj->initDenseElement(0, NullValue()); resultPairObj->initDenseElement(1, NullValue()); return resultPairObj; } /*** Map ********************************************************************/ struct js::UnbarrieredHashPolicy { using Lookup = Value; static HashNumber hash(const Lookup& v, const mozilla::HashCodeScrambler& hcs) { return HashValue(v, hcs); } static bool match(const Value& k, const Lookup& l) { return k == l; } static bool isEmpty(const Value& v) { return v.isMagic(JS_HASH_KEY_EMPTY); } static void makeEmpty(Value* vp) { vp->setMagic(JS_HASH_KEY_EMPTY); } }; // ValueMap, MapObject::UnbarrieredTable and MapObject::PreBarrieredTable must // all have the same memory layout. static_assert(sizeof(ValueMap) == sizeof(MapObject::UnbarrieredTable)); static_assert(sizeof(ValueMap::Entry) == sizeof(MapObject::UnbarrieredTable::Entry)); static_assert(sizeof(ValueMap) == sizeof(MapObject::PreBarrieredTable)); static_assert(sizeof(ValueMap::Entry) == sizeof(MapObject::PreBarrieredTable::Entry)); const JSClassOps MapObject::classOps_ = { nullptr, // addProperty nullptr, // delProperty nullptr, // enumerate nullptr, // newEnumerate nullptr, // resolve nullptr, // mayResolve finalize, // finalize nullptr, // call nullptr, // construct trace, // trace }; const ClassSpec MapObject::classSpec_ = { GenericCreateConstructor, GenericCreatePrototype, nullptr, MapObject::staticProperties, MapObject::methods, MapObject::properties, MapObject::finishInit}; const JSClass MapObject::class_ = { "Map", JSCLASS_DELAY_METADATA_BUILDER | JSCLASS_HAS_RESERVED_SLOTS(MapObject::SlotCount) | JSCLASS_HAS_CACHED_PROTO(JSProto_Map) | JSCLASS_FOREGROUND_FINALIZE | JSCLASS_SKIP_NURSERY_FINALIZE, &MapObject::classOps_, &MapObject::classSpec_}; const JSClass MapObject::protoClass_ = { "Map.prototype", JSCLASS_HAS_CACHED_PROTO(JSProto_Map), JS_NULL_CLASS_OPS, &MapObject::classSpec_}; const JSPropertySpec MapObject::properties[] = { JS_PSG("size", size, 0), JS_STRING_SYM_PS(toStringTag, "Map", JSPROP_READONLY), JS_PS_END}; // clang-format off const JSFunctionSpec MapObject::methods[] = { JS_INLINABLE_FN("get", get, 1, 0, MapGet), JS_INLINABLE_FN("has", has, 1, 0, MapHas), JS_FN("set", set, 2, 0), JS_FN("delete", delete_, 1, 0), JS_FN("keys", keys, 0, 0), JS_FN("values", values, 0, 0), JS_FN("clear", clear, 0, 0), JS_SELF_HOSTED_FN("forEach", "MapForEach", 2, 0), JS_FN("entries", entries, 0, 0), // @@iterator is re-defined in finishInit so that it has the // same identity as |entries|. JS_SYM_FN(iterator, entries, 0, 0), JS_FS_END }; // clang-format on const JSPropertySpec MapObject::staticProperties[] = { JS_SELF_HOSTED_SYM_GET(species, "$MapSpecies", 0), JS_PS_END}; /* static */ bool MapObject::finishInit(JSContext* cx, HandleObject ctor, HandleObject proto) { Handle nativeProto = proto.as(); RootedValue entriesFn(cx); RootedId entriesId(cx, NameToId(cx->names().entries)); if (!NativeGetProperty(cx, nativeProto, entriesId, &entriesFn)) { return false; } // 23.1.3.12 Map.prototype[@@iterator]() // The initial value of the @@iterator property is the same function object // as the initial value of the "entries" property. RootedId iteratorId(cx, PropertyKey::Symbol(cx->wellKnownSymbols().iterator)); return NativeDefineDataProperty(cx, nativeProto, iteratorId, entriesFn, 0); } void MapObject::trace(JSTracer* trc, JSObject* obj) { if (ValueMap* map = obj->as().getTableUnchecked()) { map->trace(trc); } } using NurseryKeysVector = mozilla::Vector; template static NurseryKeysVector* GetNurseryKeys(TableObject* t) { Value value = t->getReservedSlot(TableObject::NurseryKeysSlot); return reinterpret_cast(value.toPrivate()); } template static NurseryKeysVector* AllocNurseryKeys(TableObject* t) { MOZ_ASSERT(!GetNurseryKeys(t)); auto keys = js_new(); if (!keys) { return nullptr; } t->setReservedSlot(TableObject::NurseryKeysSlot, PrivateValue(keys)); return keys; } template static void DeleteNurseryKeys(TableObject* t) { auto keys = GetNurseryKeys(t); MOZ_ASSERT(keys); js_delete(keys); t->setReservedSlot(TableObject::NurseryKeysSlot, PrivateValue(nullptr)); } // A generic store buffer entry that traces all nursery keys for an ordered hash // map or set. template class js::OrderedHashTableRef : public gc::BufferableRef { ObjectT* object; public: explicit OrderedHashTableRef(ObjectT* obj) : object(obj) {} void trace(JSTracer* trc) override { MOZ_ASSERT(!IsInsideNursery(object)); auto realTable = object->getTableUnchecked(); auto unbarrieredTable = reinterpret_cast(realTable); NurseryKeysVector* keys = GetNurseryKeys(object); MOZ_ASSERT(keys); for (Value key : *keys) { MOZ_ASSERT(unbarrieredTable->hash(key) == realTable->hash(*reinterpret_cast(&key))); // Note: we use a lambda to avoid tenuring keys that have been removed // from the Map or Set. unbarrieredTable->rekeyOneEntry(key, [trc](const Value& prior) { Value key = prior; TraceManuallyBarrieredEdge(trc, &key, "ordered hash table key"); return key; }); } DeleteNurseryKeys(object); } }; template [[nodiscard]] inline static bool PostWriteBarrierImpl(ObjectT* obj, const Value& keyValue) { if (MOZ_LIKELY(!keyValue.hasObjectPayload() && !keyValue.isBigInt())) { MOZ_ASSERT_IF(keyValue.isGCThing(), !IsInsideNursery(keyValue.toGCThing())); return true; } if (!IsInsideNursery(keyValue.toGCThing())) { return true; } NurseryKeysVector* keys = GetNurseryKeys(obj); if (!keys) { keys = AllocNurseryKeys(obj); if (!keys) { return false; } keyValue.toGCThing()->storeBuffer()->putGeneric( OrderedHashTableRef(obj)); } return keys->append(keyValue); } [[nodiscard]] inline static bool PostWriteBarrier(MapObject* map, const Value& key) { MOZ_ASSERT(!IsInsideNursery(map)); return PostWriteBarrierImpl(map, key); } [[nodiscard]] inline static bool PostWriteBarrier(SetObject* set, const Value& key) { if (IsInsideNursery(set)) { return true; } return PostWriteBarrierImpl(set, key); } bool MapObject::getKeysAndValuesInterleaved( HandleObject obj, JS::MutableHandle> entries) { const ValueMap* map = obj->as().getData(); if (!map) { return false; } for (ValueMap::Range r = map->all(); !r.empty(); r.popFront()) { if (!entries.append(r.front().key.get()) || !entries.append(r.front().value)) { return false; } } return true; } bool MapObject::set(JSContext* cx, HandleObject obj, HandleValue k, HandleValue v) { MapObject* mapObject = &obj->as(); Rooted key(cx); if (!key.setValue(cx, k)) { return false; } return setWithHashableKey(cx, mapObject, key, v); } /* static */ inline bool MapObject::setWithHashableKey(JSContext* cx, MapObject* obj, Handle key, Handle value) { ValueMap* table = obj->getTableUnchecked(); if (!table) { return false; } bool needsPostBarriers = obj->isTenured(); if (needsPostBarriers) { // Use the ValueMap representation which has post barriers. if (!PostWriteBarrier(obj, key.get()) || !table->put(key.get(), value)) { ReportOutOfMemory(cx); return false; } } else { // Use the PreBarrieredTable representation which does not. auto* preBarriedTable = reinterpret_cast(table); if (!preBarriedTable->put(key.get(), value.get())) { ReportOutOfMemory(cx); return false; } } return true; } MapObject* MapObject::create(JSContext* cx, HandleObject proto /* = nullptr */) { auto map = cx->make_unique(cx->zone(), cx->realm()->randomHashCodeScrambler()); if (!map) { return nullptr; } if (!map->init()) { ReportOutOfMemory(cx); return nullptr; } AutoSetNewObjectMetadata metadata(cx); MapObject* mapObj = NewObjectWithClassProto(cx, proto); if (!mapObj) { return nullptr; } bool insideNursery = IsInsideNursery(mapObj); if (insideNursery && !cx->nursery().addMapWithNurseryMemory(mapObj)) { ReportOutOfMemory(cx); return nullptr; } InitReservedSlot(mapObj, DataSlot, map.release(), MemoryUse::MapObjectTable); mapObj->initReservedSlot(NurseryKeysSlot, PrivateValue(nullptr)); mapObj->initReservedSlot(HasNurseryMemorySlot, JS::BooleanValue(insideNursery)); return mapObj; } size_t MapObject::sizeOfData(mozilla::MallocSizeOf mallocSizeOf) { size_t size = 0; if (const ValueMap* map = getData()) { size += map->sizeOfIncludingThis(mallocSizeOf); } if (NurseryKeysVector* nurseryKeys = GetNurseryKeys(this)) { size += nurseryKeys->sizeOfIncludingThis(mallocSizeOf); } return size; } void MapObject::finalize(JS::GCContext* gcx, JSObject* obj) { MOZ_ASSERT(gcx->onMainThread()); ValueMap* table = obj->as().getTableUnchecked(); if (!table) { return; } bool needsPostBarriers = obj->isTenured(); if (needsPostBarriers) { // Use the ValueMap representation which has post barriers. gcx->delete_(obj, table, MemoryUse::MapObjectTable); } else { // Use the PreBarrieredTable representation which does not. auto* preBarriedTable = reinterpret_cast(table); gcx->delete_(obj, preBarriedTable, MemoryUse::MapObjectTable); } } /* static */ void MapObject::sweepAfterMinorGC(JS::GCContext* gcx, MapObject* mapobj) { bool wasInsideNursery = IsInsideNursery(mapobj); if (wasInsideNursery && !IsForwarded(mapobj)) { finalize(gcx, mapobj); return; } mapobj = MaybeForwarded(mapobj); mapobj->getTableUnchecked()->destroyNurseryRanges(); SetHasNurseryMemory(mapobj, false); if (wasInsideNursery) { AddCellMemory(mapobj, sizeof(ValueMap), MemoryUse::MapObjectTable); } } bool MapObject::construct(JSContext* cx, unsigned argc, Value* vp) { AutoJSConstructorProfilerEntry pseudoFrame(cx, "Map"); CallArgs args = CallArgsFromVp(argc, vp); if (!ThrowIfNotConstructing(cx, args, "Map")) { return false; } RootedObject proto(cx); if (!GetPrototypeFromBuiltinConstructor(cx, args, JSProto_Map, &proto)) { return false; } Rooted obj(cx, MapObject::create(cx, proto)); if (!obj) { return false; } if (!args.get(0).isNullOrUndefined()) { FixedInvokeArgs<1> args2(cx); args2[0].set(args[0]); RootedValue thisv(cx, ObjectValue(*obj)); if (!CallSelfHostedFunction(cx, cx->names().MapConstructorInit, thisv, args2, args2.rval())) { return false; } } args.rval().setObject(*obj); return true; } bool MapObject::is(HandleValue v) { return v.isObject() && v.toObject().hasClass(&class_) && !v.toObject().as().getReservedSlot(DataSlot).isUndefined(); } bool MapObject::is(HandleObject o) { return o->hasClass(&class_) && !o->as().getReservedSlot(DataSlot).isUndefined(); } #define ARG0_KEY(cx, args, key) \ Rooted key(cx); \ if (args.length() > 0 && !key.setValue(cx, args[0])) return false const ValueMap& MapObject::extract(HandleObject o) { MOZ_ASSERT(o->hasClass(&MapObject::class_)); return *o->as().getData(); } const ValueMap& MapObject::extract(const CallArgs& args) { MOZ_ASSERT(args.thisv().isObject()); MOZ_ASSERT(args.thisv().toObject().hasClass(&MapObject::class_)); return *args.thisv().toObject().as().getData(); } uint32_t MapObject::size(JSContext* cx, HandleObject obj) { const ValueMap& map = extract(obj); static_assert(sizeof(map.count()) <= sizeof(uint32_t), "map count must be precisely representable as a JS number"); return map.count(); } bool MapObject::size_impl(JSContext* cx, const CallArgs& args) { RootedObject obj(cx, &args.thisv().toObject()); args.rval().setNumber(size(cx, obj)); return true; } bool MapObject::size(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "size"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool MapObject::get(JSContext* cx, HandleObject obj, HandleValue key, MutableHandleValue rval) { const ValueMap& map = extract(obj); Rooted k(cx); if (!k.setValue(cx, key)) { return false; } if (const ValueMap::Entry* p = map.get(k)) { rval.set(p->value); } else { rval.setUndefined(); } return true; } bool MapObject::get_impl(JSContext* cx, const CallArgs& args) { RootedObject obj(cx, &args.thisv().toObject()); return get(cx, obj, args.get(0), args.rval()); } bool MapObject::get(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "get"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool MapObject::has(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { const ValueMap& map = extract(obj); Rooted k(cx); if (!k.setValue(cx, key)) { return false; } *rval = map.has(k); return true; } bool MapObject::has_impl(JSContext* cx, const CallArgs& args) { bool found; RootedObject obj(cx, &args.thisv().toObject()); if (has(cx, obj, args.get(0), &found)) { args.rval().setBoolean(found); return true; } return false; } bool MapObject::has(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "has"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool MapObject::set_impl(JSContext* cx, const CallArgs& args) { MOZ_ASSERT(MapObject::is(args.thisv())); MapObject* obj = &args.thisv().toObject().as(); ARG0_KEY(cx, args, key); if (!setWithHashableKey(cx, obj, key, args.get(1))) { return false; } args.rval().set(args.thisv()); return true; } bool MapObject::set(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "set"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool MapObject::delete_(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { MapObject* mapObject = &obj->as(); Rooted k(cx); if (!k.setValue(cx, key)) { return false; } bool ok; if (mapObject->isTenured()) { ok = mapObject->tenuredTable()->remove(k, rval); } else { ok = mapObject->nurseryTable()->remove(k, rval); } if (!ok) { ReportOutOfMemory(cx); return false; } return true; } bool MapObject::delete_impl(JSContext* cx, const CallArgs& args) { // MapObject::trace does not trace deleted entries. Incremental GC therefore // requires that no HeapPtr objects pointing to heap values be left // alive in the ValueMap. // // OrderedHashMap::remove() doesn't destroy the removed entry. It merely // calls OrderedHashMap::MapOps::makeEmpty. But that is sufficient, because // makeEmpty clears the value by doing e->value = Value(), and in the case // of a ValueMap, Value() means HeapPtr(), which is the same as // HeapPtr(UndefinedValue()). MOZ_ASSERT(MapObject::is(args.thisv())); RootedObject obj(cx, &args.thisv().toObject()); bool found; if (!delete_(cx, obj, args.get(0), &found)) { return false; } args.rval().setBoolean(found); return true; } bool MapObject::delete_(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "delete"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool MapObject::iterator(JSContext* cx, IteratorKind kind, HandleObject obj, MutableHandleValue iter) { const ValueMap& map = extract(obj); Rooted iterobj(cx, MapIteratorObject::create(cx, obj, &map, kind)); if (!iterobj) { return false; } iter.setObject(*iterobj); return true; } bool MapObject::iterator_impl(JSContext* cx, const CallArgs& args, IteratorKind kind) { RootedObject obj(cx, &args.thisv().toObject()); return iterator(cx, kind, obj, args.rval()); } bool MapObject::keys_impl(JSContext* cx, const CallArgs& args) { return iterator_impl(cx, args, Keys); } bool MapObject::keys(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "keys"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, keys_impl, args); } bool MapObject::values_impl(JSContext* cx, const CallArgs& args) { return iterator_impl(cx, args, Values); } bool MapObject::values(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "values"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, values_impl, args); } bool MapObject::entries_impl(JSContext* cx, const CallArgs& args) { return iterator_impl(cx, args, Entries); } bool MapObject::entries(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "entries"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, entries_impl, args); } bool MapObject::clear_impl(JSContext* cx, const CallArgs& args) { RootedObject obj(cx, &args.thisv().toObject()); args.rval().setUndefined(); return clear(cx, obj); } bool MapObject::clear(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Map.prototype", "clear"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, clear_impl, args); } bool MapObject::clear(JSContext* cx, HandleObject obj) { MapObject* mapObject = &obj->as(); bool ok; if (mapObject->isTenured()) { ok = mapObject->tenuredTable()->clear(); } else { ok = mapObject->nurseryTable()->clear(); } if (!ok) { ReportOutOfMemory(cx); return false; } return true; } /*** SetIterator ************************************************************/ static const JSClassOps SetIteratorObjectClassOps = { nullptr, // addProperty nullptr, // delProperty nullptr, // enumerate nullptr, // newEnumerate nullptr, // resolve nullptr, // mayResolve SetIteratorObject::finalize, // finalize nullptr, // call nullptr, // construct nullptr, // trace }; static const ClassExtension SetIteratorObjectClassExtension = { SetIteratorObject::objectMoved, // objectMovedOp }; const JSClass SetIteratorObject::class_ = { "Set Iterator", JSCLASS_HAS_RESERVED_SLOTS(SetIteratorObject::SlotCount) | JSCLASS_FOREGROUND_FINALIZE | JSCLASS_SKIP_NURSERY_FINALIZE, &SetIteratorObjectClassOps, JS_NULL_CLASS_SPEC, &SetIteratorObjectClassExtension}; const JSFunctionSpec SetIteratorObject::methods[] = { JS_SELF_HOSTED_FN("next", "SetIteratorNext", 0, 0), JS_FS_END}; static inline ValueSet::Range* SetIteratorObjectRange(NativeObject* obj) { MOZ_ASSERT(obj->is()); return obj->maybePtrFromReservedSlot( SetIteratorObject::RangeSlot); } inline SetObject::IteratorKind SetIteratorObject::kind() const { int32_t i = getReservedSlot(KindSlot).toInt32(); MOZ_ASSERT(i == SetObject::Values || i == SetObject::Entries); return SetObject::IteratorKind(i); } /* static */ bool GlobalObject::initSetIteratorProto(JSContext* cx, Handle global) { Rooted base( cx, GlobalObject::getOrCreateIteratorPrototype(cx, global)); if (!base) { return false; } Rooted proto( cx, GlobalObject::createBlankPrototypeInheriting(cx, base)); if (!proto) { return false; } if (!JS_DefineFunctions(cx, proto, SetIteratorObject::methods) || !DefineToStringTag(cx, proto, cx->names().SetIterator)) { return false; } global->initBuiltinProto(ProtoKind::SetIteratorProto, proto); return true; } SetIteratorObject* SetIteratorObject::create(JSContext* cx, HandleObject obj, ValueSet* data, SetObject::IteratorKind kind) { MOZ_ASSERT(kind != SetObject::Keys); Handle setobj(obj.as()); Rooted global(cx, &setobj->global()); Rooted proto( cx, GlobalObject::getOrCreateSetIteratorPrototype(cx, global)); if (!proto) { return nullptr; } SetIteratorObject* iterobj = NewObjectWithGivenProto(cx, proto); if (!iterobj) { return nullptr; } iterobj->init(setobj, kind); constexpr size_t BufferSize = RoundUp(sizeof(ValueSet::Range), gc::CellAlignBytes); Nursery& nursery = cx->nursery(); void* buffer = nursery.allocateBufferSameLocation(iterobj, BufferSize); if (!buffer) { // Retry with |iterobj| and |buffer| forcibly tenured. iterobj = NewTenuredObjectWithGivenProto(cx, proto); if (!iterobj) { return nullptr; } iterobj->init(setobj, kind); buffer = nursery.allocateBufferSameLocation(iterobj, BufferSize); if (!buffer) { ReportOutOfMemory(cx); return nullptr; } } bool insideNursery = IsInsideNursery(iterobj); MOZ_ASSERT(insideNursery == nursery.isInside(buffer)); if (insideNursery && !HasNurseryMemory(setobj.get())) { if (!cx->nursery().addSetWithNurseryMemory(setobj)) { ReportOutOfMemory(cx); return nullptr; } SetHasNurseryMemory(setobj.get(), true); } auto range = data->createRange(buffer, insideNursery); iterobj->setReservedSlot(RangeSlot, PrivateValue(range)); return iterobj; } void SetIteratorObject::finalize(JS::GCContext* gcx, JSObject* obj) { MOZ_ASSERT(gcx->onMainThread()); MOZ_ASSERT(!IsInsideNursery(obj)); auto range = SetIteratorObjectRange(&obj->as()); MOZ_ASSERT(!gcx->runtime()->gc.nursery().isInside(range)); // Bug 1560019: Malloc memory associated with SetIteratorObjects is not // currently tracked. gcx->deleteUntracked(range); } size_t SetIteratorObject::objectMoved(JSObject* obj, JSObject* old) { if (!IsInsideNursery(old)) { return 0; } SetIteratorObject* iter = &obj->as(); ValueSet::Range* range = SetIteratorObjectRange(iter); if (!range) { return 0; } Nursery& nursery = iter->runtimeFromMainThread()->gc.nursery(); if (!nursery.isInside(range)) { nursery.removeMallocedBufferDuringMinorGC(range); return 0; } AutoEnterOOMUnsafeRegion oomUnsafe; auto newRange = iter->zone()->new_(*range); if (!newRange) { oomUnsafe.crash( "SetIteratorObject failed to allocate Range data while tenuring."); } range->~Range(); iter->setReservedSlot(SetIteratorObject::RangeSlot, PrivateValue(newRange)); return sizeof(ValueSet::Range); } bool SetIteratorObject::next(SetIteratorObject* setIterator, ArrayObject* resultObj) { // IC code calls this directly. AutoUnsafeCallWithABI unsafe; // Check invariants for inlined _GetNextSetEntryForIterator. // The array should be tenured, so that post-barrier can be done simply. MOZ_ASSERT(resultObj->isTenured()); // The array elements should be fixed. MOZ_ASSERT(resultObj->hasFixedElements()); MOZ_ASSERT(resultObj->getDenseInitializedLength() == 1); MOZ_ASSERT(resultObj->getDenseCapacity() >= 1); ValueSet::Range* range = SetIteratorObjectRange(setIterator); if (!range) { return true; } if (range->empty()) { DestroyRange(setIterator, range); setIterator->setReservedSlot(RangeSlot, PrivateValue(nullptr)); return true; } resultObj->setDenseElement(0, range->front().get()); range->popFront(); return false; } /* static */ JSObject* SetIteratorObject::createResult(JSContext* cx) { Rooted resultObj( cx, NewDenseFullyAllocatedArray(cx, 1, TenuredObject)); if (!resultObj) { return nullptr; } resultObj->setDenseInitializedLength(1); resultObj->initDenseElement(0, NullValue()); return resultObj; } /*** Set ********************************************************************/ const JSClassOps SetObject::classOps_ = { nullptr, // addProperty nullptr, // delProperty nullptr, // enumerate nullptr, // newEnumerate nullptr, // resolve nullptr, // mayResolve finalize, // finalize nullptr, // call nullptr, // construct trace, // trace }; const ClassSpec SetObject::classSpec_ = { GenericCreateConstructor, GenericCreatePrototype, nullptr, SetObject::staticProperties, SetObject::methods, SetObject::properties, SetObject::finishInit}; const JSClass SetObject::class_ = { "Set", JSCLASS_DELAY_METADATA_BUILDER | JSCLASS_HAS_RESERVED_SLOTS(SetObject::SlotCount) | JSCLASS_HAS_CACHED_PROTO(JSProto_Set) | JSCLASS_FOREGROUND_FINALIZE | JSCLASS_SKIP_NURSERY_FINALIZE, &SetObject::classOps_, &SetObject::classSpec_, }; const JSClass SetObject::protoClass_ = { "Set.prototype", JSCLASS_HAS_CACHED_PROTO(JSProto_Set), JS_NULL_CLASS_OPS, &SetObject::classSpec_}; const JSPropertySpec SetObject::properties[] = { JS_PSG("size", size, 0), JS_STRING_SYM_PS(toStringTag, "Set", JSPROP_READONLY), JS_PS_END}; // clang-format off const JSFunctionSpec SetObject::methods[] = { JS_INLINABLE_FN("has", has, 1, 0, SetHas), JS_FN("add", add, 1, 0), JS_FN("delete", delete_, 1, 0), JS_FN("entries", entries, 0, 0), JS_FN("clear", clear, 0, 0), JS_SELF_HOSTED_FN("forEach", "SetForEach", 2, 0), #ifdef ENABLE_NEW_SET_METHODS JS_SELF_HOSTED_FN("union", "SetUnion", 1, 0), JS_SELF_HOSTED_FN("difference", "SetDifference", 1, 0), JS_SELF_HOSTED_FN("intersection", "SetIntersection", 1, 0), JS_SELF_HOSTED_FN("symmetricDifference", "SetSymmetricDifference", 1, 0), JS_SELF_HOSTED_FN("isSubsetOf", "SetIsSubsetOf", 1, 0), JS_SELF_HOSTED_FN("isSupersetOf", "SetIsSupersetOf", 1, 0), JS_SELF_HOSTED_FN("isDisjointFrom", "SetIsDisjointFrom", 1, 0), #endif JS_FN("values", values, 0, 0), // @@iterator and |keys| re-defined in finishInit so that they have the // same identity as |values|. JS_FN("keys", values, 0, 0), JS_SYM_FN(iterator, values, 0, 0), JS_FS_END }; // clang-format on const JSPropertySpec SetObject::staticProperties[] = { JS_SELF_HOSTED_SYM_GET(species, "$SetSpecies", 0), JS_PS_END}; /* static */ bool SetObject::finishInit(JSContext* cx, HandleObject ctor, HandleObject proto) { Handle nativeProto = proto.as(); RootedValue valuesFn(cx); RootedId valuesId(cx, NameToId(cx->names().values)); if (!NativeGetProperty(cx, nativeProto, valuesId, &valuesFn)) { return false; } // 23.2.3.8 Set.prototype.keys() // The initial value of the "keys" property is the same function object // as the initial value of the "values" property. RootedId keysId(cx, NameToId(cx->names().keys)); if (!NativeDefineDataProperty(cx, nativeProto, keysId, valuesFn, 0)) { return false; } // 23.2.3.11 Set.prototype[@@iterator]() // See above. RootedId iteratorId(cx, PropertyKey::Symbol(cx->wellKnownSymbols().iterator)); return NativeDefineDataProperty(cx, nativeProto, iteratorId, valuesFn, 0); } bool SetObject::keys(JSContext* cx, HandleObject obj, JS::MutableHandle> keys) { ValueSet* set = obj->as().getData(); if (!set) { return false; } for (ValueSet::Range r = set->all(); !r.empty(); r.popFront()) { if (!keys.append(r.front().get())) { return false; } } return true; } bool SetObject::add(JSContext* cx, HandleObject obj, HandleValue k) { ValueSet* set = obj->as().getData(); if (!set) { return false; } Rooted key(cx); if (!key.setValue(cx, k)) { return false; } if (!PostWriteBarrier(&obj->as(), key.get()) || !set->put(key.get())) { ReportOutOfMemory(cx); return false; } return true; } SetObject* SetObject::create(JSContext* cx, HandleObject proto /* = nullptr */) { auto set = cx->make_unique(cx->zone(), cx->realm()->randomHashCodeScrambler()); if (!set) { return nullptr; } if (!set->init()) { ReportOutOfMemory(cx); return nullptr; } AutoSetNewObjectMetadata metadata(cx); SetObject* obj = NewObjectWithClassProto(cx, proto); if (!obj) { return nullptr; } bool insideNursery = IsInsideNursery(obj); if (insideNursery && !cx->nursery().addSetWithNurseryMemory(obj)) { ReportOutOfMemory(cx); return nullptr; } InitReservedSlot(obj, DataSlot, set.release(), MemoryUse::MapObjectTable); obj->initReservedSlot(NurseryKeysSlot, PrivateValue(nullptr)); obj->initReservedSlot(HasNurseryMemorySlot, JS::BooleanValue(insideNursery)); return obj; } void SetObject::trace(JSTracer* trc, JSObject* obj) { SetObject* setobj = static_cast(obj); if (ValueSet* set = setobj->getData()) { set->trace(trc); } } size_t SetObject::sizeOfData(mozilla::MallocSizeOf mallocSizeOf) { size_t size = 0; if (ValueSet* set = getData()) { size += set->sizeOfIncludingThis(mallocSizeOf); } if (NurseryKeysVector* nurseryKeys = GetNurseryKeys(this)) { size += nurseryKeys->sizeOfIncludingThis(mallocSizeOf); } return size; } void SetObject::finalize(JS::GCContext* gcx, JSObject* obj) { MOZ_ASSERT(gcx->onMainThread()); SetObject* setobj = static_cast(obj); if (ValueSet* set = setobj->getData()) { gcx->delete_(obj, set, MemoryUse::MapObjectTable); } } /* static */ void SetObject::sweepAfterMinorGC(JS::GCContext* gcx, SetObject* setobj) { bool wasInsideNursery = IsInsideNursery(setobj); if (wasInsideNursery && !IsForwarded(setobj)) { finalize(gcx, setobj); return; } setobj = MaybeForwarded(setobj); setobj->getData()->destroyNurseryRanges(); SetHasNurseryMemory(setobj, false); if (wasInsideNursery) { AddCellMemory(setobj, sizeof(ValueSet), MemoryUse::MapObjectTable); } } bool SetObject::isBuiltinAdd(HandleValue add) { return IsNativeFunction(add, SetObject::add); } bool SetObject::construct(JSContext* cx, unsigned argc, Value* vp) { AutoJSConstructorProfilerEntry pseudoFrame(cx, "Set"); CallArgs args = CallArgsFromVp(argc, vp); if (!ThrowIfNotConstructing(cx, args, "Set")) { return false; } RootedObject proto(cx); if (!GetPrototypeFromBuiltinConstructor(cx, args, JSProto_Set, &proto)) { return false; } Rooted obj(cx, SetObject::create(cx, proto)); if (!obj) { return false; } if (!args.get(0).isNullOrUndefined()) { RootedValue iterable(cx, args[0]); bool optimized = false; if (!IsOptimizableInitForSet(cx, obj, iterable, &optimized)) { return false; } if (optimized) { RootedValue keyVal(cx); Rooted key(cx); ValueSet* set = obj->getData(); Rooted array(cx, &iterable.toObject().as()); for (uint32_t index = 0; index < array->getDenseInitializedLength(); ++index) { keyVal.set(array->getDenseElement(index)); MOZ_ASSERT(!keyVal.isMagic(JS_ELEMENTS_HOLE)); if (!key.setValue(cx, keyVal)) { return false; } if (!PostWriteBarrier(obj, key.get()) || !set->put(key.get())) { ReportOutOfMemory(cx); return false; } } } else { FixedInvokeArgs<1> args2(cx); args2[0].set(args[0]); RootedValue thisv(cx, ObjectValue(*obj)); if (!CallSelfHostedFunction(cx, cx->names().SetConstructorInit, thisv, args2, args2.rval())) { return false; } } } args.rval().setObject(*obj); return true; } bool SetObject::is(HandleValue v) { return v.isObject() && v.toObject().hasClass(&class_) && !v.toObject().as().getReservedSlot(DataSlot).isUndefined(); } bool SetObject::is(HandleObject o) { return o->hasClass(&class_) && !o->as().getReservedSlot(DataSlot).isUndefined(); } ValueSet& SetObject::extract(HandleObject o) { MOZ_ASSERT(o->hasClass(&SetObject::class_)); return *o->as().getData(); } ValueSet& SetObject::extract(const CallArgs& args) { MOZ_ASSERT(args.thisv().isObject()); MOZ_ASSERT(args.thisv().toObject().hasClass(&SetObject::class_)); return *static_cast(args.thisv().toObject()).getData(); } uint32_t SetObject::size(JSContext* cx, HandleObject obj) { MOZ_ASSERT(SetObject::is(obj)); ValueSet& set = extract(obj); static_assert(sizeof(set.count()) <= sizeof(uint32_t), "set count must be precisely representable as a JS number"); return set.count(); } bool SetObject::size_impl(JSContext* cx, const CallArgs& args) { MOZ_ASSERT(is(args.thisv())); ValueSet& set = extract(args); static_assert(sizeof(set.count()) <= sizeof(uint32_t), "set count must be precisely representable as a JS number"); args.rval().setNumber(set.count()); return true; } bool SetObject::size(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "size"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool SetObject::has_impl(JSContext* cx, const CallArgs& args) { MOZ_ASSERT(is(args.thisv())); ValueSet& set = extract(args); ARG0_KEY(cx, args, key); args.rval().setBoolean(set.has(key)); return true; } bool SetObject::has(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { MOZ_ASSERT(SetObject::is(obj)); ValueSet& set = extract(obj); Rooted k(cx); if (!k.setValue(cx, key)) { return false; } *rval = set.has(k); return true; } bool SetObject::has(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "has"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool SetObject::add_impl(JSContext* cx, const CallArgs& args) { MOZ_ASSERT(is(args.thisv())); ValueSet& set = extract(args); ARG0_KEY(cx, args, key); if (!PostWriteBarrier(&args.thisv().toObject().as(), key.get()) || !set.put(key.get())) { ReportOutOfMemory(cx); return false; } args.rval().set(args.thisv()); return true; } bool SetObject::add(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "add"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool SetObject::delete_(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { MOZ_ASSERT(SetObject::is(obj)); ValueSet& set = extract(obj); Rooted k(cx); if (!k.setValue(cx, key)) { return false; } if (!set.remove(k, rval)) { ReportOutOfMemory(cx); return false; } return true; } bool SetObject::delete_impl(JSContext* cx, const CallArgs& args) { MOZ_ASSERT(is(args.thisv())); ValueSet& set = extract(args); ARG0_KEY(cx, args, key); bool found; if (!set.remove(key, &found)) { ReportOutOfMemory(cx); return false; } args.rval().setBoolean(found); return true; } bool SetObject::delete_(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "delete"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, args); } bool SetObject::iterator(JSContext* cx, IteratorKind kind, HandleObject obj, MutableHandleValue iter) { MOZ_ASSERT(SetObject::is(obj)); ValueSet& set = extract(obj); Rooted iterobj(cx, SetIteratorObject::create(cx, obj, &set, kind)); if (!iterobj) { return false; } iter.setObject(*iterobj); return true; } bool SetObject::iterator_impl(JSContext* cx, const CallArgs& args, IteratorKind kind) { Rooted setobj(cx, &args.thisv().toObject().as()); ValueSet& set = *setobj->getData(); Rooted iterobj(cx, SetIteratorObject::create(cx, setobj, &set, kind)); if (!iterobj) { return false; } args.rval().setObject(*iterobj); return true; } bool SetObject::values_impl(JSContext* cx, const CallArgs& args) { return iterator_impl(cx, args, Values); } bool SetObject::values(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "values"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, values_impl, args); } bool SetObject::entries_impl(JSContext* cx, const CallArgs& args) { return iterator_impl(cx, args, Entries); } bool SetObject::entries(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "entries"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, entries_impl, args); } bool SetObject::clear(JSContext* cx, HandleObject obj) { MOZ_ASSERT(SetObject::is(obj)); ValueSet& set = extract(obj); if (!set.clear()) { ReportOutOfMemory(cx); return false; } return true; } bool SetObject::clear_impl(JSContext* cx, const CallArgs& args) { Rooted setobj(cx, &args.thisv().toObject().as()); if (!setobj->getData()->clear()) { ReportOutOfMemory(cx); return false; } args.rval().setUndefined(); return true; } bool SetObject::clear(JSContext* cx, unsigned argc, Value* vp) { AutoJSMethodProfilerEntry pseudoFrame(cx, "Set.prototype", "clear"); CallArgs args = CallArgsFromVp(argc, vp); return CallNonGenericMethod(cx, is, clear_impl, args); } /*** JS static utility functions ********************************************/ static bool forEach(const char* funcName, JSContext* cx, HandleObject obj, HandleValue callbackFn, HandleValue thisArg) { CHECK_THREAD(cx); RootedId forEachId(cx, NameToId(cx->names().forEach)); RootedFunction forEachFunc( cx, JS::GetSelfHostedFunction(cx, funcName, forEachId, 2)); if (!forEachFunc) { return false; } RootedValue fval(cx, ObjectValue(*forEachFunc)); return Call(cx, fval, obj, callbackFn, thisArg, &fval); } // Handles Clear/Size for public jsapi map/set access template RetT CallObjFunc(RetT (*ObjFunc)(JSContext*, HandleObject), JSContext* cx, HandleObject obj) { CHECK_THREAD(cx); cx->check(obj); // Always unwrap, in case this is an xray or cross-compartment wrapper. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); // Enter the realm of the backing object before calling functions on // it. JSAutoRealm ar(cx, unwrappedObj); return ObjFunc(cx, unwrappedObj); } // Handles Has/Delete for public jsapi map/set access bool CallObjFunc(bool (*ObjFunc)(JSContext* cx, HandleObject obj, HandleValue key, bool* rval), JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { CHECK_THREAD(cx); cx->check(obj, key); // Always unwrap, in case this is an xray or cross-compartment wrapper. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); JSAutoRealm ar(cx, unwrappedObj); // If we're working with a wrapped map/set, rewrap the key into the // compartment of the unwrapped map/set. RootedValue wrappedKey(cx, key); if (obj != unwrappedObj) { if (!JS_WrapValue(cx, &wrappedKey)) { return false; } } return ObjFunc(cx, unwrappedObj, wrappedKey, rval); } // Handles iterator generation for public jsapi map/set access template bool CallObjFunc(bool (*ObjFunc)(JSContext* cx, Iter kind, HandleObject obj, MutableHandleValue iter), JSContext* cx, Iter iterType, HandleObject obj, MutableHandleValue rval) { CHECK_THREAD(cx); cx->check(obj); // Always unwrap, in case this is an xray or cross-compartment wrapper. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); { // Retrieve the iterator while in the unwrapped map/set's compartment, // otherwise we'll crash on a compartment assert. JSAutoRealm ar(cx, unwrappedObj); if (!ObjFunc(cx, iterType, unwrappedObj, rval)) { return false; } } // If the caller is in a different compartment than the map/set, rewrap the // iterator object into the caller's compartment. if (obj != unwrappedObj) { if (!JS_WrapValue(cx, rval)) { return false; } } return true; } /*** JS public APIs *********************************************************/ JS_PUBLIC_API JSObject* JS::NewMapObject(JSContext* cx) { return MapObject::create(cx); } JS_PUBLIC_API uint32_t JS::MapSize(JSContext* cx, HandleObject obj) { return CallObjFunc(&MapObject::size, cx, obj); } JS_PUBLIC_API bool JS::MapGet(JSContext* cx, HandleObject obj, HandleValue key, MutableHandleValue rval) { CHECK_THREAD(cx); cx->check(obj, key, rval); // Unwrap the object, and enter its realm. If object isn't wrapped, // this is essentially a noop. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); { JSAutoRealm ar(cx, unwrappedObj); RootedValue wrappedKey(cx, key); // If we passed in a wrapper, wrap our key into its compartment now. if (obj != unwrappedObj) { if (!JS_WrapValue(cx, &wrappedKey)) { return false; } } if (!MapObject::get(cx, unwrappedObj, wrappedKey, rval)) { return false; } } // If we passed in a wrapper, wrap our return value on the way out. if (obj != unwrappedObj) { if (!JS_WrapValue(cx, rval)) { return false; } } return true; } JS_PUBLIC_API bool JS::MapSet(JSContext* cx, HandleObject obj, HandleValue key, HandleValue val) { CHECK_THREAD(cx); cx->check(obj, key, val); // Unwrap the object, and enter its compartment. If object isn't wrapped, // this is essentially a noop. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); { JSAutoRealm ar(cx, unwrappedObj); // If we passed in a wrapper, wrap both key and value before adding to // the map RootedValue wrappedKey(cx, key); RootedValue wrappedValue(cx, val); if (obj != unwrappedObj) { if (!JS_WrapValue(cx, &wrappedKey) || !JS_WrapValue(cx, &wrappedValue)) { return false; } } return MapObject::set(cx, unwrappedObj, wrappedKey, wrappedValue); } } JS_PUBLIC_API bool JS::MapHas(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { return CallObjFunc(MapObject::has, cx, obj, key, rval); } JS_PUBLIC_API bool JS::MapDelete(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { return CallObjFunc(MapObject::delete_, cx, obj, key, rval); } JS_PUBLIC_API bool JS::MapClear(JSContext* cx, HandleObject obj) { return CallObjFunc(&MapObject::clear, cx, obj); } JS_PUBLIC_API bool JS::MapKeys(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return CallObjFunc(&MapObject::iterator, cx, MapObject::Keys, obj, rval); } JS_PUBLIC_API bool JS::MapValues(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return CallObjFunc(&MapObject::iterator, cx, MapObject::Values, obj, rval); } JS_PUBLIC_API bool JS::MapEntries(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return CallObjFunc(&MapObject::iterator, cx, MapObject::Entries, obj, rval); } JS_PUBLIC_API bool JS::MapForEach(JSContext* cx, HandleObject obj, HandleValue callbackFn, HandleValue thisVal) { return forEach("MapForEach", cx, obj, callbackFn, thisVal); } JS_PUBLIC_API JSObject* JS::NewSetObject(JSContext* cx) { return SetObject::create(cx); } JS_PUBLIC_API uint32_t JS::SetSize(JSContext* cx, HandleObject obj) { return CallObjFunc(&SetObject::size, cx, obj); } JS_PUBLIC_API bool JS::SetAdd(JSContext* cx, HandleObject obj, HandleValue key) { CHECK_THREAD(cx); cx->check(obj, key); // Unwrap the object, and enter its compartment. If object isn't wrapped, // this is essentially a noop. RootedObject unwrappedObj(cx); unwrappedObj = UncheckedUnwrap(obj); { JSAutoRealm ar(cx, unwrappedObj); // If we passed in a wrapper, wrap key before adding to the set RootedValue wrappedKey(cx, key); if (obj != unwrappedObj) { if (!JS_WrapValue(cx, &wrappedKey)) { return false; } } return SetObject::add(cx, unwrappedObj, wrappedKey); } } JS_PUBLIC_API bool JS::SetHas(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { return CallObjFunc(SetObject::has, cx, obj, key, rval); } JS_PUBLIC_API bool JS::SetDelete(JSContext* cx, HandleObject obj, HandleValue key, bool* rval) { return CallObjFunc(SetObject::delete_, cx, obj, key, rval); } JS_PUBLIC_API bool JS::SetClear(JSContext* cx, HandleObject obj) { return CallObjFunc(&SetObject::clear, cx, obj); } JS_PUBLIC_API bool JS::SetKeys(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return SetValues(cx, obj, rval); } JS_PUBLIC_API bool JS::SetValues(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return CallObjFunc(&SetObject::iterator, cx, SetObject::Values, obj, rval); } JS_PUBLIC_API bool JS::SetEntries(JSContext* cx, HandleObject obj, MutableHandleValue rval) { return CallObjFunc(&SetObject::iterator, cx, SetObject::Entries, obj, rval); } JS_PUBLIC_API bool JS::SetForEach(JSContext* cx, HandleObject obj, HandleValue callbackFn, HandleValue thisVal) { return forEach("SetForEach", cx, obj, callbackFn, thisVal); }