/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * 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/. */ #ifndef jsobjinlines_h #define jsobjinlines_h #include "jsobj.h" #include "mozilla/DebugOnly.h" #include "jsfriendapi.h" #include "jsfun.h" #include "builtin/MapObject.h" #include "builtin/TypedObject.h" #include "gc/Allocator.h" #include "vm/ArrayObject.h" #include "vm/DateObject.h" #include "vm/EnvironmentObject.h" #include "vm/NumberObject.h" #include "vm/Probes.h" #include "vm/StringObject.h" #include "vm/TypedArrayCommon.h" #include "jsatominlines.h" #include "jscompartmentinlines.h" #include "jsgcinlines.h" #include "vm/ShapedObject-inl.h" #include "vm/TypeInference-inl.h" inline js::Shape* JSObject::maybeShape() const { if (!is()) return nullptr; return as().shape(); } inline js::Shape* JSObject::ensureShape(js::ExclusiveContext* cx) { js::Shape* shape = maybeShape(); MOZ_ASSERT(shape); return shape; } inline void JSObject::finalize(js::FreeOp* fop) { js::probes::FinalizeObject(this); #ifdef DEBUG MOZ_ASSERT(isTenured()); if (!IsBackgroundFinalized(asTenured().getAllocKind())) { /* Assert we're on the main thread. */ MOZ_ASSERT(CurrentThreadCanAccessRuntime(fop->runtime())); } #endif const js::Class* clasp = getClass(); js::NativeObject* nobj = nullptr; if (clasp->isNative()) nobj = &as(); if (clasp->hasFinalize()) clasp->doFinalize(fop, this); if (!nobj) return; if (nobj->hasDynamicSlots()) fop->free_(nobj->slots_); if (nobj->hasDynamicElements()) { js::ObjectElements* elements = nobj->getElementsHeader(); if (elements->isCopyOnWrite()) { if (elements->ownerObject() == this) { // Don't free the elements until object finalization finishes, // so that other objects can access these elements while they // are themselves finalized. fop->freeLater(elements); } } else { fop->free_(elements); } } nobj->sweepDictionaryListPointer(); } MOZ_ALWAYS_INLINE void js::NativeObject::sweepDictionaryListPointer() { // For dictionary objects (which must be native), it's possible that // unreachable shapes may be marked whose listp points into this object. In // case this happens, null out the shape's pointer so that a moving GC will // not try to access the dead object. if (shape_->listp == &shape_) shape_->listp = nullptr; } /* static */ inline bool JSObject::setSingleton(js::ExclusiveContext* cx, js::HandleObject obj) { MOZ_ASSERT_IF(cx->isJSContext(), !IsInsideNursery(obj)); js::ObjectGroup* group = js::ObjectGroup::lazySingletonGroup(cx, obj->getClass(), obj->taggedProto()); if (!group) return false; obj->group_ = group; return true; } /* static */ inline js::ObjectGroup* JSObject::getGroup(JSContext* cx, js::HandleObject obj) { MOZ_ASSERT(cx->compartment() == obj->compartment()); if (obj->hasLazyGroup()) { if (cx->compartment() != obj->compartment()) MOZ_CRASH(); return makeLazyGroup(cx, obj); } return obj->group_; } inline void JSObject::setGroup(js::ObjectGroup* group) { MOZ_RELEASE_ASSERT(group); MOZ_ASSERT(!isSingleton()); group_ = group; } /*** Standard internal methods *******************************************************************/ inline bool js::GetPrototype(JSContext* cx, js::HandleObject obj, js::MutableHandleObject protop) { if (obj->hasDynamicPrototype()) { MOZ_ASSERT(obj->is()); return js::Proxy::getPrototype(cx, obj, protop); } protop.set(obj->taggedProto().toObjectOrNull()); return true; } inline bool js::IsExtensible(ExclusiveContext* cx, HandleObject obj, bool* extensible) { if (obj->is()) { if (!cx->shouldBeJSContext()) return false; return Proxy::isExtensible(cx->asJSContext(), obj, extensible); } *extensible = obj->nonProxyIsExtensible(); return true; } inline bool js::HasProperty(JSContext* cx, HandleObject obj, PropertyName* name, bool* found) { RootedId id(cx, NameToId(name)); return HasProperty(cx, obj, id, found); } inline bool js::GetElement(JSContext* cx, HandleObject obj, HandleValue receiver, uint32_t index, MutableHandleValue vp) { RootedId id(cx); if (!IndexToId(cx, index, &id)) return false; return GetProperty(cx, obj, receiver, id, vp); } inline bool js::GetElement(JSContext* cx, HandleObject obj, HandleObject receiver, uint32_t index, MutableHandleValue vp) { RootedValue receiverValue(cx, ObjectValue(*receiver)); return GetElement(cx, obj, receiverValue, index, vp); } inline bool js::GetElementNoGC(JSContext* cx, JSObject* obj, const Value& receiver, uint32_t index, Value* vp) { if (obj->getOpsGetProperty()) return false; if (index > JSID_INT_MAX) return false; return GetPropertyNoGC(cx, obj, receiver, INT_TO_JSID(index), vp); } inline bool js::GetElementNoGC(JSContext* cx, JSObject* obj, JSObject* receiver, uint32_t index, Value* vp) { return GetElementNoGC(cx, obj, ObjectValue(*receiver), index, vp); } inline bool js::DeleteProperty(JSContext* cx, HandleObject obj, HandleId id, ObjectOpResult& result) { MarkTypePropertyNonData(cx, obj, id); if (DeletePropertyOp op = obj->getOpsDeleteProperty()) return op(cx, obj, id, result); return NativeDeleteProperty(cx, obj.as(), id, result); } inline bool js::DeleteElement(JSContext* cx, HandleObject obj, uint32_t index, ObjectOpResult& result) { RootedId id(cx); if (!IndexToId(cx, index, &id)) return false; return DeleteProperty(cx, obj, id, result); } /* * */ inline bool JSObject::isQualifiedVarObj() const { if (is()) return as().environment().isQualifiedVarObj(); bool rv = hasAllFlags(js::BaseShape::QUALIFIED_VAROBJ); MOZ_ASSERT_IF(rv, is() || is() || is() || is() || is() || (is() && !as().isSyntactic())); return rv; } inline bool JSObject::isUnqualifiedVarObj() const { if (is()) return as().environment().isUnqualifiedVarObj(); return is() || is(); } namespace js { inline bool ClassCanHaveFixedData(const Class* clasp) { // Normally, the number of fixed slots given an object is the maximum // permitted for its size class. For array buffers and non-shared typed // arrays we only use enough to cover the class reserved slots, so that // the remaining space in the object's allocation is available for the // buffer's data. return !clasp->isNative() || clasp == &js::ArrayBufferObject::class_ || js::IsTypedArrayClass(clasp); } // This function is meant to be called from allocation fast paths. // // If we do have an allocation metadata builder, it can cause a GC, so the object // must be rooted. The usual way to do this would be to make our callers pass a // HandleObject, but that would require them to pay the cost of rooting the // object unconditionally, even though collecting metadata is rare. Instead, // SetNewObjectMetadata's contract is that the caller must use the pointer // returned in place of the pointer passed. If a GC occurs, the returned pointer // may be the passed pointer, relocated by GC. If no GC could occur, it's just // passed through. We root nothing unless necessary. static MOZ_ALWAYS_INLINE MOZ_MUST_USE JSObject* SetNewObjectMetadata(ExclusiveContext* cxArg, JSObject* obj) { MOZ_ASSERT(!cxArg->compartment()->hasObjectPendingMetadata()); // The metadata builder is invoked for each object created on the main // thread, except when analysis/compilation is active, to avoid recursion. if (JSContext* cx = cxArg->maybeJSContext()) { if (MOZ_UNLIKELY((size_t)cx->compartment()->hasAllocationMetadataBuilder()) && !cx->zone()->suppressAllocationMetadataBuilder) { // Don't collect metadata on objects that represent metadata. AutoSuppressAllocationMetadataBuilder suppressMetadata(cx); RootedObject rooted(cx, obj); cx->compartment()->setNewObjectMetadata(cx, rooted); return rooted; } } return obj; } } // namespace js /* static */ inline JSObject* JSObject::create(js::ExclusiveContext* cx, js::gc::AllocKind kind, js::gc::InitialHeap heap, js::HandleShape shape, js::HandleObjectGroup group) { const js::Class* clasp = group->clasp(); MOZ_ASSERT(shape && group); MOZ_ASSERT(clasp == shape->getObjectClass()); MOZ_ASSERT(clasp != &js::ArrayObject::class_); MOZ_ASSERT_IF(!js::ClassCanHaveFixedData(clasp), js::gc::GetGCKindSlots(kind, clasp) == shape->numFixedSlots()); #ifdef DEBUG static const uint32_t FinalizeMask = JSCLASS_FOREGROUND_FINALIZE | JSCLASS_BACKGROUND_FINALIZE; uint32_t flags = clasp->flags; uint32_t finalizeFlags = flags & FinalizeMask; // 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. if (clasp->hasFinalize() && !clasp->isProxy()) { MOZ_ASSERT(finalizeFlags == JSCLASS_FOREGROUND_FINALIZE || finalizeFlags == JSCLASS_BACKGROUND_FINALIZE); MOZ_ASSERT((finalizeFlags == JSCLASS_BACKGROUND_FINALIZE) == IsBackgroundFinalized(kind)); } else { MOZ_ASSERT(finalizeFlags == 0); } MOZ_ASSERT_IF(clasp->hasFinalize(), heap == js::gc::TenuredHeap || CanNurseryAllocateFinalizedClass(clasp) || clasp->isProxy()); MOZ_ASSERT_IF(group->hasUnanalyzedPreliminaryObjects(), heap == js::gc::TenuredHeap); #endif MOZ_ASSERT(!cx->compartment()->hasObjectPendingMetadata()); // Non-native classes cannot have reserved slots or private data, and the // objects can't have any fixed slots, for compatibility with // GetReservedOrProxyPrivateSlot. MOZ_ASSERT_IF(!clasp->isNative(), JSCLASS_RESERVED_SLOTS(clasp) == 0); MOZ_ASSERT_IF(!clasp->isNative(), !clasp->hasPrivate()); MOZ_ASSERT_IF(!clasp->isNative(), shape->numFixedSlots() == 0); MOZ_ASSERT_IF(!clasp->isNative(), shape->slotSpan() == 0); size_t nDynamicSlots = 0; if (clasp->isNative()) { nDynamicSlots = js::NativeObject::dynamicSlotsCount(shape->numFixedSlots(), shape->slotSpan(), clasp); } else if (clasp->isProxy()) { // Proxy objects overlay the |slots| field with a ProxyValueArray. MOZ_ASSERT(sizeof(js::detail::ProxyValueArray) % sizeof(js::HeapSlot) == 0); nDynamicSlots = sizeof(js::detail::ProxyValueArray) / sizeof(js::HeapSlot); } JSObject* obj = js::Allocate(cx, kind, nDynamicSlots, heap, clasp); if (!obj) return nullptr; obj->group_.init(group); // This function allocates normal objects and proxies and typed objects // (all with shapes), *and* it allocates objects without shapes (various // unboxed object classes). Setting shape is naturally only valid for the // former class of objects. if (obj->is()) obj->as().initShape(shape); // Note: slots are created and assigned internally by Allocate. obj->setInitialElementsMaybeNonNative(js::emptyObjectElements); if (clasp->hasPrivate()) obj->as().privateRef(shape->numFixedSlots()) = nullptr; if (size_t span = shape->slotSpan()) obj->as().initializeSlotRange(0, span); // JSFunction's fixed slots expect POD-style initialization. if (clasp->isJSFunction()) { MOZ_ASSERT(kind == js::gc::AllocKind::FUNCTION || kind == js::gc::AllocKind::FUNCTION_EXTENDED); size_t size = kind == js::gc::AllocKind::FUNCTION ? sizeof(JSFunction) : sizeof(js::FunctionExtended); memset(obj->as().fixedSlots(), 0, size - sizeof(js::NativeObject)); if (kind == js::gc::AllocKind::FUNCTION_EXTENDED) { // SetNewObjectMetadata may gc, which will be unhappy if flags & // EXTENDED doesn't match the arena's AllocKind. obj->as().setFlags(JSFunction::EXTENDED); } } if (clasp->shouldDelayMetadataBuilder()) cx->compartment()->setObjectPendingMetadata(cx, obj); else obj = SetNewObjectMetadata(cx, obj); js::gc::TraceCreateObject(obj); return obj; } inline void JSObject::setInitialSlotsMaybeNonNative(js::HeapSlot* slots) { static_cast(this)->slots_ = slots; } inline void JSObject::setInitialElementsMaybeNonNative(js::HeapSlot* elements) { static_cast(this)->elements_ = elements; } inline js::GlobalObject& JSObject::global() const { /* * The global is read-barriered so that it is kept live by access through * the JSCompartment. When accessed through a JSObject, however, the global * will be already be kept live by the black JSObject's parent pointer, so * does not need to be read-barriered. */ return *compartment()->unsafeUnbarrieredMaybeGlobal(); } inline js::GlobalObject* JSObject::globalForTracing(JSTracer*) const { return compartment()->unsafeUnbarrieredMaybeGlobal(); } inline bool JSObject::isOwnGlobal(JSTracer* trc) const { return globalForTracing(trc) == this; } inline bool JSObject::hasAllFlags(js::BaseShape::Flag flags) const { MOZ_ASSERT(flags); if (js::Shape* shape = maybeShape()) return shape->hasAllObjectFlags(flags); return false; } inline bool JSObject::nonProxyIsExtensible() const { MOZ_ASSERT(!uninlinedIsProxy()); // [[Extensible]] for ordinary non-proxy objects is an object flag. return !hasAllFlags(js::BaseShape::NOT_EXTENSIBLE); } inline bool JSObject::isBoundFunction() const { return is() && as().isBoundFunction(); } inline bool JSObject::isDelegate() const { return hasAllFlags(js::BaseShape::DELEGATE); } inline bool JSObject::hasUncacheableProto() const { return hasAllFlags(js::BaseShape::UNCACHEABLE_PROTO); } inline bool JSObject::hadElementsAccess() const { return hasAllFlags(js::BaseShape::HAD_ELEMENTS_ACCESS); } inline bool JSObject::isIndexed() const { return hasAllFlags(js::BaseShape::INDEXED); } inline bool JSObject::staticPrototypeIsImmutable() const { MOZ_ASSERT(hasStaticPrototype()); return hasAllFlags(js::BaseShape::IMMUTABLE_PROTOTYPE); } inline bool JSObject::isIteratedSingleton() const { return hasAllFlags(js::BaseShape::ITERATED_SINGLETON); } inline bool JSObject::isNewGroupUnknown() const { return hasAllFlags(js::BaseShape::NEW_GROUP_UNKNOWN); } inline bool JSObject::wasNewScriptCleared() const { return hasAllFlags(js::BaseShape::NEW_SCRIPT_CLEARED); } namespace js { static MOZ_ALWAYS_INLINE bool IsFunctionObject(const js::Value& v) { return v.isObject() && v.toObject().is(); } static MOZ_ALWAYS_INLINE bool IsFunctionObject(const js::Value& v, JSFunction** fun) { if (v.isObject() && v.toObject().is()) { *fun = &v.toObject().as(); return true; } return false; } static MOZ_ALWAYS_INLINE bool IsNativeFunction(const js::Value& v) { JSFunction* fun; return IsFunctionObject(v, &fun) && fun->isNative(); } static MOZ_ALWAYS_INLINE bool IsNativeFunction(const js::Value& v, JSFunction** fun) { return IsFunctionObject(v, fun) && (*fun)->isNative(); } static MOZ_ALWAYS_INLINE bool IsNativeFunction(const js::Value& v, JSNative native) { JSFunction* fun; return IsFunctionObject(v, &fun) && fun->maybeNative() == native; } // Return whether looking up a method on 'obj' definitely resolves to the // original specified native function. The method may conservatively return // 'false' in the case of proxies or other non-native objects. static MOZ_ALWAYS_INLINE bool HasNativeMethodPure(JSObject* obj, PropertyName* name, JSNative native, JSContext* cx) { Value v; if (!GetPropertyPure(cx, obj, NameToId(name), &v)) return false; return IsNativeFunction(v, native); } // Return whether 'obj' definitely has no @@toPrimitive method. static MOZ_ALWAYS_INLINE bool HasNoToPrimitiveMethodPure(JSObject* obj, JSContext* cx) { jsid id = SYMBOL_TO_JSID(cx->wellKnownSymbols().toPrimitive); JSObject* pobj; Shape* shape; if (!LookupPropertyPure(cx, obj, id, &pobj, &shape)) return false; return !shape; } /* ES6 draft rev 28 (2014 Oct 14) 7.1.14 */ inline bool ToPropertyKey(JSContext* cx, HandleValue argument, MutableHandleId result) { // Steps 1-2. RootedValue key(cx, argument); if (!ToPrimitive(cx, JSTYPE_STRING, &key)) return false; // Steps 3-4. return ValueToId(cx, key, result); } /* * Return true if this is a compiler-created internal function accessed by * its own object. Such a function object must not be accessible to script * or embedding code. */ inline bool IsInternalFunctionObject(JSObject& funobj) { JSFunction& fun = funobj.as(); return fun.isInterpreted() && !fun.environment(); } /* * Make an object with the specified prototype. If parent is null, it will * default to the prototype's global if the prototype is non-null. */ JSObject* NewObjectWithGivenTaggedProto(ExclusiveContext* cx, const Class* clasp, Handle proto, gc::AllocKind allocKind, NewObjectKind newKind, uint32_t initialShapeFlags = 0); inline JSObject* NewObjectWithGivenTaggedProto(ExclusiveContext* cx, const Class* clasp, Handle proto, NewObjectKind newKind = GenericObject, uint32_t initialShapeFlags = 0) { gc::AllocKind allocKind = gc::GetGCObjectKind(clasp); return NewObjectWithGivenTaggedProto(cx, clasp, proto, allocKind, newKind, initialShapeFlags); } template inline T* NewObjectWithGivenTaggedProto(ExclusiveContext* cx, Handle proto, NewObjectKind newKind = GenericObject, uint32_t initialShapeFlags = 0) { JSObject* obj = NewObjectWithGivenTaggedProto(cx, &T::class_, proto, newKind, initialShapeFlags); return obj ? &obj->as() : nullptr; } template inline T* NewObjectWithNullTaggedProto(ExclusiveContext* cx, NewObjectKind newKind = GenericObject, uint32_t initialShapeFlags = 0) { Rooted nullProto(cx, TaggedProto(nullptr)); return NewObjectWithGivenTaggedProto(cx, nullProto, newKind, initialShapeFlags); } inline JSObject* NewObjectWithGivenProto(ExclusiveContext* cx, const Class* clasp, HandleObject proto, gc::AllocKind allocKind, NewObjectKind newKind) { return NewObjectWithGivenTaggedProto(cx, clasp, AsTaggedProto(proto), allocKind, newKind); } inline JSObject* NewObjectWithGivenProto(ExclusiveContext* cx, const Class* clasp, HandleObject proto, NewObjectKind newKind = GenericObject) { return NewObjectWithGivenTaggedProto(cx, clasp, AsTaggedProto(proto), newKind); } template inline T* NewObjectWithGivenProto(ExclusiveContext* cx, HandleObject proto, NewObjectKind newKind = GenericObject) { return NewObjectWithGivenTaggedProto(cx, AsTaggedProto(proto), newKind); } template inline T* NewObjectWithGivenProto(ExclusiveContext* cx, HandleObject proto, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { JSObject* obj = NewObjectWithGivenTaggedProto(cx, &T::class_, AsTaggedProto(proto), allocKind, newKind); return obj ? &obj->as() : nullptr; } // Make an object with the prototype set according to the cached prototype or // Object.prototype. JSObject* NewObjectWithClassProtoCommon(ExclusiveContext* cx, const Class* clasp, HandleObject proto, gc::AllocKind allocKind, NewObjectKind newKind); inline JSObject* NewObjectWithClassProto(ExclusiveContext* cx, const Class* clasp, HandleObject proto, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { return NewObjectWithClassProtoCommon(cx, clasp, proto, allocKind, newKind); } inline JSObject* NewObjectWithClassProto(ExclusiveContext* cx, const Class* clasp, HandleObject proto, NewObjectKind newKind = GenericObject) { gc::AllocKind allocKind = gc::GetGCObjectKind(clasp); return NewObjectWithClassProto(cx, clasp, proto, allocKind, newKind); } template inline T* NewObjectWithClassProto(ExclusiveContext* cx, HandleObject proto = nullptr, NewObjectKind newKind = GenericObject) { JSObject* obj = NewObjectWithClassProto(cx, &T::class_, proto, newKind); return obj ? &obj->as() : nullptr; } template inline T* NewObjectWithClassProto(ExclusiveContext* cx, HandleObject proto, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { JSObject* obj = NewObjectWithClassProto(cx, &T::class_, proto, allocKind, newKind); return obj ? &obj->as() : nullptr; } /* * Create a native instance of the given class with parent and proto set * according to the context's active global. */ inline JSObject* NewBuiltinClassInstance(ExclusiveContext* cx, const Class* clasp, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { return NewObjectWithClassProto(cx, clasp, nullptr, allocKind, newKind); } inline JSObject* NewBuiltinClassInstance(ExclusiveContext* cx, const Class* clasp, NewObjectKind newKind = GenericObject) { gc::AllocKind allocKind = gc::GetGCObjectKind(clasp); return NewBuiltinClassInstance(cx, clasp, allocKind, newKind); } template inline T* NewBuiltinClassInstance(ExclusiveContext* cx, NewObjectKind newKind = GenericObject) { JSObject* obj = NewBuiltinClassInstance(cx, &T::class_, newKind); return obj ? &obj->as() : nullptr; } template inline T* NewBuiltinClassInstance(ExclusiveContext* cx, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { JSObject* obj = NewBuiltinClassInstance(cx, &T::class_, allocKind, newKind); return obj ? &obj->as() : nullptr; } // Used to optimize calls to (new Object()) bool NewObjectScriptedCall(JSContext* cx, MutableHandleObject obj); JSObject* NewObjectWithGroupCommon(ExclusiveContext* cx, HandleObjectGroup group, gc::AllocKind allocKind, NewObjectKind newKind); template inline T* NewObjectWithGroup(ExclusiveContext* cx, HandleObjectGroup group, gc::AllocKind allocKind, NewObjectKind newKind = GenericObject) { JSObject* obj = NewObjectWithGroupCommon(cx, group, allocKind, newKind); return obj ? &obj->as() : nullptr; } template inline T* NewObjectWithGroup(ExclusiveContext* cx, HandleObjectGroup group, NewObjectKind newKind = GenericObject) { gc::AllocKind allocKind = gc::GetGCObjectKind(group->clasp()); return NewObjectWithGroup(cx, group, allocKind, newKind); } /* * As for gc::GetGCObjectKind, where numElements is a guess at the final size of * the object, zero if the final size is unknown. This should only be used for * objects that do not require any fixed slots. */ static inline gc::AllocKind GuessObjectGCKind(size_t numElements) { if (numElements) return gc::GetGCObjectKind(numElements); return gc::AllocKind::OBJECT4; } static inline gc::AllocKind GuessArrayGCKind(size_t numElements) { if (numElements) return gc::GetGCArrayKind(numElements); return gc::AllocKind::OBJECT8; } // Returns ESClass::Other if the value isn't an object, or if the object // isn't of one of the enumerated classes. Otherwise returns the appropriate // class. inline bool GetClassOfValue(JSContext* cx, HandleValue v, ESClass* cls) { if (!v.isObject()) { *cls = ESClass::Other; return true; } RootedObject obj(cx, &v.toObject()); return GetBuiltinClass(cx, obj, cls); } extern NativeObject* InitClass(JSContext* cx, HandleObject obj, HandleObject parent_proto, const Class* clasp, JSNative constructor, unsigned nargs, const JSPropertySpec* ps, const JSFunctionSpec* fs, const JSPropertySpec* static_ps, const JSFunctionSpec* static_fs, NativeObject** ctorp = nullptr, gc::AllocKind ctorKind = gc::AllocKind::FUNCTION); } /* namespace js */ #endif /* jsobjinlines_h */