/* -*- 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/. */ /* * JS object implementation. */ #include "vm/JSObject-inl.h" #include "mozilla/MemoryReporting.h" #include #include "jsapi.h" #include "jsexn.h" #include "jsfriendapi.h" #include "jsnum.h" #include "jstypes.h" #include "builtin/BigInt.h" #include "builtin/MapObject.h" #include "builtin/Object.h" #include "builtin/String.h" #include "builtin/Symbol.h" #include "builtin/WeakSetObject.h" #include "gc/AllocKind.h" #include "gc/GC.h" #include "js/CharacterEncoding.h" #include "js/friend/DumpFunctions.h" // js::DumpObject #include "js/friend/ErrorMessages.h" // JSErrNum, js::GetErrorMessage, JSMSG_* #include "js/friend/WindowProxy.h" // js::IsWindow, js::ToWindowProxyIfWindow #include "js/MemoryMetrics.h" #include "js/PropertyDescriptor.h" // JS::FromPropertyDescriptor #include "js/PropertySpec.h" // JSPropertySpec #include "js/Proxy.h" #include "js/Result.h" #include "js/UbiNode.h" #include "js/Wrapper.h" #include "proxy/DeadObjectProxy.h" #include "util/Memory.h" #include "util/Text.h" #include "util/WindowsWrapper.h" #include "vm/ArgumentsObject.h" #include "vm/BytecodeUtil.h" #include "vm/Compartment.h" #include "vm/DateObject.h" #include "vm/Interpreter.h" #include "vm/Iteration.h" #include "vm/JSAtom.h" #include "vm/JSContext.h" #include "vm/JSFunction.h" #include "vm/JSScript.h" #include "vm/ProxyObject.h" #include "vm/RegExpObject.h" #include "vm/Shape.h" #include "vm/TypedArrayObject.h" #include "vm/Watchtower.h" #include "vm/WellKnownAtom.h" // js_*_str #include "vm/WrapperObject.h" #ifdef ENABLE_RECORD_TUPLE # include "builtin/RecordObject.h" # include "builtin/TupleObject.h" # include "vm/RecordType.h" # include "vm/TupleType.h" #endif #include "wasm/WasmGcObject.h" #include "gc/StableCellHasher-inl.h" #include "vm/BooleanObject-inl.h" #include "vm/EnvironmentObject-inl.h" #include "vm/Interpreter-inl.h" #include "vm/JSAtom-inl.h" #include "vm/JSContext-inl.h" #include "vm/NativeObject-inl.h" #include "vm/NumberObject-inl.h" #include "vm/ObjectFlags-inl.h" #include "vm/Realm-inl.h" #include "vm/StringObject-inl.h" #include "vm/TypedArrayObject-inl.h" using namespace js; using mozilla::Maybe; void js::ReportNotObject(JSContext* cx, JSErrNum err, int spindex, HandleValue v) { MOZ_ASSERT(!v.isObject()); ReportValueError(cx, err, spindex, v, nullptr); } void js::ReportNotObject(JSContext* cx, JSErrNum err, HandleValue v) { ReportNotObject(cx, err, JSDVG_SEARCH_STACK, v); } void js::ReportNotObject(JSContext* cx, const Value& v) { RootedValue value(cx, v); ReportNotObject(cx, JSMSG_OBJECT_REQUIRED, value); } void js::ReportNotObjectArg(JSContext* cx, const char* nth, const char* fun, HandleValue v) { MOZ_ASSERT(!v.isObject()); UniqueChars bytes; if (const char* chars = ValueToSourceForError(cx, v, bytes)) { JS_ReportErrorNumberLatin1(cx, GetErrorMessage, nullptr, JSMSG_OBJECT_REQUIRED_ARG, nth, fun, chars); } } JS_PUBLIC_API const char* JS::InformalValueTypeName(const Value& v) { switch (v.type()) { case ValueType::Double: case ValueType::Int32: return "number"; case ValueType::Boolean: return "boolean"; case ValueType::Undefined: return "undefined"; case ValueType::Null: return "null"; case ValueType::String: return "string"; case ValueType::Symbol: return "symbol"; case ValueType::BigInt: return "bigint"; case ValueType::Object: #ifdef ENABLE_RECORD_TUPLE case ValueType::ExtendedPrimitive: #endif return v.getObjectPayload().getClass()->name; case ValueType::Magic: return "magic"; case ValueType::PrivateGCThing: break; } MOZ_CRASH("unexpected type"); } // ES6 draft rev37 6.2.4.4 FromPropertyDescriptor JS_PUBLIC_API bool JS::FromPropertyDescriptor( JSContext* cx, Handle> desc_, MutableHandleValue vp) { AssertHeapIsIdle(); CHECK_THREAD(cx); cx->check(desc_); // Step 1. if (desc_.isNothing()) { vp.setUndefined(); return true; } Rooted desc(cx, *desc_); return FromPropertyDescriptorToObject(cx, desc, vp); } bool js::FromPropertyDescriptorToObject(JSContext* cx, Handle desc, MutableHandleValue vp) { // Step 2-3. RootedObject obj(cx, NewPlainObject(cx)); if (!obj) { return false; } const JSAtomState& names = cx->names(); // Step 4. if (desc.hasValue()) { if (!DefineDataProperty(cx, obj, names.value, desc.value())) { return false; } } // Step 5. RootedValue v(cx); if (desc.hasWritable()) { v.setBoolean(desc.writable()); if (!DefineDataProperty(cx, obj, names.writable, v)) { return false; } } // Step 6. if (desc.hasGetter()) { if (JSObject* get = desc.getter()) { v.setObject(*get); } else { v.setUndefined(); } if (!DefineDataProperty(cx, obj, names.get, v)) { return false; } } // Step 7. if (desc.hasSetter()) { if (JSObject* set = desc.setter()) { v.setObject(*set); } else { v.setUndefined(); } if (!DefineDataProperty(cx, obj, names.set, v)) { return false; } } // Step 8. if (desc.hasEnumerable()) { v.setBoolean(desc.enumerable()); if (!DefineDataProperty(cx, obj, names.enumerable, v)) { return false; } } // Step 9. if (desc.hasConfigurable()) { v.setBoolean(desc.configurable()); if (!DefineDataProperty(cx, obj, names.configurable, v)) { return false; } } vp.setObject(*obj); return true; } bool js::GetFirstArgumentAsObject(JSContext* cx, const CallArgs& args, const char* method, MutableHandleObject objp) { if (!args.requireAtLeast(cx, method, 1)) { return false; } HandleValue v = args[0]; if (!v.isObject()) { UniqueChars bytes = DecompileValueGenerator(cx, JSDVG_SEARCH_STACK, v, nullptr); if (!bytes) { return false; } JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, JSMSG_UNEXPECTED_TYPE, bytes.get(), "not an object"); return false; } objp.set(&v.toObject()); return true; } static bool GetPropertyIfPresent(JSContext* cx, HandleObject obj, HandleId id, MutableHandleValue vp, bool* foundp) { if (!HasProperty(cx, obj, id, foundp)) { return false; } if (!*foundp) { vp.setUndefined(); return true; } return GetProperty(cx, obj, obj, id, vp); } bool js::Throw(JSContext* cx, HandleId id, unsigned errorNumber, const char* details) { MOZ_ASSERT(js_ErrorFormatString[errorNumber].argCount == (details ? 2 : 1)); MOZ_ASSERT_IF(details, JS::StringIsASCII(details)); UniqueChars bytes = IdToPrintableUTF8(cx, id, IdToPrintableBehavior::IdIsPropertyKey); if (!bytes) { return false; } if (details) { JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, errorNumber, bytes.get(), details); } else { JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, errorNumber, bytes.get()); } return false; } /*** PropertyDescriptor operations and DefineProperties *********************/ #ifndef ENABLE_DECORATORS // These are defined by CommonPropertyNames.h and WellKnownAtom.{cpp,h} // when decorators are enabled. static const char js_getter_str[] = "getter"; static const char js_setter_str[] = "setter"; #endif static Result<> CheckCallable(JSContext* cx, JSObject* obj, const char* fieldName) { if (obj && !obj->isCallable()) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_BAD_GET_SET_FIELD, fieldName); return cx->alreadyReportedError(); } return Ok(); } // 6.2.5.5 ToPropertyDescriptor(Obj) bool js::ToPropertyDescriptor(JSContext* cx, HandleValue descval, bool checkAccessors, MutableHandle desc_) { // Step 1. RootedObject obj(cx, RequireObject(cx, JSMSG_OBJECT_REQUIRED_PROP_DESC, descval)); if (!obj) { return false; } // Step 2. Rooted desc(cx, PropertyDescriptor::Empty()); RootedId id(cx); RootedValue v(cx); // Steps 3-4. id = NameToId(cx->names().enumerable); bool hasEnumerable = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasEnumerable)) { return false; } if (hasEnumerable) { desc.setEnumerable(ToBoolean(v)); } // Steps 5-6. id = NameToId(cx->names().configurable); bool hasConfigurable = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasConfigurable)) { return false; } if (hasConfigurable) { desc.setConfigurable(ToBoolean(v)); } // Steps 7-8. id = NameToId(cx->names().value); bool hasValue = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasValue)) { return false; } if (hasValue) { desc.setValue(v); } // Steps 9-10. id = NameToId(cx->names().writable); bool hasWritable = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasWritable)) { return false; } if (hasWritable) { desc.setWritable(ToBoolean(v)); } // Steps 11-12. id = NameToId(cx->names().get); bool hasGet = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasGet)) { return false; } RootedObject getter(cx); if (hasGet) { if (v.isObject()) { if (checkAccessors) { JS_TRY_OR_RETURN_FALSE(cx, CheckCallable(cx, &v.toObject(), js_getter_str)); } getter = &v.toObject(); } else if (v.isUndefined()) { getter = nullptr; } else { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_BAD_GET_SET_FIELD, js_getter_str); return false; } } // Steps 13-14. id = NameToId(cx->names().set); bool hasSet = false; if (!GetPropertyIfPresent(cx, obj, id, &v, &hasSet)) { return false; } RootedObject setter(cx); if (hasSet) { if (v.isObject()) { if (checkAccessors) { JS_TRY_OR_RETURN_FALSE(cx, CheckCallable(cx, &v.toObject(), js_setter_str)); } setter = &v.toObject(); } else if (v.isUndefined()) { setter = nullptr; } else { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_BAD_GET_SET_FIELD, js_setter_str); return false; } } // Step 15. if (hasGet || hasSet) { if (hasValue || hasWritable) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_INVALID_DESCRIPTOR); return false; } // We delay setGetter/setSetter after the previous check, // because otherwise we would assert. if (hasGet) { desc.setGetter(getter); } if (hasSet) { desc.setSetter(setter); } } desc.assertValid(); desc_.set(desc); return true; } Result<> js::CheckPropertyDescriptorAccessors(JSContext* cx, Handle desc) { if (desc.hasGetter()) { MOZ_TRY(CheckCallable(cx, desc.getter(), js_getter_str)); } if (desc.hasSetter()) { MOZ_TRY(CheckCallable(cx, desc.setter(), js_setter_str)); } return Ok(); } // 6.2.5.6 CompletePropertyDescriptor(Desc) void js::CompletePropertyDescriptor(MutableHandle desc) { // Step 1. desc.assertValid(); // Step 2. // Let like be the Record { [[Value]]: undefined, [[Writable]]: false, // [[Get]]: undefined, [[Set]]: undefined, // [[Enumerable]]: false, [[Configurable]]: false }. // Step 3. if (desc.isGenericDescriptor() || desc.isDataDescriptor()) { // Step 3.a. if (!desc.hasValue()) { desc.setValue(UndefinedHandleValue); } // Step 3.b. if (!desc.hasWritable()) { desc.setWritable(false); } } else { // Step 4.a. if (!desc.hasGetter()) { desc.setGetter(nullptr); } // Step 4.b. if (!desc.hasSetter()) { desc.setSetter(nullptr); } } // Step 5. if (!desc.hasEnumerable()) { desc.setEnumerable(false); } // Step 6. if (!desc.hasConfigurable()) { desc.setConfigurable(false); } desc.assertComplete(); } bool js::ReadPropertyDescriptors( JSContext* cx, HandleObject props, bool checkAccessors, MutableHandleIdVector ids, MutableHandle descs) { if (!GetPropertyKeys(cx, props, JSITER_OWNONLY | JSITER_SYMBOLS, ids)) { return false; } RootedId id(cx); for (size_t i = 0, len = ids.length(); i < len; i++) { id = ids[i]; Rooted desc(cx); RootedValue v(cx); if (!GetProperty(cx, props, props, id, &v) || !ToPropertyDescriptor(cx, v, checkAccessors, &desc) || !descs.append(desc)) { return false; } } return true; } /*** Seal and freeze ********************************************************/ /* ES6 draft rev 29 (6 Dec 2014) 7.3.13. */ bool js::SetIntegrityLevel(JSContext* cx, HandleObject obj, IntegrityLevel level) { cx->check(obj); // Steps 3-5. (Steps 1-2 are redundant assertions.) if (!PreventExtensions(cx, obj)) { return false; } // Steps 6-9, loosely interpreted. if (obj->is() && !obj->is() && !obj->is()) { Handle nobj = obj.as(); // Use a fast path to seal/freeze properties. This has the benefit of // creating shared property maps if possible, whereas the slower/generic // implementation below ends up converting non-empty objects to dictionary // mode. if (nobj->shape()->propMapLength() > 0) { if (!NativeObject::freezeOrSealProperties(cx, nobj, level)) { return false; } } // Ordinarily ArraySetLength handles this, but we're going behind its back // right now, so we must do this manually. if (level == IntegrityLevel::Frozen && obj->is()) { obj->as().setNonWritableLength(cx); } } else { // Steps 6-7. RootedIdVector keys(cx); if (!GetPropertyKeys( cx, obj, JSITER_HIDDEN | JSITER_OWNONLY | JSITER_SYMBOLS, &keys)) { return false; } RootedId id(cx); Rooted desc(cx, PropertyDescriptor::Empty()); // 8.a/9.a. The two different loops are merged here. for (size_t i = 0; i < keys.length(); i++) { id = keys[i]; if (level == IntegrityLevel::Sealed) { // 8.a.i. desc.setConfigurable(false); } else { // 9.a.i-ii. Rooted> currentDesc(cx); if (!GetOwnPropertyDescriptor(cx, obj, id, ¤tDesc)) { return false; } // 9.a.iii. if (currentDesc.isNothing()) { continue; } // 9.a.iii.1-2 desc = PropertyDescriptor::Empty(); if (currentDesc->isAccessorDescriptor()) { desc.setConfigurable(false); } else { desc.setConfigurable(false); desc.setWritable(false); } } // 8.a.i-ii. / 9.a.iii.3-4 if (!DefineProperty(cx, obj, id, desc)) { return false; } } } // Finally, freeze or seal the dense elements. if (obj->is()) { if (!ObjectElements::FreezeOrSeal(cx, obj.as(), level)) { return false; } } return true; } static bool ResolveLazyProperties(JSContext* cx, Handle obj) { const JSClass* clasp = obj->getClass(); if (JSEnumerateOp enumerate = clasp->getEnumerate()) { if (!enumerate(cx, obj)) { return false; } } if (clasp->getNewEnumerate() && clasp->getResolve()) { RootedIdVector properties(cx); if (!clasp->getNewEnumerate()(cx, obj, &properties, /* enumerableOnly = */ false)) { return false; } RootedId id(cx); for (size_t i = 0; i < properties.length(); i++) { id = properties[i]; bool found; if (!HasOwnProperty(cx, obj, id, &found)) { return false; } } } return true; } // ES6 draft rev33 (12 Feb 2015) 7.3.15 bool js::TestIntegrityLevel(JSContext* cx, HandleObject obj, IntegrityLevel level, bool* result) { // Steps 3-6. (Steps 1-2 are redundant assertions.) bool status; if (!IsExtensible(cx, obj, &status)) { return false; } if (status) { *result = false; return true; } // Fast path for native objects. if (obj->is()) { Handle nobj = obj.as(); // Force lazy properties to be resolved. if (!ResolveLazyProperties(cx, nobj)) { return false; } // Typed array elements are configurable, writable properties, so if any // elements are present, the typed array can neither be sealed nor frozen. if (nobj->is() && nobj->as().length() > 0) { *result = false; return true; } bool hasDenseElements = false; for (size_t i = 0; i < nobj->getDenseInitializedLength(); i++) { if (nobj->containsDenseElement(i)) { hasDenseElements = true; break; } } if (hasDenseElements) { // Unless the sealed flag is set, dense elements are configurable. if (!nobj->denseElementsAreSealed()) { *result = false; return true; } // Unless the frozen flag is set, dense elements are writable. if (level == IntegrityLevel::Frozen && !nobj->denseElementsAreFrozen()) { *result = false; return true; } } // Steps 7-9. for (ShapePropertyIter iter(nobj->shape()); !iter.done(); iter++) { // Steps 9.c.i-ii. if (iter->configurable() || (level == IntegrityLevel::Frozen && iter->isDataDescriptor() && iter->writable())) { // Private fields on objects don't participate in the frozen state, and // so should be elided from checking for frozen state. if (iter->key().isPrivateName()) { continue; } *result = false; return true; } } } else { // Steps 7-8. RootedIdVector props(cx); if (!GetPropertyKeys( cx, obj, JSITER_HIDDEN | JSITER_OWNONLY | JSITER_SYMBOLS, &props)) { return false; } // Step 9. RootedId id(cx); Rooted> desc(cx); for (size_t i = 0, len = props.length(); i < len; i++) { id = props[i]; // Steps 9.a-b. if (!GetOwnPropertyDescriptor(cx, obj, id, &desc)) { return false; } // Step 9.c. if (desc.isNothing()) { continue; } // Steps 9.c.i-ii. if (desc->configurable() || (level == IntegrityLevel::Frozen && desc->isDataDescriptor() && desc->writable())) { // Since we don't request JSITER_PRIVATE in GetPropertyKeys above, we // should never see a private name here. MOZ_ASSERT(!id.isPrivateName()); *result = false; return true; } } } // Step 10. *result = true; return true; } /* * */ static MOZ_ALWAYS_INLINE NativeObject* NewObject(JSContext* cx, const JSClass* clasp, Handle proto, gc::AllocKind kind, NewObjectKind newKind) { MOZ_ASSERT(clasp->isNativeObject()); // Some classes have specialized allocation functions and shouldn't end up // here. MOZ_ASSERT(clasp != &ArrayObject::class_); MOZ_ASSERT(clasp != &PlainObject::class_); MOZ_ASSERT(!clasp->isJSFunction()); // Computing nfixed based on the AllocKind isn't right for objects which can // store fixed data inline (TypedArrays and ArrayBuffers) so for simplicity // and performance reasons we don't support such objects here. MOZ_ASSERT(!ClassCanHaveFixedData(clasp)); size_t nfixed = GetGCKindSlots(kind); if (CanChangeToBackgroundAllocKind(kind, clasp)) { kind = ForegroundToBackgroundAllocKind(kind); } Rooted shape( cx, SharedShape::getInitialShape(cx, clasp, cx->realm(), proto, nfixed, ObjectFlags())); if (!shape) { return nullptr; } gc::Heap heap = GetInitialHeap(newKind, clasp); NativeObject* obj = NativeObject::create(cx, kind, heap, shape); if (!obj) { return nullptr; } probes::CreateObject(cx, obj); return obj; } NativeObject* js::NewObjectWithGivenTaggedProto(JSContext* cx, const JSClass* clasp, Handle proto, gc::AllocKind allocKind, NewObjectKind newKind) { return NewObject(cx, clasp, proto, allocKind, newKind); } NativeObject* js::NewObjectWithClassProto(JSContext* cx, const JSClass* clasp, HandleObject protoArg, gc::AllocKind allocKind, NewObjectKind newKind) { if (protoArg) { return NewObjectWithGivenTaggedProto(cx, clasp, AsTaggedProto(protoArg), allocKind, newKind); } // Find the appropriate proto for clasp. Built-in classes have a cached // proto on cx->global(); all others get %ObjectPrototype%. JSProtoKey protoKey = JSCLASS_CACHED_PROTO_KEY(clasp); if (protoKey == JSProto_Null) { protoKey = JSProto_Object; } JSObject* proto = GlobalObject::getOrCreatePrototype(cx, protoKey); if (!proto) { return nullptr; } Rooted taggedProto(cx, TaggedProto(proto)); return NewObject(cx, clasp, taggedProto, allocKind, newKind); } bool js::GetPrototypeFromConstructor(JSContext* cx, HandleObject newTarget, JSProtoKey intrinsicDefaultProto, MutableHandleObject proto) { RootedValue protov(cx); if (!GetProperty(cx, newTarget, newTarget, cx->names().prototype, &protov)) { return false; } if (protov.isObject()) { proto.set(&protov.toObject()); } else if (newTarget->is() && newTarget->as().realm() == cx->realm()) { // Steps 4.a-b fetch the builtin prototype of the current realm, which we // represent as nullptr. proto.set(nullptr); } else if (intrinsicDefaultProto == JSProto_Null) { // Bug 1317416. The caller did not pass a reasonable JSProtoKey, so let the // caller select a prototype object. Most likely they will choose one from // the wrong realm. proto.set(nullptr); } else { // Step 4.a: Let realm be ? GetFunctionRealm(constructor); Realm* realm = JS::GetFunctionRealm(cx, newTarget); if (!realm) { return false; } // Step 4.b: Set proto to realm's intrinsic object named // intrinsicDefaultProto. { Maybe ar; if (cx->realm() != realm) { ar.emplace(cx, realm->maybeGlobal()); } proto.set(GlobalObject::getOrCreatePrototype(cx, intrinsicDefaultProto)); } if (!proto) { return false; } if (!cx->compartment()->wrap(cx, proto)) { return false; } } return true; } /* static */ bool JSObject::nonNativeSetProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue v, HandleValue receiver, ObjectOpResult& result) { return obj->getOpsSetProperty()(cx, obj, id, v, receiver, result); } /* static */ bool JSObject::nonNativeSetElement(JSContext* cx, HandleObject obj, uint32_t index, HandleValue v, HandleValue receiver, ObjectOpResult& result) { RootedId id(cx); if (!IndexToId(cx, index, &id)) { return false; } return nonNativeSetProperty(cx, obj, id, v, receiver, result); } static bool CopyPropertyFrom(JSContext* cx, HandleId id, HandleObject target, HandleObject obj) { // |target| must not be a CCW because we need to enter its realm below and // CCWs are not associated with a single realm. MOZ_ASSERT(!IsCrossCompartmentWrapper(target)); // |obj| and |cx| are generally not same-compartment with |target| here. cx->check(obj, id); Rooted> desc(cx); if (!GetOwnPropertyDescriptor(cx, obj, id, &desc)) { return false; } MOZ_ASSERT(desc.isSome()); JSAutoRealm ar(cx, target); cx->markId(id); RootedId wrappedId(cx, id); if (!cx->compartment()->wrap(cx, &desc)) { return false; } Rooted desc_(cx, *desc); return DefineProperty(cx, target, wrappedId, desc_); } JS_PUBLIC_API bool JS_CopyOwnPropertiesAndPrivateFields(JSContext* cx, HandleObject target, HandleObject obj) { // Both |obj| and |target| must not be CCWs because we need to enter their // realms below and CCWs are not associated with a single realm. MOZ_ASSERT(!IsCrossCompartmentWrapper(obj)); MOZ_ASSERT(!IsCrossCompartmentWrapper(target)); JSAutoRealm ar(cx, obj); RootedIdVector props(cx); if (!GetPropertyKeys( cx, obj, JSITER_PRIVATE | JSITER_OWNONLY | JSITER_HIDDEN | JSITER_SYMBOLS, &props)) { return false; } for (size_t i = 0; i < props.length(); ++i) { if (!CopyPropertyFrom(cx, props[i], target, obj)) { return false; } } return true; } static bool InitializePropertiesFromCompatibleNativeObject( JSContext* cx, Handle dst, Handle src) { cx->check(src, dst); MOZ_ASSERT(src->getClass() == dst->getClass()); MOZ_ASSERT(dst->shape()->objectFlags().isEmpty()); MOZ_ASSERT(src->numFixedSlots() == dst->numFixedSlots()); MOZ_ASSERT(!src->inDictionaryMode()); MOZ_ASSERT(!dst->inDictionaryMode()); if (!dst->ensureElements(cx, src->getDenseInitializedLength())) { return false; } uint32_t initialized = src->getDenseInitializedLength(); for (uint32_t i = 0; i < initialized; ++i) { dst->setDenseInitializedLength(i + 1); dst->initDenseElement(i, src->getDenseElement(i)); } // If there are no properties to copy, we're done. if (!src->sharedShape()->propMap()) { return true; } Rooted shape(cx); if (src->staticPrototype() == dst->staticPrototype()) { shape = src->sharedShape(); } else { // We need to generate a new shape for dst that has dst's proto but all // the property information from src. Note that we asserted above that // dst's object flags are empty. SharedShape* srcShape = src->sharedShape(); ObjectFlags objFlags; objFlags = CopyPropMapObjectFlags(objFlags, srcShape->objectFlags()); Rooted map(cx, srcShape->propMap()); uint32_t mapLength = srcShape->propMapLength(); shape = SharedShape::getPropMapShape(cx, dst->shape()->base(), dst->numFixedSlots(), map, mapLength, objFlags); if (!shape) { return false; } } uint32_t oldSpan = dst->sharedShape()->slotSpan(); uint32_t newSpan = shape->slotSpan(); if (!dst->setShapeAndAddNewSlots(cx, shape, oldSpan, newSpan)) { return false; } for (size_t i = JSCLASS_RESERVED_SLOTS(src->getClass()); i < newSpan; i++) { dst->setSlot(i, src->getSlot(i)); } return true; } JS_PUBLIC_API bool JS_InitializePropertiesFromCompatibleNativeObject( JSContext* cx, HandleObject dst, HandleObject src) { return InitializePropertiesFromCompatibleNativeObject( cx, dst.as(), src.as()); } bool js::ObjectMayBeSwapped(const JSObject* obj) { const JSClass* clasp = obj->getClass(); // We want to optimize Window/globals and Gecko doesn't require transplanting // them (only the WindowProxy around them). A Window may be a DOMClass, so we // explicitly check if this is a global. if (clasp->isGlobal()) { return false; } // WindowProxy, Wrapper, DeadProxyObject, DOMProxy, and DOMClass (non-global) // types may be swapped. It is hard to detect DOMProxy from shell, so target // proxies in general. return clasp->isProxyObject() || clasp->isDOMClass(); } bool NativeObject::prepareForSwap(JSContext* cx, MutableHandleValueVector slotValuesOut) { MOZ_ASSERT(slotValuesOut.empty()); for (size_t i = 0; i < slotSpan(); i++) { if (!slotValuesOut.append(getSlot(i))) { return false; } } if (hasDynamicSlots()) { ObjectSlots* slotsHeader = getSlotsHeader(); size_t size = ObjectSlots::allocSize(slotsHeader->capacity()); RemoveCellMemory(this, size, MemoryUse::ObjectSlots); if (!cx->nursery().isInside(slotsHeader)) { if (!isTenured()) { cx->nursery().removeMallocedBuffer(slotsHeader, size); } js_free(slotsHeader); } setEmptyDynamicSlots(0); } if (hasDynamicElements()) { ObjectElements* elements = getElementsHeader(); void* allocatedElements = getUnshiftedElementsHeader(); size_t count = elements->numAllocatedElements(); size_t size = count * sizeof(HeapSlot); if (isTenured()) { RemoveCellMemory(this, size, MemoryUse::ObjectElements); } else if (cx->nursery().isInside(allocatedElements)) { // Move nursery allocated elements in case they end up in a tenured // object. ObjectElements* newElements = reinterpret_cast(js_pod_malloc(count)); if (!newElements) { return false; } memmove(newElements, elements, size); elements_ = newElements->elements(); } else { cx->nursery().removeMallocedBuffer(allocatedElements, size); } MOZ_ASSERT(hasDynamicElements()); } return true; } /* static */ bool NativeObject::fixupAfterSwap(JSContext* cx, Handle obj, gc::AllocKind kind, HandleValueVector slotValues) { // This object has just been swapped with some other object, and its shape // no longer reflects its allocated size. Correct this information and // fill the slots in with the specified values. MOZ_ASSERT_IF(!obj->inDictionaryMode(), obj->slotSpan() == slotValues.length()); // Make sure the shape's numFixedSlots() is correct. size_t nfixed = gc::GetGCKindSlots(kind); if (nfixed != obj->shape()->numFixedSlots()) { if (!NativeObject::changeNumFixedSlotsAfterSwap(cx, obj, nfixed)) { return false; } MOZ_ASSERT(obj->shape()->numFixedSlots() == nfixed); } uint32_t oldDictionarySlotSpan = obj->inDictionaryMode() ? slotValues.length() : 0; MOZ_ASSERT(!obj->hasUniqueId()); size_t ndynamic = calculateDynamicSlots(nfixed, slotValues.length(), obj->getClass()); size_t currentSlots = obj->getSlotsHeader()->capacity(); MOZ_ASSERT(ndynamic >= currentSlots); if (ndynamic > currentSlots) { if (!obj->growSlots(cx, currentSlots, ndynamic)) { return false; } } if (obj->inDictionaryMode()) { obj->setDictionaryModeSlotSpan(oldDictionarySlotSpan); } for (size_t i = 0, len = slotValues.length(); i < len; i++) { obj->initSlotUnchecked(i, slotValues[i]); } if (obj->hasDynamicElements()) { ObjectElements* elements = obj->getElementsHeader(); void* allocatedElements = obj->getUnshiftedElementsHeader(); MOZ_ASSERT(!cx->nursery().isInside(allocatedElements)); size_t size = elements->numAllocatedElements() * sizeof(HeapSlot); if (obj->isTenured()) { AddCellMemory(obj, size, MemoryUse::ObjectElements); } else if (!cx->nursery().registerMallocedBuffer(allocatedElements, size)) { return false; } } return true; } [[nodiscard]] bool ProxyObject::prepareForSwap( JSContext* cx, MutableHandleValueVector valuesOut) { MOZ_ASSERT(valuesOut.empty()); // Remove the GCPtrs we're about to swap from the store buffer, to // ensure we don't trace bogus values. gc::StoreBuffer& sb = cx->runtime()->gc.storeBuffer(); // Reserve space for the expando, private slot and the reserved slots. if (!valuesOut.reserve(2 + numReservedSlots())) { return false; } js::detail::ProxyValueArray* valArray = data.values(); sb.unputValue(&valArray->expandoSlot); sb.unputValue(&valArray->privateSlot); valuesOut.infallibleAppend(valArray->expandoSlot); valuesOut.infallibleAppend(valArray->privateSlot); for (size_t i = 0; i < numReservedSlots(); i++) { sb.unputValue(&valArray->reservedSlots.slots[i]); valuesOut.infallibleAppend(valArray->reservedSlots.slots[i]); } if (isTenured() && !usingInlineValueArray()) { size_t count = detail::ProxyValueArray::allocCount(numReservedSlots()); RemoveCellMemory(this, count * sizeof(Value), MemoryUse::ProxyExternalValueArray); js_free(valArray); data.reservedSlots = nullptr; } return true; } bool ProxyObject::fixupAfterSwap(JSContext* cx, const HandleValueVector values) { MOZ_ASSERT(getClass()->isProxyObject()); size_t nreserved = numReservedSlots(); // |values| contains the expando slot, private slot and the reserved slots. MOZ_ASSERT(values.length() == 2 + nreserved); // Allocate the external value array in malloc memory, even for nursery // proxies. size_t count = detail::ProxyValueArray::allocCount(nreserved); auto* allocation = js_pod_malloc(count); if (!allocation) { return false; } size_t size = count * sizeof(Value); if (isTenured()) { AddCellMemory(&asTenured(), size, MemoryUse::ProxyExternalValueArray); } else if (!cx->nursery().registerMallocedBuffer(allocation, size)) { js_free(allocation); return false; } auto* valArray = reinterpret_cast(allocation); valArray->expandoSlot = values[0]; valArray->privateSlot = values[1]; for (size_t i = 0; i < nreserved; i++) { valArray->reservedSlots.slots[i] = values[i + 2]; } data.reservedSlots = &valArray->reservedSlots; MOZ_ASSERT(!usingInlineValueArray()); return true; } static gc::AllocKind SwappableObjectAllocKind(JSObject* obj) { MOZ_ASSERT(ObjectMayBeSwapped(obj)); if (obj->isTenured()) { return obj->asTenured().getAllocKind(); } if (obj->is()) { return obj->as().allocKindForTenure(); } return obj->as().allocKindForTenure(); } /* Use this method with extreme caution. It trades the guts of two objects. */ void JSObject::swap(JSContext* cx, HandleObject a, HandleObject b, AutoEnterOOMUnsafeRegion& oomUnsafe) { // Ensure swap doesn't cause a finalizer to be run at the wrong time. MOZ_ASSERT(a->isBackgroundFinalized() == b->isBackgroundFinalized()); MOZ_ASSERT(a->compartment() == b->compartment()); // You must have entered the objects' compartment before calling this. MOZ_ASSERT(cx->compartment() == a->compartment()); // Only certain types of objects are allowed to be swapped. This allows the // JITs to better optimize objects that can never swap and rules out most // builtin objects that have special behaviour. MOZ_RELEASE_ASSERT(js::ObjectMayBeSwapped(a)); MOZ_RELEASE_ASSERT(js::ObjectMayBeSwapped(b)); if (!Watchtower::watchObjectSwap(cx, a, b)) { oomUnsafe.crash("watchObjectSwap"); } // Ensure we update any embedded nursery pointers in either object. gc::StoreBuffer& storeBuffer = cx->runtime()->gc.storeBuffer(); if (a->isTenured()) { storeBuffer.putWholeCell(a); } if (b->isTenured()) { storeBuffer.putWholeCell(b); } if (a->isTenured() || b->isTenured()) { if (a->zone()->wasGCStarted()) { storeBuffer.setMayHavePointersToDeadCells(); } } unsigned r = NotifyGCPreSwap(a, b); ProxyObject* pa = a->is() ? &a->as() : nullptr; ProxyObject* pb = b->is() ? &b->as() : nullptr; bool aIsProxyWithInlineValues = pa && pa->usingInlineValueArray(); bool bIsProxyWithInlineValues = pb && pb->usingInlineValueArray(); bool aIsUsedAsPrototype = a->isUsedAsPrototype(); bool bIsUsedAsPrototype = b->isUsedAsPrototype(); // Swap element associations. Zone* zone = a->zone(); // Record any associated unique IDs and prepare for swap. // // Note that unique IDs are NOT swapped but remain associated with the // original address. uint64_t aid = 0; uint64_t bid = 0; (void)gc::MaybeGetUniqueId(a, &aid); (void)gc::MaybeGetUniqueId(b, &bid); NativeObject* na = a->is() ? &a->as() : nullptr; NativeObject* nb = b->is() ? &b->as() : nullptr; if ((aid || bid) && (na || nb)) { // We can't remove unique IDs from native objects when they are swapped with // objects without an ID. Instead ensure they both have IDs so we always // have something to overwrite the old ID with. if (!gc::GetOrCreateUniqueId(a, &aid) || !gc::GetOrCreateUniqueId(b, &bid)) { oomUnsafe.crash("Failed to create unique ID during swap"); } // IDs stored in NativeObjects could shadow those stored in the zone // table. Remove any zone table IDs first. if (pa && aid) { gc::RemoveUniqueId(a); } if (pb && bid) { gc::RemoveUniqueId(b); } } gc::AllocKind ka = SwappableObjectAllocKind(a); gc::AllocKind kb = SwappableObjectAllocKind(b); size_t sa = gc::Arena::thingSize(ka); size_t sb = gc::Arena::thingSize(kb); if (sa == sb && a->isTenured() == b->isTenured()) { // When both objects are the same size and in the same heap, just do a plain // swap of their contents. // Swap slot associations. zone->swapCellMemory(a, b, MemoryUse::ObjectSlots); size_t size = sa; char tmp[sizeof(JSObject_Slots16)]; MOZ_ASSERT(size <= sizeof(tmp)); js_memcpy(tmp, a, size); js_memcpy(a, b, size); js_memcpy(b, tmp, size); zone->swapCellMemory(a, b, MemoryUse::ObjectElements); zone->swapCellMemory(a, b, MemoryUse::ProxyExternalValueArray); if (aIsProxyWithInlineValues) { b->as().setInlineValueArray(); } if (bIsProxyWithInlineValues) { a->as().setInlineValueArray(); } } else { // Avoid GC in here to avoid confusing the tracing code with our // intermediate state. gc::AutoSuppressGC suppress(cx); // When the objects have different sizes, they will have different numbers // of fixed slots before and after the swap, so the slots for native objects // will need to be rearranged. Remember the original values from the // objects. RootedValueVector avals(cx); RootedValueVector bvals(cx); if (na && !na->prepareForSwap(cx, &avals)) { oomUnsafe.crash("NativeObject::prepareForSwap"); } if (nb && !nb->prepareForSwap(cx, &bvals)) { oomUnsafe.crash("NativeObject::prepareForSwap"); } // Do the same for proxy value arrays. if (pa && !pa->prepareForSwap(cx, &avals)) { oomUnsafe.crash("ProxyObject::prepareForSwap"); } if (pb && !pb->prepareForSwap(cx, &bvals)) { oomUnsafe.crash("ProxyObject::prepareForSwap"); } // Swap the main fields of the objects, whether they are native objects or // proxies. char tmp[sizeof(JSObject_Slots0)]; js_memcpy(&tmp, a, sizeof tmp); js_memcpy(a, b, sizeof tmp); js_memcpy(b, &tmp, sizeof tmp); if (na && !NativeObject::fixupAfterSwap(cx, b.as(), kb, avals)) { oomUnsafe.crash("NativeObject::fixupAfterSwap"); } if (nb && !NativeObject::fixupAfterSwap(cx, a.as(), ka, bvals)) { oomUnsafe.crash("NativeObject::fixupAfterSwap"); } if (pa && !b->as().fixupAfterSwap(cx, avals)) { oomUnsafe.crash("ProxyObject::fixupAfterSwap"); } if (pb && !a->as().fixupAfterSwap(cx, bvals)) { oomUnsafe.crash("ProxyObject::fixupAfterSwap"); } } // Restore original unique IDs. if ((aid || bid) && (na || nb)) { if ((aid && !gc::SetOrUpdateUniqueId(cx, a, aid)) || (bid && !gc::SetOrUpdateUniqueId(cx, b, bid))) { oomUnsafe.crash("Failed to set unique ID after swap"); } } MOZ_ASSERT_IF(aid, gc::GetUniqueIdInfallible(a) == aid); MOZ_ASSERT_IF(bid, gc::GetUniqueIdInfallible(b) == bid); // Preserve the IsUsedAsPrototype flag on the objects. if (aIsUsedAsPrototype) { if (!JSObject::setIsUsedAsPrototype(cx, a)) { oomUnsafe.crash("setIsUsedAsPrototype"); } } if (bIsUsedAsPrototype) { if (!JSObject::setIsUsedAsPrototype(cx, b)) { oomUnsafe.crash("setIsUsedAsPrototype"); } } /* * We need a write barrier here. If |a| was marked and |b| was not, then * after the swap, |b|'s guts would never be marked. The write barrier * solves this. * * Normally write barriers happen before the write. However, that's not * necessary here because nothing is being destroyed. We're just swapping. */ PreWriteBarrier(zone, a.get(), [](JSTracer* trc, JSObject* obj) { obj->traceChildren(trc); }); PreWriteBarrier(zone, b.get(), [](JSTracer* trc, JSObject* obj) { obj->traceChildren(trc); }); NotifyGCPostSwap(a, b, r); } static NativeObject* DefineConstructorAndPrototype( JSContext* cx, HandleObject obj, Handle atom, HandleObject protoProto, const JSClass* clasp, Native constructor, unsigned nargs, const JSPropertySpec* ps, const JSFunctionSpec* fs, const JSPropertySpec* static_ps, const JSFunctionSpec* static_fs, NativeObject** ctorp) { // Create the prototype object. Rooted proto( cx, GlobalObject::createBlankPrototypeInheriting(cx, clasp, protoProto)); if (!proto) { return nullptr; } Rooted ctor(cx); if (!constructor) { ctor = proto; } else { ctor = NewNativeConstructor(cx, constructor, nargs, atom); if (!ctor) { return nullptr; } if (!LinkConstructorAndPrototype(cx, ctor, proto)) { return nullptr; } } if (!DefinePropertiesAndFunctions(cx, proto, ps, fs) || (ctor != proto && !DefinePropertiesAndFunctions(cx, ctor, static_ps, static_fs))) { return nullptr; } RootedId id(cx, AtomToId(atom)); RootedValue value(cx, ObjectValue(*ctor)); if (!DefineDataProperty(cx, obj, id, value, 0)) { return nullptr; } if (ctorp) { *ctorp = ctor; } return proto; } NativeObject* js::InitClass(JSContext* cx, HandleObject obj, const JSClass* protoClass, HandleObject protoProto_, const char* name, Native constructor, unsigned nargs, const JSPropertySpec* ps, const JSFunctionSpec* fs, const JSPropertySpec* static_ps, const JSFunctionSpec* static_fs, NativeObject** ctorp) { Rooted atom(cx, Atomize(cx, name, strlen(name))); if (!atom) { return nullptr; } /* * All instances of the class will inherit properties from the prototype * object we are about to create (in DefineConstructorAndPrototype), which * in turn will inherit from protoProto. * * If protoProto is nullptr, default to Object.prototype. * If protoClass is nullptr, default to PlainObject. */ RootedObject protoProto(cx, protoProto_); if (!protoProto) { protoProto = &cx->global()->getObjectPrototype(); } if (!protoClass) { protoClass = &PlainObject::class_; } return DefineConstructorAndPrototype(cx, obj, atom, protoProto, protoClass, constructor, nargs, ps, fs, static_ps, static_fs, ctorp); } /** * Returns the original Object.prototype from the embedding-provided incumbent * global. * * Really, we want the incumbent global itself so we can pass it to other * embedding hooks which need it. Specifically, the enqueue promise hook * takes an incumbent global so it can set that on the PromiseCallbackJob * it creates. * * The reason for not just returning the global itself is that we'd need to * wrap it into the current compartment, and later unwrap it. Unwrapping * globals is tricky, though: we might accidentally unwrap through an inner * to its outer window and end up with the wrong global. Plain objects don't * have this problem, so we use the global's Object.prototype. The code using * it - e.g. EnqueuePromiseReactionJob - can then unwrap the object and get * its global without fear of unwrapping too far. */ bool js::GetObjectFromIncumbentGlobal(JSContext* cx, MutableHandleObject obj) { Rooted globalObj(cx, cx->runtime()->getIncumbentGlobal(cx)); if (!globalObj) { obj.set(nullptr); return true; } obj.set(&globalObj->getObjectPrototype()); // The object might be from a different compartment, so wrap it. if (obj && !cx->compartment()->wrap(cx, obj)) { return false; } return true; } static bool IsStandardPrototype(JSObject* obj, JSProtoKey key) { return obj->nonCCWGlobal().maybeGetPrototype(key) == obj; } JSProtoKey JS::IdentifyStandardInstance(JSObject* obj) { // Note: The prototype shares its JSClass with instances. MOZ_ASSERT(!obj->is()); JSProtoKey key = StandardProtoKeyOrNull(obj); if (key != JSProto_Null && !IsStandardPrototype(obj, key)) { return key; } return JSProto_Null; } JSProtoKey JS::IdentifyStandardPrototype(JSObject* obj) { // Note: The prototype shares its JSClass with instances. MOZ_ASSERT(!obj->is()); JSProtoKey key = StandardProtoKeyOrNull(obj); if (key != JSProto_Null && IsStandardPrototype(obj, key)) { return key; } return JSProto_Null; } JSProtoKey JS::IdentifyStandardInstanceOrPrototype(JSObject* obj) { return StandardProtoKeyOrNull(obj); } JSProtoKey JS::IdentifyStandardConstructor(JSObject* obj) { // Note that isNativeConstructor does not imply that we are a standard // constructor, but the converse is true (at least until we start having // self-hosted constructors for standard classes). This lets us avoid a costly // loop for many functions (which, depending on the call site, may be the // common case). if (!obj->is() || !(obj->as().flags().isNativeConstructor())) { return JSProto_Null; } static_assert(JSProto_Null == 0, "Loop below can start at 1 to skip JSProto_Null"); GlobalObject& global = obj->as().global(); for (size_t k = 1; k < JSProto_LIMIT; ++k) { JSProtoKey key = static_cast(k); if (global.maybeGetConstructor(key) == obj) { return key; } } return JSProto_Null; } bool js::LookupProperty(JSContext* cx, HandleObject obj, js::HandleId id, MutableHandleObject objp, PropertyResult* propp) { if (LookupPropertyOp op = obj->getOpsLookupProperty()) { return op(cx, obj, id, objp, propp); } return NativeLookupPropertyInline(cx, obj.as(), id, objp, propp); } bool js::LookupName(JSContext* cx, Handle name, HandleObject envChain, MutableHandleObject objp, MutableHandleObject pobjp, PropertyResult* propp) { RootedId id(cx, NameToId(name)); for (RootedObject env(cx, envChain); env; env = env->enclosingEnvironment()) { if (!LookupProperty(cx, env, id, pobjp, propp)) { return false; } if (propp->isFound()) { objp.set(env); return true; } } objp.set(nullptr); pobjp.set(nullptr); propp->setNotFound(); return true; } bool js::LookupNameNoGC(JSContext* cx, PropertyName* name, JSObject* envChain, JSObject** objp, NativeObject** pobjp, PropertyResult* propp) { AutoAssertNoPendingException nogc(cx); MOZ_ASSERT(!*objp && !*pobjp && propp->isNotFound()); for (JSObject* env = envChain; env; env = env->enclosingEnvironment()) { if (env->getOpsLookupProperty()) { return false; } if (!NativeLookupPropertyInline(cx, &env->as(), NameToId(name), pobjp, propp)) { return false; } if (propp->isFound()) { *objp = env; return true; } } return true; } bool js::LookupNameWithGlobalDefault(JSContext* cx, Handle name, HandleObject envChain, MutableHandleObject objp) { RootedId id(cx, NameToId(name)); RootedObject pobj(cx); PropertyResult prop; RootedObject env(cx, envChain); for (; !env->is(); env = env->enclosingEnvironment()) { if (!LookupProperty(cx, env, id, &pobj, &prop)) { return false; } if (prop.isFound()) { break; } } objp.set(env); return true; } bool js::LookupNameUnqualified(JSContext* cx, Handle name, HandleObject envChain, MutableHandleObject objp) { RootedId id(cx, NameToId(name)); RootedObject pobj(cx); PropertyResult prop; RootedObject env(cx, envChain); for (; !env->isUnqualifiedVarObj(); env = env->enclosingEnvironment()) { if (!LookupProperty(cx, env, id, &pobj, &prop)) { return false; } if (prop.isFound()) { break; } } // See note above RuntimeLexicalErrorObject. if (pobj == env) { bool isTDZ = false; if (prop.isFound() && name != cx->names().dotThis) { // Treat Debugger environments specially for TDZ checks, as they // look like non-native environments but in fact wrap native // environments. if (env->is()) { RootedValue v(cx); Rooted envProxy( cx, &env->as()); if (!DebugEnvironmentProxy::getMaybeSentinelValue(cx, envProxy, id, &v)) { return false; } isTDZ = IsUninitializedLexical(v); } else { isTDZ = IsUninitializedLexicalSlot(env, prop); } } if (isTDZ) { env = RuntimeLexicalErrorObject::create(cx, env, JSMSG_UNINITIALIZED_LEXICAL); if (!env) { return false; } } else if (env->is() && !prop.propertyInfo().writable()) { // Assigning to a named lambda callee name is a no-op in sloppy mode. if (!(env->is() && env->as().scope().kind() == ScopeKind::NamedLambda)) { MOZ_ASSERT(name != cx->names().dotThis); env = RuntimeLexicalErrorObject::create(cx, env, JSMSG_BAD_CONST_ASSIGN); if (!env) { return false; } } } } objp.set(env); return true; } bool js::HasOwnProperty(JSContext* cx, HandleObject obj, HandleId id, bool* result) { if (obj->is()) { return Proxy::hasOwn(cx, obj, id, result); } if (GetOwnPropertyOp op = obj->getOpsGetOwnPropertyDescriptor()) { Rooted> desc(cx); if (!op(cx, obj, id, &desc)) { return false; } *result = desc.isSome(); return true; } PropertyResult prop; if (!NativeLookupOwnProperty(cx, obj.as(), id, &prop)) { return false; } *result = prop.isFound(); return true; } bool js::LookupPropertyPure(JSContext* cx, JSObject* obj, jsid id, NativeObject** objp, PropertyResult* propp) { if (obj->getOpsLookupProperty()) { return false; } return NativeLookupPropertyInline( cx, &obj->as(), id, objp, propp); } bool js::LookupOwnPropertyPure(JSContext* cx, JSObject* obj, jsid id, PropertyResult* propp) { if (obj->getOpsLookupProperty()) { return false; } return NativeLookupOwnPropertyInline( cx, &obj->as(), id, propp); } static inline bool NativeGetPureInline(NativeObject* pobj, jsid id, PropertyResult prop, Value* vp, JSContext* cx) { if (prop.isDenseElement()) { *vp = pobj->getDenseElement(prop.denseElementIndex()); return true; } if (prop.isTypedArrayElement()) { size_t idx = prop.typedArrayElementIndex(); return pobj->as().getElement(cx, idx, vp); } // Fail if we have a custom getter. PropertyInfo propInfo = prop.propertyInfo(); if (!propInfo.isDataProperty()) { return false; } *vp = pobj->getSlot(propInfo.slot()); MOZ_ASSERT(!vp->isMagic()); return true; } bool js::GetPropertyPure(JSContext* cx, JSObject* obj, jsid id, Value* vp) { NativeObject* pobj; PropertyResult prop; if (!LookupPropertyPure(cx, obj, id, &pobj, &prop)) { return false; } if (prop.isNotFound()) { vp->setUndefined(); return true; } return NativeGetPureInline(pobj, id, prop, vp, cx); } bool js::GetOwnPropertyPure(JSContext* cx, JSObject* obj, jsid id, Value* vp, bool* found) { PropertyResult prop; if (!LookupOwnPropertyPure(cx, obj, id, &prop)) { return false; } if (prop.isNotFound()) { *found = false; vp->setUndefined(); return true; } *found = true; return obj->is() && NativeGetPureInline(&obj->as(), id, prop, vp, cx); } static inline bool NativeGetGetterPureInline(NativeObject* holder, PropertyResult prop, JSFunction** fp) { MOZ_ASSERT(prop.isNativeProperty()); PropertyInfo propInfo = prop.propertyInfo(); if (holder->hasGetter(propInfo)) { JSObject* getter = holder->getGetter(propInfo); if (getter->is()) { *fp = &getter->as(); return true; } } *fp = nullptr; return true; } bool js::GetGetterPure(JSContext* cx, JSObject* obj, jsid id, JSFunction** fp) { /* Just like GetPropertyPure, but get getter function, without invoking * it. */ NativeObject* pobj; PropertyResult prop; if (!LookupPropertyPure(cx, obj, id, &pobj, &prop)) { return false; } if (prop.isNotFound()) { *fp = nullptr; return true; } return prop.isNativeProperty() && NativeGetGetterPureInline(pobj, prop, fp); } bool js::GetOwnGetterPure(JSContext* cx, JSObject* obj, jsid id, JSFunction** fp) { JS::AutoCheckCannotGC nogc; PropertyResult prop; if (!LookupOwnPropertyPure(cx, obj, id, &prop)) { return false; } if (prop.isNotFound()) { *fp = nullptr; return true; } return prop.isNativeProperty() && NativeGetGetterPureInline(&obj->as(), prop, fp); } bool js::GetOwnNativeGetterPure(JSContext* cx, JSObject* obj, jsid id, JSNative* native) { JS::AutoCheckCannotGC nogc; *native = nullptr; PropertyResult prop; if (!LookupOwnPropertyPure(cx, obj, id, &prop)) { return false; } if (!prop.isNativeProperty()) { return true; } PropertyInfo propInfo = prop.propertyInfo(); NativeObject* nobj = &obj->as(); if (!nobj->hasGetter(propInfo)) { return true; } JSObject* getterObj = nobj->getGetter(propInfo); if (!getterObj->is()) { return true; } JSFunction* getter = &getterObj->as(); if (!getter->isNativeFun()) { return true; } *native = getter->native(); return true; } bool js::HasOwnDataPropertyPure(JSContext* cx, JSObject* obj, jsid id, bool* result) { PropertyResult prop; if (!LookupOwnPropertyPure(cx, obj, id, &prop)) { return false; } *result = prop.isNativeProperty() && prop.propertyInfo().isDataProperty(); return true; } bool js::GetPrototypeIfOrdinary(JSContext* cx, HandleObject obj, bool* isOrdinary, MutableHandleObject protop) { if (obj->is()) { return js::Proxy::getPrototypeIfOrdinary(cx, obj, isOrdinary, protop); } *isOrdinary = true; protop.set(obj->staticPrototype()); return true; } /*** ES6 standard internal methods ******************************************/ bool js::SetPrototype(JSContext* cx, HandleObject obj, HandleObject proto, JS::ObjectOpResult& result) { // The proxy trap subsystem fully handles prototype-setting for proxies // with dynamic [[Prototype]]s. if (obj->hasDynamicPrototype()) { MOZ_ASSERT(obj->is()); return Proxy::setPrototype(cx, obj, proto, result); } /* * ES6 9.1.2 step 3-4 if |obj.[[Prototype]]| has SameValue as |proto| return * true. Since the values in question are objects, we can just compare * pointers. */ if (proto == obj->staticPrototype()) { return result.succeed(); } /* Disallow mutation of immutable [[Prototype]]s. */ if (obj->staticPrototypeIsImmutable()) { return result.fail(JSMSG_CANT_SET_PROTO); } /* * Disallow mutating the [[Prototype]] on Typed Objects, per the spec. */ if (obj->is()) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_CANT_SET_PROTO_OF, "incompatible WebAssembly object"); return false; } /* ES6 9.1.2 step 5 forbids changing [[Prototype]] if not [[Extensible]]. */ bool extensible; if (!IsExtensible(cx, obj, &extensible)) { return false; } if (!extensible) { return result.fail(JSMSG_CANT_SET_PROTO); } /* * ES6 9.1.2 step 6 forbids generating cyclical prototype chains. But we * have to do this comparison on the observable WindowProxy, not on the * possibly-Window object we're setting the proto on. */ RootedObject objMaybeWindowProxy(cx, ToWindowProxyIfWindow(obj)); RootedObject obj2(cx, proto); while (obj2) { MOZ_ASSERT(!IsWindow(obj2)); if (obj2 == objMaybeWindowProxy) { return result.fail(JSMSG_CANT_SET_PROTO_CYCLE); } bool isOrdinary; if (!GetPrototypeIfOrdinary(cx, obj2, &isOrdinary, &obj2)) { return false; } if (!isOrdinary) { break; } } Rooted taggedProto(cx, TaggedProto(proto)); if (!JSObject::setProtoUnchecked(cx, obj, taggedProto)) { return false; } return result.succeed(); } bool js::SetPrototype(JSContext* cx, HandleObject obj, HandleObject proto) { ObjectOpResult result; return SetPrototype(cx, obj, proto, result) && result.checkStrict(cx, obj); } bool js::PreventExtensions(JSContext* cx, HandleObject obj, ObjectOpResult& result) { if (obj->is()) { return js::Proxy::preventExtensions(cx, obj, result); } if (!obj->nonProxyIsExtensible()) { // If the following assertion fails, there's somewhere else a missing // call to shrinkCapacityToInitializedLength() which needs to be found // and fixed. MOZ_ASSERT_IF(obj->is(), obj->as().getDenseInitializedLength() == obj->as().getDenseCapacity()); return result.succeed(); } if (obj->is()) { // Force lazy properties to be resolved. Handle nobj = obj.as(); if (!ResolveLazyProperties(cx, nobj)) { return false; } // Prepare the elements. We have to do this before we mark the object // non-extensible; that's fine because these changes are not observable. ObjectElements::PrepareForPreventExtensions(cx, nobj); } // Finally, set the NotExtensible flag on the Shape and ObjectElements. if (!JSObject::setFlag(cx, obj, ObjectFlag::NotExtensible)) { return false; } if (obj->is()) { ObjectElements::PreventExtensions(&obj->as()); } return result.succeed(); } bool js::PreventExtensions(JSContext* cx, HandleObject obj) { ObjectOpResult result; return PreventExtensions(cx, obj, result) && result.checkStrict(cx, obj); } bool js::GetOwnPropertyDescriptor( JSContext* cx, HandleObject obj, HandleId id, MutableHandle> desc) { if (GetOwnPropertyOp op = obj->getOpsGetOwnPropertyDescriptor()) { bool ok = op(cx, obj, id, desc); if (ok && desc.isSome()) { desc->assertComplete(); } return ok; } return NativeGetOwnPropertyDescriptor(cx, obj.as(), id, desc); } bool js::DefineProperty(JSContext* cx, HandleObject obj, HandleId id, Handle desc) { ObjectOpResult result; return DefineProperty(cx, obj, id, desc, result) && result.checkStrict(cx, obj, id); } bool js::DefineProperty(JSContext* cx, HandleObject obj, HandleId id, Handle desc, ObjectOpResult& result) { desc.assertValid(); if (DefinePropertyOp op = obj->getOpsDefineProperty()) { return op(cx, obj, id, desc, result); } return NativeDefineProperty(cx, obj.as(), id, desc, result); } bool js::DefineAccessorProperty(JSContext* cx, HandleObject obj, HandleId id, HandleObject getter, HandleObject setter, unsigned attrs, ObjectOpResult& result) { Rooted desc( cx, PropertyDescriptor::Accessor( getter ? mozilla::Some(getter) : mozilla::Nothing(), setter ? mozilla::Some(setter) : mozilla::Nothing(), attrs)); if (DefinePropertyOp op = obj->getOpsDefineProperty()) { MOZ_ASSERT(!cx->isHelperThreadContext()); return op(cx, obj, id, desc, result); } return NativeDefineProperty(cx, obj.as(), id, desc, result); } bool js::DefineDataProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue value, unsigned attrs, ObjectOpResult& result) { Rooted desc(cx, PropertyDescriptor::Data(value, attrs)); if (DefinePropertyOp op = obj->getOpsDefineProperty()) { MOZ_ASSERT(!cx->isHelperThreadContext()); return op(cx, obj, id, desc, result); } return NativeDefineProperty(cx, obj.as(), id, desc, result); } bool js::DefineAccessorProperty(JSContext* cx, HandleObject obj, HandleId id, HandleObject getter, HandleObject setter, unsigned attrs) { ObjectOpResult result; if (!DefineAccessorProperty(cx, obj, id, getter, setter, attrs, result)) { return false; } if (!result) { MOZ_ASSERT(!cx->isHelperThreadContext()); result.reportError(cx, obj, id); return false; } return true; } bool js::DefineDataProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue value, unsigned attrs) { ObjectOpResult result; if (!DefineDataProperty(cx, obj, id, value, attrs, result)) { return false; } if (!result) { MOZ_ASSERT(!cx->isHelperThreadContext()); result.reportError(cx, obj, id); return false; } return true; } bool js::DefineDataProperty(JSContext* cx, HandleObject obj, PropertyName* name, HandleValue value, unsigned attrs) { RootedId id(cx, NameToId(name)); return DefineDataProperty(cx, obj, id, value, attrs); } bool js::DefineDataElement(JSContext* cx, HandleObject obj, uint32_t index, HandleValue value, unsigned attrs) { RootedId id(cx); if (!IndexToId(cx, index, &id)) { return false; } return DefineDataProperty(cx, obj, id, value, attrs); } /*** SpiderMonkey nonstandard internal methods ******************************/ // Mark an object as having an immutable prototype // // NOTE: This does not correspond to the SetImmutablePrototype ECMAScript // method. bool js::SetImmutablePrototype(JSContext* cx, HandleObject obj, bool* succeeded) { if (obj->hasDynamicPrototype()) { MOZ_ASSERT(!cx->isHelperThreadContext()); return Proxy::setImmutablePrototype(cx, obj, succeeded); } if (!JSObject::setFlag(cx, obj, ObjectFlag::ImmutablePrototype)) { return false; } *succeeded = true; return true; } bool js::GetPropertyDescriptor( JSContext* cx, HandleObject obj, HandleId id, MutableHandle> desc, MutableHandleObject holder) { RootedObject pobj(cx); for (pobj = obj; pobj;) { if (!GetOwnPropertyDescriptor(cx, pobj, id, desc)) { return false; } if (desc.isSome()) { holder.set(pobj); return true; } if (!GetPrototype(cx, pobj, &pobj)) { return false; } } MOZ_ASSERT(desc.isNothing()); holder.set(nullptr); return true; } /* * */ extern bool PropertySpecNameToId(JSContext* cx, JSPropertySpec::Name name, MutableHandleId id); // If a property or method is part of an experimental feature that can be // disabled at run-time by a preference, we keep it in the JSFunctionSpec / // JSPropertySpec list, but omit the definition if the preference is off. JS_PUBLIC_API bool js::ShouldIgnorePropertyDefinition(JSContext* cx, JSProtoKey key, jsid id) { if (!cx->realm()->creationOptions().getToSourceEnabled() && (id == NameToId(cx->names().toSource) || id == NameToId(cx->names().uneval))) { return true; } if (key == JSProto_FinalizationRegistry && cx->realm()->creationOptions().getWeakRefsEnabled() == JS::WeakRefSpecifier::EnabledWithoutCleanupSome && id == NameToId(cx->names().cleanupSome)) { return true; } #ifdef NIGHTLY_BUILD if (key == JSProto_Array && !cx->realm()->creationOptions().getArrayGroupingEnabled() && (id == NameToId(cx->names().group) || id == NameToId(cx->names().groupToMap))) { return true; } #endif // It's gently surprising that this is JSProto_Function, but the trick // to realize is that this is a -constructor function-, not a function // on the prototype; and the proto of the constructor is JSProto_Function. if (key == JSProto_Function && !cx->realm()->creationOptions().getArrayFromAsyncEnabled() && id == NameToId(cx->names().fromAsync)) { return true; } if (key == JSProto_Array && !cx->realm()->creationOptions().getChangeArrayByCopyEnabled() && (id == NameToId(cx->names().with) || id == NameToId(cx->names().toReversed) || id == NameToId(cx->names().toSorted) || id == NameToId(cx->names().toSpliced))) { return true; } if (key == JSProto_TypedArray && !cx->realm()->creationOptions().getChangeArrayByCopyEnabled() && (id == NameToId(cx->names().with) || id == NameToId(cx->names().toReversed) || id == NameToId(cx->names().toSorted))) { return true; } #ifdef ENABLE_NEW_SET_METHODS if (key == JSProto_Set && !cx->realm()->creationOptions().getNewSetMethodsEnabled() && (id == NameToId(cx->names().union_) || id == NameToId(cx->names().difference) || id == NameToId(cx->names().intersection) || id == NameToId(cx->names().isSubsetOf) || id == NameToId(cx->names().isSupersetOf) || id == NameToId(cx->names().isDisjointFrom) || id == NameToId(cx->names().symmetricDifference))) { return true; } #endif return false; } static bool DefineFunctionFromSpec(JSContext* cx, HandleObject obj, const JSFunctionSpec* fs) { RootedId id(cx); if (!PropertySpecNameToId(cx, fs->name, &id)) { return false; } if (ShouldIgnorePropertyDefinition(cx, StandardProtoKeyOrNull(obj), id)) { return true; } JSFunction* fun = NewFunctionFromSpec(cx, fs, id); if (!fun) { return false; } RootedValue funVal(cx, ObjectValue(*fun)); return DefineDataProperty(cx, obj, id, funVal, fs->flags & ~JSFUN_FLAGS_MASK); } bool js::DefineFunctions(JSContext* cx, HandleObject obj, const JSFunctionSpec* fs) { for (; fs->name; fs++) { if (!DefineFunctionFromSpec(cx, obj, fs)) { return false; } } return true; } /*** ToPrimitive ************************************************************/ /* * Gets |obj[id]|. If that value's not callable, returns true and stores an * object value in *vp. If it's callable, calls it with no arguments and |obj| * as |this|, returning the result in *vp. * * This is a mini-abstraction for ES6 draft rev 36 (2015 Mar 17), * 7.1.1, second algorithm (OrdinaryToPrimitive), steps 5.a-c. */ static bool MaybeCallMethod(JSContext* cx, HandleObject obj, HandleId id, MutableHandleValue vp) { if (!GetProperty(cx, obj, obj, id, vp)) { return false; } if (!IsCallable(vp)) { vp.setObject(*obj); return true; } return js::Call(cx, vp, obj, vp); } static bool ReportCantConvert(JSContext* cx, unsigned errorNumber, HandleObject obj, JSType hint) { const JSClass* clasp = obj->getClass(); // Avoid recursive death when decompiling in ReportValueError. RootedString str(cx); if (hint == JSTYPE_STRING) { str = JS_AtomizeString(cx, clasp->name); if (!str) { return false; } } else { str = nullptr; } RootedValue val(cx, ObjectValue(*obj)); ReportValueError(cx, errorNumber, JSDVG_SEARCH_STACK, val, str, hint == JSTYPE_UNDEFINED ? "primitive type" : hint == JSTYPE_STRING ? "string" : "number"); return false; } bool JS::OrdinaryToPrimitive(JSContext* cx, HandleObject obj, JSType hint, MutableHandleValue vp) { MOZ_ASSERT(hint == JSTYPE_NUMBER || hint == JSTYPE_STRING || hint == JSTYPE_UNDEFINED); Rooted id(cx); const JSClass* clasp = obj->getClass(); if (hint == JSTYPE_STRING) { id = NameToId(cx->names().toString); bool calledToString = false; if (clasp == &StringObject::class_) { // Optimize (new String(...)).toString(). StringObject* nobj = &obj->as(); if (HasNativeMethodPure(nobj, cx->names().toString, str_toString, cx)) { vp.setString(nobj->unbox()); return true; } } else if (clasp == &PlainObject::class_) { JSFunction* fun; if (GetPropertyPure(cx, obj, id, vp.address()) && IsFunctionObject(vp, &fun)) { // Common case: we have a toString function. Try to short-circuit if // it's Object.prototype.toString and there's no @@toStringTag. if (fun->maybeNative() == obj_toString && !MaybeHasInterestingSymbolProperty( cx, obj, cx->wellKnownSymbols().toStringTag)) { vp.setString(cx->names().objectObject); return true; } if (!js::Call(cx, vp, obj, vp)) { return false; } calledToString = true; } } if (!calledToString) { if (!MaybeCallMethod(cx, obj, id, vp)) { return false; } } if (vp.isPrimitive()) { return true; } id = NameToId(cx->names().valueOf); if (!MaybeCallMethod(cx, obj, id, vp)) { return false; } if (vp.isPrimitive()) { return true; } } else { id = NameToId(cx->names().valueOf); if (clasp == &StringObject::class_) { // Optimize new String(...).valueOf(). StringObject* nobj = &obj->as(); if (HasNativeMethodPure(nobj, cx->names().valueOf, str_toString, cx)) { vp.setString(nobj->unbox()); return true; } } else if (clasp == &NumberObject::class_) { // Optimize new Number(...).valueOf(). NumberObject* nobj = &obj->as(); if (HasNativeMethodPure(nobj, cx->names().valueOf, num_valueOf, cx)) { vp.setNumber(nobj->unbox()); return true; } } if (!MaybeCallMethod(cx, obj, id, vp)) { return false; } if (vp.isPrimitive()) { return true; } id = NameToId(cx->names().toString); if (!MaybeCallMethod(cx, obj, id, vp)) { return false; } if (vp.isPrimitive()) { return true; } } return ReportCantConvert(cx, JSMSG_CANT_CONVERT_TO, obj, hint); } bool js::ToPrimitiveSlow(JSContext* cx, JSType preferredType, MutableHandleValue vp) { // Step numbers refer to the first algorithm listed in ES6 draft rev 36 // (2015 Mar 17) 7.1.1 ToPrimitive. MOZ_ASSERT(preferredType == JSTYPE_UNDEFINED || preferredType == JSTYPE_STRING || preferredType == JSTYPE_NUMBER); RootedObject obj(cx, &vp.toObject()); // Steps 4-5. RootedValue method(cx); if (!GetInterestingSymbolProperty(cx, obj, cx->wellKnownSymbols().toPrimitive, &method)) { return false; } // Step 6. if (!method.isNullOrUndefined()) { // Step 6 of GetMethod. js::Call() below would do this check and throw a // TypeError anyway, but this produces a better error message. if (!IsCallable(method)) { return ReportCantConvert(cx, JSMSG_TOPRIMITIVE_NOT_CALLABLE, obj, preferredType); } // Steps 1-3, 6.a-b. RootedValue arg0( cx, StringValue(preferredType == JSTYPE_STRING ? cx->names().string : preferredType == JSTYPE_NUMBER ? cx->names().number : cx->names().default_)); if (!js::Call(cx, method, vp, arg0, vp)) { return false; } // Steps 6.c-d. if (vp.isObject()) { return ReportCantConvert(cx, JSMSG_TOPRIMITIVE_RETURNED_OBJECT, obj, preferredType); } return true; } return OrdinaryToPrimitive(cx, obj, preferredType, vp); } /* ES6 draft rev 28 (2014 Oct 14) 7.1.14 */ bool js::ToPropertyKeySlow(JSContext* cx, HandleValue argument, MutableHandleId result) { MOZ_ASSERT(argument.isObject()); // Steps 1-2. RootedValue key(cx, argument); if (!ToPrimitiveSlow(cx, JSTYPE_STRING, &key)) { return false; } // Steps 3-4. return PrimitiveValueToId(cx, key, result); } /* * */ bool js::IsPrototypeOf(JSContext* cx, HandleObject protoObj, JSObject* obj, bool* result) { RootedObject obj2(cx, obj); for (;;) { // The [[Prototype]] chain might be cyclic. if (!CheckForInterrupt(cx)) { return false; } if (!GetPrototype(cx, obj2, &obj2)) { return false; } if (!obj2) { *result = false; return true; } if (obj2 == protoObj) { *result = true; return true; } } } JSObject* js::PrimitiveToObject(JSContext* cx, const Value& v) { MOZ_ASSERT(v.isPrimitive()); switch (v.type()) { case ValueType::String: { Rooted str(cx, v.toString()); return StringObject::create(cx, str); } case ValueType::Double: case ValueType::Int32: return NumberObject::create(cx, v.toNumber()); case ValueType::Boolean: return BooleanObject::create(cx, v.toBoolean()); case ValueType::Symbol: { RootedSymbol symbol(cx, v.toSymbol()); return SymbolObject::create(cx, symbol); } case ValueType::BigInt: { RootedBigInt bigInt(cx, v.toBigInt()); return BigIntObject::create(cx, bigInt); } #ifdef ENABLE_RECORD_TUPLE case ValueType::ExtendedPrimitive: { JSObject& obj = v.toExtendedPrimitive(); if (obj.is()) { Rooted rec(cx, &obj.as()); return RecordObject::create(cx, rec); } if (obj.is()) { Rooted tuple(cx, &obj.as()); return TupleObject::create(cx, tuple); } MOZ_CRASH("Unexpected ExtendedPrimitive type."); } #endif case ValueType::Undefined: case ValueType::Null: case ValueType::Magic: case ValueType::PrivateGCThing: case ValueType::Object: break; } MOZ_CRASH("unexpected type"); } // Like PrimitiveToObject, but returns the JSProtoKey of the prototype that // would be used without actually creating the object. JSProtoKey js::PrimitiveToProtoKey(JSContext* cx, const Value& v) { MOZ_ASSERT(v.isPrimitive()); switch (v.type()) { case ValueType::String: return JSProto_String; case ValueType::Double: case ValueType::Int32: return JSProto_Number; case ValueType::Boolean: return JSProto_Boolean; case ValueType::Symbol: return JSProto_Symbol; case ValueType::BigInt: return JSProto_BigInt; #ifdef ENABLE_RECORD_TUPLE case ValueType::ExtendedPrimitive: if (v.toExtendedPrimitive().is()) { return JSProto_Tuple; } if (v.toExtendedPrimitive().is()) { return JSProto_Null; } MOZ_CRASH("Unsupported ExtendedPrimitive"); #endif case ValueType::Undefined: case ValueType::Null: case ValueType::Magic: case ValueType::PrivateGCThing: case ValueType::Object: break; } MOZ_CRASH("unexpected type"); } /* * Invokes the ES5 ToObject algorithm on vp, returning the result. If vp might * already be an object, use ToObject. reportScanStack controls how null and * undefined errors are reported. * * Callers must handle the already-object case. */ JSObject* js::ToObjectSlow(JSContext* cx, JS::HandleValue val, bool reportScanStack) { MOZ_ASSERT(!val.isMagic()); MOZ_ASSERT(!val.isObject()); if (val.isNullOrUndefined()) { ReportIsNullOrUndefinedForPropertyAccess( cx, val, reportScanStack ? JSDVG_SEARCH_STACK : JSDVG_IGNORE_STACK); return nullptr; } return PrimitiveToObject(cx, val); } JSObject* js::ToObjectSlowForPropertyAccess(JSContext* cx, JS::HandleValue val, int valIndex, HandleId key) { MOZ_ASSERT(!val.isMagic()); MOZ_ASSERT(!val.isObject()); if (val.isNullOrUndefined()) { ReportIsNullOrUndefinedForPropertyAccess(cx, val, valIndex, key); return nullptr; } return PrimitiveToObject(cx, val); } JSObject* js::ToObjectSlowForPropertyAccess(JSContext* cx, JS::HandleValue val, int valIndex, Handle key) { MOZ_ASSERT(!val.isMagic()); MOZ_ASSERT(!val.isObject()); if (val.isNullOrUndefined()) { RootedId keyId(cx, NameToId(key)); ReportIsNullOrUndefinedForPropertyAccess(cx, val, valIndex, keyId); return nullptr; } return PrimitiveToObject(cx, val); } JSObject* js::ToObjectSlowForPropertyAccess(JSContext* cx, JS::HandleValue val, int valIndex, HandleValue keyValue) { MOZ_ASSERT(!val.isMagic()); MOZ_ASSERT(!val.isObject()); if (val.isNullOrUndefined()) { RootedId key(cx); if (keyValue.isPrimitive()) { if (!PrimitiveValueToId(cx, keyValue, &key)) { return nullptr; } ReportIsNullOrUndefinedForPropertyAccess(cx, val, valIndex, key); } else { ReportIsNullOrUndefinedForPropertyAccess(cx, val, valIndex); } return nullptr; } return PrimitiveToObject(cx, val); } JSObject* js::GetThisObject(JSObject* obj) { // Use the WindowProxy if the global is a Window, as Window must never be // exposed to script. if (obj->is()) { return ToWindowProxyIfWindow(obj); } // We should not expose any environments except NSVOs to script. The NSVO is // pretending to be the global object in this case. MOZ_ASSERT(obj->is() || !obj->is()); return obj; } JSObject* js::GetThisObjectOfLexical(JSObject* env) { return env->as().thisObject(); } JSObject* js::GetThisObjectOfWith(JSObject* env) { MOZ_ASSERT(env->is()); return GetThisObject(env->as().withThis()); } class GetObjectSlotNameFunctor : public JS::TracingContext::Functor { JSObject* obj; public: explicit GetObjectSlotNameFunctor(JSObject* ctx) : obj(ctx) {} virtual void operator()(JS::TracingContext* trc, char* buf, size_t bufsize) override; }; void GetObjectSlotNameFunctor::operator()(JS::TracingContext* tcx, char* buf, size_t bufsize) { MOZ_ASSERT(tcx->index() != JS::TracingContext::InvalidIndex); uint32_t slot = uint32_t(tcx->index()); Maybe key; if (obj->is()) { NativeShape* shape = obj->as().shape(); for (ShapePropertyIter iter(shape); !iter.done(); iter++) { if (iter->hasSlot() && iter->slot() == slot) { key.emplace(iter->key()); break; } } } if (key.isNothing()) { do { const char* slotname = nullptr; const char* pattern = nullptr; if (obj->is()) { pattern = "CLASS_OBJECT(%s)"; if (false) { ; } #define TEST_SLOT_MATCHES_PROTOTYPE(name, clasp) \ else if ((JSProto_##name) == slot) { \ slotname = js_##name##_str; \ } JS_FOR_EACH_PROTOTYPE(TEST_SLOT_MATCHES_PROTOTYPE) #undef TEST_SLOT_MATCHES_PROTOTYPE } else { pattern = "%s"; if (obj->is()) { if (slot == EnvironmentObject::enclosingEnvironmentSlot()) { slotname = "enclosing_environment"; } else if (obj->is()) { if (slot == CallObject::calleeSlot()) { slotname = "callee_slot"; } } else if (obj->is()) { if (slot == WithEnvironmentObject::objectSlot()) { slotname = "with_object"; } else if (slot == WithEnvironmentObject::thisSlot()) { slotname = "with_this"; } } } } if (slotname) { snprintf(buf, bufsize, pattern, slotname); } else { snprintf(buf, bufsize, "**UNKNOWN SLOT %" PRIu32 "**", slot); } } while (false); } else { if (key->isInt()) { snprintf(buf, bufsize, "%" PRId32, key->toInt()); } else if (key->isAtom()) { PutEscapedString(buf, bufsize, key->toAtom(), 0); } else if (key->isSymbol()) { snprintf(buf, bufsize, "**SYMBOL KEY**"); } else { snprintf(buf, bufsize, "**FINALIZED ATOM KEY**"); } } } /*** Debugging routines *****************************************************/ #if defined(DEBUG) || defined(JS_JITSPEW) /* * Routines to print out values during debugging. These are FRIEND_API to help * the debugger find them and to support temporarily hacking js::Dump* calls * into other code. */ static void dumpValue(const Value& v, js::GenericPrinter& out) { switch (v.type()) { case ValueType::Null: out.put("null"); break; case ValueType::Undefined: out.put("undefined"); break; case ValueType::Int32: out.printf("%d", v.toInt32()); break; case ValueType::Double: out.printf("%g", v.toDouble()); break; case ValueType::String: v.toString()->dumpNoNewline(out); break; case ValueType::Symbol: v.toSymbol()->dump(out); break; case ValueType::BigInt: v.toBigInt()->dump(out); break; case ValueType::Object: if (v.toObject().is()) { JSFunction* fun = &v.toObject().as(); if (fun->displayAtom()) { out.put("displayAtom(), 0); } else { out.put("hasBaseScript()) { BaseScript* script = fun->baseScript(); out.printf(" (%s:%u)", script->filename() ? script->filename() : "", script->lineno()); } out.printf(" at %p>", (void*)fun); } else { JSObject* obj = &v.toObject(); const JSClass* clasp = obj->getClass(); out.printf("<%s%s at %p>", clasp->name, (clasp == &PlainObject::class_) ? "" : " object", (void*)obj); } break; # ifdef ENABLE_RECORD_TUPLE case ValueType::ExtendedPrimitive: { JSObject* obj = &v.toExtendedPrimitive(); out.printf("<%s at %p>", obj->getClass()->name, (void*)obj); break; } # endif case ValueType::Boolean: if (v.toBoolean()) { out.put("true"); } else { out.put("false"); } break; case ValueType::Magic: out.put("'); break; case ValueType::PrivateGCThing: out.printf("", v.toGCThing()); break; } } namespace js { // We don't want jsfriendapi.h to depend on GenericPrinter, // so these functions are declared directly in the cpp. JS_PUBLIC_API void DumpValue(const JS::Value& val, js::GenericPrinter& out); JS_PUBLIC_API void DumpId(jsid id, js::GenericPrinter& out); JS_PUBLIC_API void DumpInterpreterFrame(JSContext* cx, js::GenericPrinter& out, InterpreterFrame* start = nullptr); } // namespace js JS_PUBLIC_API void js::DumpValue(const Value& val, js::GenericPrinter& out) { dumpValue(val, out); out.putChar('\n'); } JS_PUBLIC_API void js::DumpId(jsid id, js::GenericPrinter& out) { out.printf("jsid %p = ", (void*)id.asRawBits()); dumpValue(IdToValue(id), out); out.putChar('\n'); } static void DumpProperty(const NativeObject* obj, PropMap* map, uint32_t index, js::GenericPrinter& out) { PropertyInfoWithKey prop = map->getPropertyInfoWithKey(index); jsid id = prop.key(); if (id.isAtom()) { id.toAtom()->dumpCharsNoNewline(out); } else if (id.isInt()) { out.printf("%d", id.toInt()); } else if (id.isSymbol()) { id.toSymbol()->dump(out); } else { out.printf("id %p", reinterpret_cast(id.asRawBits())); } if (prop.isDataProperty()) { out.printf(": "); dumpValue(obj->getSlot(prop.slot()), out); } else if (prop.isAccessorProperty()) { out.printf(": getter %p setter %p", obj->getGetter(prop), obj->getSetter(prop)); } out.printf(" (map %p/%u", map, index); if (prop.enumerable()) { out.put(" enumerable"); } if (prop.configurable()) { out.put(" configurable"); } if (prop.isDataDescriptor() && prop.writable()) { out.put(" writable"); } if (prop.isCustomDataProperty()) { out.printf(" "); } if (prop.hasSlot()) { out.printf(" slot %u", prop.slot()); } out.printf(")\n"); } bool JSObject::hasSameRealmAs(JSContext* cx) const { return nonCCWRealm() == cx->realm(); } bool JSObject::uninlinedIsProxyObject() const { return is(); } bool JSObject::uninlinedNonProxyIsExtensible() const { return nonProxyIsExtensible(); } void JSObject::dump(js::GenericPrinter& out) const { const JSObject* obj = this; out.printf("object %p\n", obj); if (IsCrossCompartmentWrapper(this)) { out.printf(" compartment %p\n", compartment()); } else { JSObject* globalObj = &nonCCWGlobal(); out.printf(" global %p [%s]\n", globalObj, globalObj->getClass()->name); } const JSClass* clasp = obj->getClass(); out.printf(" class %p %s\n", clasp, clasp->name); if (IsProxy(obj)) { auto* handler = GetProxyHandler(obj); out.printf(" handler %p", handler); if (IsDeadProxyObject(obj)) { out.printf(" (DeadObjectProxy)"); } else if (IsCrossCompartmentWrapper(obj)) { out.printf(" (CCW)"); } out.putChar('\n'); Value priv = GetProxyPrivate(obj); if (!priv.isUndefined()) { out.printf(" private "); dumpValue(priv, out); out.putChar('\n'); } Value expando = GetProxyExpando(obj); if (!expando.isNull()) { out.printf(" expando "); dumpValue(expando, out); out.putChar('\n'); } } const Shape* shape = obj->shape(); out.printf(" shape %p\n", shape); out.put(" flags:"); if (obj->isUsedAsPrototype()) { out.put(" used_as_prototype"); } if (!obj->is() && !obj->nonProxyIsExtensible()) { out.put(" not_extensible"); } if (obj->maybeHasInterestingSymbolProperty()) { out.put(" maybe_has_interesting_symbol"); } if (obj->isQualifiedVarObj()) { out.put(" varobj"); } if (obj->isUnqualifiedVarObj()) { out.put(" unqualified_varobj"); } if (obj->hasInvalidatedTeleporting()) { out.put(" invalidated_teleporting"); } if (obj->hasStaticPrototype() && obj->staticPrototypeIsImmutable()) { out.put(" immutable_prototype"); } const NativeObject* nobj = obj->is() ? &obj->as() : nullptr; if (nobj) { if (nobj->inDictionaryMode()) { out.put(" inDictionaryMode"); } if (nobj->hadGetterSetterChange()) { out.put(" had_getter_setter_change"); } if (nobj->isIndexed()) { out.put(" indexed"); } if (nobj->hasEnumerableProperty()) { out.put(" has_enumerable"); } if (nobj->is() && nobj->as().hasNonWritableOrAccessorPropExclProto()) { out.put(" has_non_writable_or_accessor_prop_excl_proto"); } if (!nobj->denseElementsArePacked()) { out.put(" non_packed_elements"); } if (nobj->getElementsHeader()->isNotExtensible()) { out.put(" not_extensible"); } if (nobj->getElementsHeader()->isSealed()) { out.put(" sealed_elements"); } if (nobj->getElementsHeader()->isFrozen()) { out.put(" frozen_elements"); } if (nobj->getElementsHeader()->maybeInIteration()) { out.put(" elements_maybe_in_iteration"); } } else { out.put(" not_native"); } out.putChar('\n'); out.put(" proto "); TaggedProto proto = obj->taggedProto(); if (proto.isDynamic()) { out.put(""); } else { dumpValue(ObjectOrNullValue(proto.toObjectOrNull()), out); } out.putChar('\n'); if (nobj) { uint32_t reserved = JSCLASS_RESERVED_SLOTS(clasp); if (reserved) { out.printf(" reserved slots:\n"); for (uint32_t i = 0; i < reserved; i++) { out.printf(" %3u ", i); out.put(": "); dumpValue(nobj->getSlot(i), out); out.putChar('\n'); } } out.put(" properties:\n"); if (PropMap* map = nobj->shape()->propMap()) { Vector maps; while (true) { if (!maps.append(map)) { out.printf("(OOM while appending maps)\n"); break; } if (!map->hasPrevious()) { break; } map = map->asLinked()->previous(); } for (size_t i = maps.length(); i > 0; i--) { size_t index = i - 1; uint32_t len = (index == 0) ? nobj->shape()->propMapLength() : PropMap::Capacity; for (uint32_t j = 0; j < len; j++) { PropMap* map = maps[index]; if (!map->hasKey(j)) { MOZ_ASSERT(map->isDictionary()); continue; } out.printf(" "); DumpProperty(nobj, map, j, out); } } } uint32_t slots = nobj->getDenseInitializedLength(); if (slots) { out.put(" elements:\n"); for (uint32_t i = 0; i < slots; i++) { out.printf(" %3u: ", i); dumpValue(nobj->getDenseElement(i), out); out.putChar('\n'); } } } } // For debuggers. void JSObject::dump() const { Fprinter out(stderr); dump(out); } static void MaybeDumpScope(Scope* scope, js::GenericPrinter& out) { if (scope) { out.printf(" scope: %s\n", ScopeKindString(scope->kind())); for (BindingIter bi(scope); bi; bi++) { out.put(" "); dumpValue(StringValue(bi.name()), out); out.putChar('\n'); } } } static void MaybeDumpValue(const char* name, const Value& v, js::GenericPrinter& out) { if (!v.isNull()) { out.printf(" %s: ", name); dumpValue(v, out); out.putChar('\n'); } } JS_PUBLIC_API void js::DumpInterpreterFrame(JSContext* cx, js::GenericPrinter& out, InterpreterFrame* start) { /* This should only called during live debugging. */ ScriptFrameIter i(cx); if (!start) { if (i.done()) { out.printf("no stack for cx = %p\n", (void*)cx); return; } } else { while (!i.done() && !i.isJSJit() && i.interpFrame() != start) { ++i; } if (i.done()) { out.printf("fp = %p not found in cx = %p\n", (void*)start, (void*)cx); return; } } for (; !i.done(); ++i) { if (i.isJSJit()) { out.put("JIT frame\n"); } else { out.printf("InterpreterFrame at %p\n", (void*)i.interpFrame()); } if (i.isFunctionFrame()) { out.put("callee fun: "); RootedValue v(cx); JSObject* fun = i.callee(cx); v.setObject(*fun); dumpValue(v, out); } else { out.put("global or eval frame, no callee"); } out.putChar('\n'); out.printf("file %s line %u\n", i.script()->filename(), i.script()->lineno()); if (jsbytecode* pc = i.pc()) { out.printf(" pc = %p\n", pc); out.printf(" current op: %s\n", CodeName(JSOp(*pc))); MaybeDumpScope(i.script()->lookupScope(pc), out); } if (i.isFunctionFrame()) { MaybeDumpValue("this", i.thisArgument(cx), out); } if (!i.isJSJit()) { out.put(" rval: "); dumpValue(i.interpFrame()->returnValue(), out); out.putChar('\n'); } out.put(" flags:"); if (i.isConstructing()) { out.put(" constructing"); } if (!i.isJSJit() && i.interpFrame()->isDebuggerEvalFrame()) { out.put(" debugger eval"); } if (i.isEvalFrame()) { out.put(" eval"); } out.putChar('\n'); out.printf(" envChain: (JSObject*) %p\n", (void*)i.environmentChain(cx)); out.putChar('\n'); } } #endif /* defined(DEBUG) || defined(JS_JITSPEW) */ JS_PUBLIC_API void js::DumpBacktrace(JSContext* cx, FILE* fp) { Fprinter out(fp); js::DumpBacktrace(cx, out); } JS_PUBLIC_API void js::DumpBacktrace(JSContext* cx, js::GenericPrinter& out) { size_t depth = 0; for (AllFramesIter i(cx); !i.done(); ++i, ++depth) { const char* filename; unsigned line; if (i.hasScript()) { filename = JS_GetScriptFilename(i.script()); line = PCToLineNumber(i.script(), i.pc()); } else { filename = i.filename(); line = i.computeLine(); } char frameType = i.isInterp() ? 'i' : i.isBaseline() ? 'b' : i.isIon() ? 'I' : i.isWasm() ? 'W' : '?'; out.printf("#%zu %14p %c %s:%u", depth, i.rawFramePtr(), frameType, filename, line); if (i.hasScript()) { out.printf(" (%p @ %zu)\n", i.script(), i.script()->pcToOffset(i.pc())); } else { out.printf(" (%p)\n", i.pc()); } } } JS_PUBLIC_API void js::DumpBacktrace(JSContext* cx) { DumpBacktrace(cx, stdout); } /* * */ bool JSObject::isBackgroundFinalized() const { if (isTenured()) { return js::gc::IsBackgroundFinalized(asTenured().getAllocKind()); } js::Nursery& nursery = runtimeFromMainThread()->gc.nursery(); return js::gc::IsBackgroundFinalized(allocKindForTenure(nursery)); } js::gc::AllocKind JSObject::allocKindForTenure( const js::Nursery& nursery) const { using namespace js::gc; MOZ_ASSERT(IsInsideNursery(this)); if (canHaveFixedElements()) { const NativeObject& nobj = as(); MOZ_ASSERT(nobj.numFixedSlots() == 0); /* Use minimal size object if we are just going to copy the pointer. */ if (!nursery.isInside(nobj.getUnshiftedElementsHeader())) { return gc::AllocKind::OBJECT0_BACKGROUND; } size_t nelements = nobj.getDenseCapacity(); return ForegroundToBackgroundAllocKind(GetGCArrayKind(nelements)); } if (is()) { return as().getAllocKind(); } /* * Typed arrays in the nursery may have a lazily allocated buffer, make * sure there is room for the array's fixed data when moving the array. */ if (is() && !as().hasBuffer()) { gc::AllocKind allocKind; if (as().hasInlineElements()) { size_t nbytes = as().byteLength(); allocKind = TypedArrayObject::AllocKindForLazyBuffer(nbytes); } else { allocKind = GetGCObjectKind(getClass()); } return ForegroundToBackgroundAllocKind(allocKind); } // Proxies that are CrossCompartmentWrappers may be nursery allocated. if (is()) { return as().allocKindForTenure(); } // WasmStructObjects have a variable-length tail which contains the first // few data fields, so make sure we copy it all over to the new object. if (is()) { // Figure out the size of this object, from the object's TypeDef. const wasm::TypeDef* typeDef = &as().typeDef(); return WasmStructObject::allocKindForTypeDef(typeDef); } if (is()) { return WasmArrayObject::allocKind(); } // All nursery allocatable non-native objects are handled above. return as().allocKindForTenure(); } void JSObject::addSizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf, JS::ClassInfo* info, JS::RuntimeSizes* runtimeSizes) { if (is() && as().hasDynamicSlots()) { info->objectsMallocHeapSlots += mallocSizeOf(as().getSlotsHeader()); } if (is() && as().hasDynamicElements()) { void* allocatedElements = as().getUnshiftedElementsHeader(); info->objectsMallocHeapElementsNormal += mallocSizeOf(allocatedElements); } // Other things may be measured in the future if DMD indicates it is // worthwhile. if (is() || is() || is() || is() || is() || is()) { // Do nothing. But this function is hot, and we win by getting the // common cases out of the way early. Some stats on the most common // classes, as measured during a vanilla browser session: // - (53.7%, 53.7%): Function // - (18.0%, 71.7%): Object // - (16.9%, 88.6%): Array // - ( 3.9%, 92.5%): Call // - ( 2.8%, 95.3%): RegExp // - ( 1.0%, 96.4%): Proxy // Note that any JSClass that is special cased below likely needs to // specify the JSCLASS_DELAY_METADATA_BUILDER flag, or else we will // probably crash if the object metadata callback attempts to get the // size of the new object (which Debugger code does) before private // slots are initialized. } else if (is()) { info->objectsMallocHeapMisc += as().sizeOfMisc(mallocSizeOf); } else if (is()) { info->objectsMallocHeapMisc += as().sizeOfData(mallocSizeOf); } else if (is()) { info->objectsMallocHeapMisc += as().sizeOfData(mallocSizeOf); } else if (is()) { info->objectsMallocHeapMisc += as().sizeOfMisc(mallocSizeOf); } else if (is()) { ArrayBufferObject::addSizeOfExcludingThis(this, mallocSizeOf, info, runtimeSizes); } else if (is()) { SharedArrayBufferObject::addSizeOfExcludingThis(this, mallocSizeOf, info, runtimeSizes); } else if (is()) { as().addSizeOfData(mallocSizeOf, info); } else if (is()) { info->objectsMallocHeapMisc += as().sizeOfExcludingThis(mallocSizeOf); } #ifdef JS_HAS_CTYPES else { // This must be the last case. info->objectsMallocHeapMisc += ctypes::SizeOfDataIfCDataObject( mallocSizeOf, const_cast(this)); } #endif } size_t JSObject::sizeOfIncludingThisInNursery() const { // This function doesn't concern itself yet with typed objects (bug 1133593). MOZ_ASSERT(!isTenured()); const Nursery& nursery = runtimeFromMainThread()->gc.nursery(); size_t size = gc::Arena::thingSize(allocKindForTenure(nursery)); if (is()) { const NativeObject& native = as(); size += native.numDynamicSlots() * sizeof(Value); if (native.hasDynamicElements()) { js::ObjectElements& elements = *native.getElementsHeader(); size += (elements.capacity + elements.numShiftedElements()) * sizeof(HeapSlot); } if (is()) { size += as().sizeOfData(); } } return size; } JS::ubi::Node::Size JS::ubi::Concrete::size( mozilla::MallocSizeOf mallocSizeOf) const { JSObject& obj = get(); if (!obj.isTenured()) { return obj.sizeOfIncludingThisInNursery(); } JS::ClassInfo info; obj.addSizeOfExcludingThis(mallocSizeOf, &info, nullptr); return obj.tenuredSizeOfThis() + info.sizeOfAllThings(); } const char16_t JS::ubi::Concrete::concreteTypeName[] = u"JSObject"; void JSObject::traceChildren(JSTracer* trc) { TraceCellHeaderEdge(trc, this, "shape"); Shape* objShape = shape(); if (objShape->isNative()) { NativeObject* nobj = &as(); { GetObjectSlotNameFunctor func(nobj); JS::AutoTracingDetails ctx(trc, func); JS::AutoTracingIndex index(trc); // Tracing can mutate the target but cannot change the slot count, // but the compiler has no way of knowing this. const uint32_t nslots = nobj->slotSpan(); for (uint32_t i = 0; i < nslots; ++i) { TraceEdge(trc, &nobj->getSlotRef(i), "object slot"); ++index; } MOZ_ASSERT(nslots == nobj->slotSpan()); } TraceRange(trc, nobj->getDenseInitializedLength(), static_cast(nobj->getDenseElements()), "objectElements"); } // Call the trace hook at the end so that during a moving GC the trace hook // will see updated fields and slots. const JSClass* clasp = objShape->getObjectClass(); if (clasp->hasTrace()) { clasp->doTrace(trc, this); } } // ES 2016 7.3.20. [[nodiscard]] JSObject* js::SpeciesConstructor( JSContext* cx, HandleObject obj, HandleObject defaultCtor, bool (*isDefaultSpecies)(JSContext*, JSFunction*)) { // Step 1 (implicit). // Fast-path for steps 2 - 8. Applies if all of the following conditions // are met: // - obj.constructor can be retrieved without side-effects. // - obj.constructor[[@@species]] can be retrieved without side-effects. // - obj.constructor[[@@species]] is the builtin's original @@species // getter. RootedValue ctor(cx); bool ctorGetSucceeded = GetPropertyPure( cx, obj, NameToId(cx->names().constructor), ctor.address()); if (ctorGetSucceeded && ctor.isObject() && &ctor.toObject() == defaultCtor) { jsid speciesId = PropertyKey::Symbol(cx->wellKnownSymbols().species); JSFunction* getter; if (GetGetterPure(cx, defaultCtor, speciesId, &getter) && getter && isDefaultSpecies(cx, getter)) { return defaultCtor; } } // Step 2. if (!ctorGetSucceeded && !GetProperty(cx, obj, obj, cx->names().constructor, &ctor)) { return nullptr; } // Step 3. if (ctor.isUndefined()) { return defaultCtor; } // Step 4. if (!ctor.isObject()) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_OBJECT_REQUIRED, "object's 'constructor' property"); return nullptr; } // Step 5. RootedObject ctorObj(cx, &ctor.toObject()); RootedValue s(cx); RootedId speciesId(cx, PropertyKey::Symbol(cx->wellKnownSymbols().species)); if (!GetProperty(cx, ctorObj, ctor, speciesId, &s)) { return nullptr; } // Step 6. if (s.isNullOrUndefined()) { return defaultCtor; } // Step 7. if (IsConstructor(s)) { return &s.toObject(); } // Step 8. JS_ReportErrorNumberASCII( cx, GetErrorMessage, nullptr, JSMSG_NOT_CONSTRUCTOR, "[Symbol.species] property of object's constructor"); return nullptr; } [[nodiscard]] JSObject* js::SpeciesConstructor( JSContext* cx, HandleObject obj, JSProtoKey ctorKey, bool (*isDefaultSpecies)(JSContext*, JSFunction*)) { RootedObject defaultCtor(cx, GlobalObject::getOrCreateConstructor(cx, ctorKey)); if (!defaultCtor) { return nullptr; } return SpeciesConstructor(cx, obj, defaultCtor, isDefaultSpecies); } bool js::Unbox(JSContext* cx, HandleObject obj, MutableHandleValue vp) { if (MOZ_UNLIKELY(obj->is())) { return Proxy::boxedValue_unbox(cx, obj, vp); } if (obj->is()) { vp.setBoolean(obj->as().unbox()); } else if (obj->is()) { vp.setNumber(obj->as().unbox()); } else if (obj->is()) { vp.setString(obj->as().unbox()); } else if (obj->is()) { vp.set(obj->as().UTCTime()); } else if (obj->is()) { vp.setSymbol(obj->as().unbox()); } else if (obj->is()) { vp.setBigInt(obj->as().unbox()); #ifdef ENABLE_RECORD_TUPLE } else if (obj->is()) { vp.setExtendedPrimitive(*obj->as().unbox()); } else if (obj->is()) { vp.setExtendedPrimitive(obj->as().unbox()); #endif } else { vp.setUndefined(); } return true; } #ifdef DEBUG void js::AssertJSClassInvariants(const JSClass* clasp) { MOZ_ASSERT(JS::StringIsASCII(clasp->name)); // Native objects shouldn't use the property operation hooks in ObjectOps. // Doing so could violate JIT invariants. // // Environment objects unfortunately use these hooks, but environment objects // are not exposed directly to script so they're generally less of an issue. if (clasp->isNativeObject() && clasp != &WithEnvironmentObject::class_ && clasp != &ModuleEnvironmentObject::class_ && clasp != &RuntimeLexicalErrorObject::class_) { MOZ_ASSERT(!clasp->getOpsLookupProperty()); MOZ_ASSERT_IF(clasp != &MappedArgumentsObject::class_, !clasp->getOpsDefineProperty()); MOZ_ASSERT(!clasp->getOpsHasProperty()); MOZ_ASSERT(!clasp->getOpsGetProperty()); MOZ_ASSERT(!clasp->getOpsSetProperty()); MOZ_ASSERT(!clasp->getOpsGetOwnPropertyDescriptor()); MOZ_ASSERT(!clasp->getOpsDeleteProperty()); } } /* static */ void JSObject::debugCheckNewObject(Shape* shape, js::gc::AllocKind allocKind, js::gc::Heap heap) { const JSClass* clasp = shape->getObjectClass(); if (!ClassCanHaveFixedData(clasp)) { NativeShape* nshape = &shape->asNative(); if (clasp == &ArrayObject::class_) { // Arrays can store the ObjectElements header inline. MOZ_ASSERT(nshape->numFixedSlots() == 0); } else { MOZ_ASSERT(gc::GetGCKindSlots(allocKind) == nshape->numFixedSlots()); } } // Assert background finalization is used when possible. MOZ_ASSERT(!CanChangeToBackgroundAllocKind(allocKind, clasp)); // Classes with a finalizer must specify whether instances will be finalized // on the main thread or in the background, except proxies whose behaviour // depends on the target object. static const uint32_t FinalizeMask = JSCLASS_FOREGROUND_FINALIZE | JSCLASS_BACKGROUND_FINALIZE; uint32_t flags = clasp->flags; uint32_t finalizeFlags = flags & FinalizeMask; if (clasp->hasFinalize() && !clasp->isProxyObject()) { MOZ_ASSERT(finalizeFlags == JSCLASS_FOREGROUND_FINALIZE || finalizeFlags == JSCLASS_BACKGROUND_FINALIZE); MOZ_ASSERT((finalizeFlags == JSCLASS_BACKGROUND_FINALIZE) == IsBackgroundFinalized(allocKind)); } else { MOZ_ASSERT(finalizeFlags == 0); } MOZ_ASSERT_IF(clasp->hasFinalize(), heap == gc::Heap::Tenured || CanNurseryAllocateFinalizedClass(clasp) || clasp->isProxyObject()); MOZ_ASSERT(!shape->isDictionary()); MOZ_ASSERT(!shape->realm()->hasObjectPendingMetadata()); // Non-native classes manage their own data and slots, so numFixedSlots is // always 0. Note that proxy classes can have reserved slots but they're not // included in numFixedSlots. if (!clasp->isNativeObject()) { MOZ_ASSERT_IF(!clasp->isProxyObject(), JSCLASS_RESERVED_SLOTS(clasp) == 0); } } #endif