/* -*- 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/. */ #include "vm/ObjectGroup.h" #include "jsexn.h" #include "jshashutil.h" #include "jsobj.h" #include "gc/Marking.h" #include "gc/Policy.h" #include "gc/StoreBuffer.h" #include "gc/Zone.h" #include "js/CharacterEncoding.h" #include "vm/ArrayObject.h" #include "vm/Shape.h" #include "vm/TaggedProto.h" #include "vm/UnboxedObject.h" #include "jsobjinlines.h" #include "vm/UnboxedObject-inl.h" using namespace js; using mozilla::DebugOnly; using mozilla::PodZero; ///////////////////////////////////////////////////////////////////// // ObjectGroup ///////////////////////////////////////////////////////////////////// ObjectGroup::ObjectGroup(const Class* clasp, TaggedProto proto, JSCompartment* comp, ObjectGroupFlags initialFlags) { PodZero(this); /* Windows may not appear on prototype chains. */ MOZ_ASSERT_IF(proto.isObject(), !IsWindow(proto.toObject())); MOZ_ASSERT(JS::StringIsASCII(clasp->name)); this->clasp_ = clasp; this->proto_ = proto; this->compartment_ = comp; this->flags_ = initialFlags; setGeneration(zone()->types.generation); } void ObjectGroup::finalize(FreeOp* fop) { if (newScriptDontCheckGeneration()) newScriptDontCheckGeneration()->clear(); fop->delete_(newScriptDontCheckGeneration()); fop->delete_(maybeUnboxedLayoutDontCheckGeneration()); if (maybePreliminaryObjectsDontCheckGeneration()) maybePreliminaryObjectsDontCheckGeneration()->clear(); fop->delete_(maybePreliminaryObjectsDontCheckGeneration()); } void ObjectGroup::setProtoUnchecked(TaggedProto proto) { proto_ = proto; MOZ_ASSERT_IF(proto_.isObject() && proto_.toObject()->isNative(), proto_.toObject()->isDelegate()); } void ObjectGroup::setProto(TaggedProto proto) { MOZ_ASSERT(singleton()); setProtoUnchecked(proto); } size_t ObjectGroup::sizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const { size_t n = 0; if (TypeNewScript* newScript = newScriptDontCheckGeneration()) n += newScript->sizeOfIncludingThis(mallocSizeOf); if (UnboxedLayout* layout = maybeUnboxedLayoutDontCheckGeneration()) n += layout->sizeOfIncludingThis(mallocSizeOf); return n; } void ObjectGroup::setAddendum(AddendumKind kind, void* addendum, bool writeBarrier /* = true */) { MOZ_ASSERT(!needsSweep()); MOZ_ASSERT(kind <= (OBJECT_FLAG_ADDENDUM_MASK >> OBJECT_FLAG_ADDENDUM_SHIFT)); if (writeBarrier) { // Manually trigger barriers if we are clearing new script or // preliminary object information. Other addendums are immutable. switch (addendumKind()) { case Addendum_PreliminaryObjects: PreliminaryObjectArrayWithTemplate::writeBarrierPre(maybePreliminaryObjects()); break; case Addendum_NewScript: TypeNewScript::writeBarrierPre(newScript()); break; case Addendum_None: break; default: MOZ_ASSERT(addendumKind() == kind); } } flags_ &= ~OBJECT_FLAG_ADDENDUM_MASK; flags_ |= kind << OBJECT_FLAG_ADDENDUM_SHIFT; addendum_ = addendum; } /* static */ bool ObjectGroup::useSingletonForClone(JSFunction* fun) { if (!fun->isInterpreted()) return false; if (fun->isArrow()) return false; if (fun->isSingleton()) return false; /* * When a function is being used as a wrapper for another function, it * improves precision greatly to distinguish between different instances of * the wrapper; otherwise we will conflate much of the information about * the wrapped functions. * * An important example is the Class.create function at the core of the * Prototype.js library, which looks like: * * var Class = { * create: function() { * return function() { * this.initialize.apply(this, arguments); * } * } * }; * * Each instance of the innermost function will have a different wrapped * initialize method. We capture this, along with similar cases, by looking * for short scripts which use both .apply and arguments. For such scripts, * whenever creating a new instance of the function we both give that * instance a singleton type and clone the underlying script. */ uint32_t begin, end; if (fun->hasScript()) { if (!fun->nonLazyScript()->isLikelyConstructorWrapper()) return false; begin = fun->nonLazyScript()->sourceStart(); end = fun->nonLazyScript()->sourceEnd(); } else { if (!fun->lazyScript()->isLikelyConstructorWrapper()) return false; begin = fun->lazyScript()->begin(); end = fun->lazyScript()->end(); } return end - begin <= 100; } /* static */ bool ObjectGroup::useSingletonForNewObject(JSContext* cx, JSScript* script, jsbytecode* pc) { /* * Make a heuristic guess at a use of JSOP_NEW that the constructed object * should have a fresh group. We do this when the NEW is immediately * followed by a simple assignment to an object's .prototype field. * This is designed to catch common patterns for subclassing in JS: * * function Super() { ... } * function Sub1() { ... } * function Sub2() { ... } * * Sub1.prototype = new Super(); * Sub2.prototype = new Super(); * * Using distinct groups for the particular prototypes of Sub1 and * Sub2 lets us continue to distinguish the two subclasses and any extra * properties added to those prototype objects. */ if (script->isStarGenerator() || script->isLegacyGenerator() || script->isAsync()) return false; if (JSOp(*pc) != JSOP_NEW) return false; pc += JSOP_NEW_LENGTH; if (JSOp(*pc) == JSOP_SETPROP) { if (script->getName(pc) == cx->names().prototype) return true; } return false; } /* static */ bool ObjectGroup::useSingletonForAllocationSite(JSScript* script, jsbytecode* pc, JSProtoKey key) { // The return value of this method can either be tested like a boolean or // passed to a NewObject method. JS_STATIC_ASSERT(GenericObject == 0); /* * Objects created outside loops in global and eval scripts should have * singleton types. For now this is only done for plain objects, but not * typed arrays or normal arrays. */ if (script->functionNonDelazifying() && !script->treatAsRunOnce()) return GenericObject; if (key != JSProto_Object) return GenericObject; // All loops in the script will have a try note indicating their boundary. if (!script->hasTrynotes()) return SingletonObject; unsigned offset = script->pcToOffset(pc); JSTryNote* tn = script->trynotes()->vector; JSTryNote* tnlimit = tn + script->trynotes()->length; for (; tn < tnlimit; tn++) { if (tn->kind != JSTRY_FOR_IN && tn->kind != JSTRY_FOR_OF && tn->kind != JSTRY_LOOP) continue; unsigned startOffset = script->mainOffset() + tn->start; unsigned endOffset = startOffset + tn->length; if (offset >= startOffset && offset < endOffset) return GenericObject; } return SingletonObject; } /* static */ bool ObjectGroup::useSingletonForAllocationSite(JSScript* script, jsbytecode* pc, const Class* clasp) { return useSingletonForAllocationSite(script, pc, JSCLASS_CACHED_PROTO_KEY(clasp)); } ///////////////////////////////////////////////////////////////////// // JSObject ///////////////////////////////////////////////////////////////////// bool JSObject::shouldSplicePrototype() { /* * During bootstrapping, if inference is enabled we need to make sure not * to splice a new prototype in for Function.prototype or the global * object if their __proto__ had previously been set to null, as this * will change the prototype for all other objects with the same type. */ if (staticPrototype() != nullptr) return false; return isSingleton(); } /* static */ bool JSObject::splicePrototype(JSContext* cx, HandleObject obj, const Class* clasp, Handle proto) { MOZ_ASSERT(cx->compartment() == obj->compartment()); /* * For singleton groups representing only a single JSObject, the proto * can be rearranged as needed without destroying type information for * the old or new types. */ MOZ_ASSERT(obj->isSingleton()); // Windows may not appear on prototype chains. MOZ_ASSERT_IF(proto.isObject(), !IsWindow(proto.toObject())); if (proto.isObject()) { RootedObject protoObj(cx, proto.toObject()); if (!JSObject::setDelegate(cx, protoObj)) return false; } // Force type instantiation when splicing lazy group. RootedObjectGroup group(cx, JSObject::getGroup(cx, obj)); if (!group) return false; RootedObjectGroup protoGroup(cx, nullptr); if (proto.isObject()) { RootedObject protoObj(cx, proto.toObject()); protoGroup = JSObject::getGroup(cx, protoObj); if (!protoGroup) return false; } group->setClasp(clasp); group->setProto(proto); return true; } /* static */ ObjectGroup* JSObject::makeLazyGroup(JSContext* cx, HandleObject obj) { MOZ_ASSERT(obj->hasLazyGroup()); MOZ_ASSERT(cx->compartment() == obj->compartment()); /* De-lazification of functions can GC, so we need to do it up here. */ if (obj->is() && obj->as().isInterpretedLazy()) { RootedFunction fun(cx, &obj->as()); if (!JSFunction::getOrCreateScript(cx, fun)) return nullptr; } // Find flags which need to be specified immediately on the object. // Don't track whether singletons are packed. ObjectGroupFlags initialFlags = OBJECT_FLAG_SINGLETON | OBJECT_FLAG_NON_PACKED; if (obj->isIteratedSingleton()) initialFlags |= OBJECT_FLAG_ITERATED; if (obj->isIndexed()) initialFlags |= OBJECT_FLAG_SPARSE_INDEXES; if (obj->is() && obj->as().length() > INT32_MAX) initialFlags |= OBJECT_FLAG_LENGTH_OVERFLOW; Rooted proto(cx, obj->taggedProto()); ObjectGroup* group = ObjectGroupCompartment::makeGroup(cx, obj->getClass(), proto, initialFlags); if (!group) return nullptr; AutoEnterAnalysis enter(cx); /* Fill in the type according to the state of this object. */ if (obj->is() && obj->as().isInterpreted()) group->setInterpretedFunction(&obj->as()); obj->group_ = group; return group; } /* static */ bool JSObject::setNewGroupUnknown(JSContext* cx, const js::Class* clasp, JS::HandleObject obj) { ObjectGroup::setDefaultNewGroupUnknown(cx, clasp, obj); return JSObject::setFlags(cx, obj, BaseShape::NEW_GROUP_UNKNOWN); } ///////////////////////////////////////////////////////////////////// // ObjectGroupCompartment NewTable ///////////////////////////////////////////////////////////////////// /* * Entries for the per-compartment set of groups which are the default * types to use for some prototype. An optional associated object is used which * allows multiple groups to be created with the same prototype. The * associated object may be a function (for types constructed with 'new') or a * type descriptor (for typed objects). These entries are also used for the set * of lazy groups in the compartment, which use a null associated object * (though there are only a few of these per compartment). */ struct ObjectGroupCompartment::NewEntry { ReadBarrieredObjectGroup group; // Note: This pointer is only used for equality and does not need a read barrier. JSObject* associated; NewEntry(ObjectGroup* group, JSObject* associated) : group(group), associated(associated) {} struct Lookup { const Class* clasp; TaggedProto proto; JSObject* associated; Lookup(const Class* clasp, TaggedProto proto, JSObject* associated) : clasp(clasp), proto(proto), associated(associated) {} bool hasAssocId() const { return !associated || associated->zone()->hasUniqueId(associated); } bool ensureAssocId() const { uint64_t unusedId; return !associated || associated->zoneFromAnyThread()->getUniqueId(associated, &unusedId); } uint64_t getAssocId() const { return associated ? associated->zone()->getUniqueIdInfallible(associated) : 0; } }; static bool hasHash(const Lookup& l) { return l.proto.hasUniqueId() && l.hasAssocId(); } static bool ensureHash(const Lookup& l) { return l.proto.ensureUniqueId() && l.ensureAssocId(); } static inline HashNumber hash(const Lookup& lookup) { MOZ_ASSERT(lookup.proto.hasUniqueId()); MOZ_ASSERT(lookup.hasAssocId()); HashNumber hash = uintptr_t(lookup.clasp); hash = mozilla::RotateLeft(hash, 4) ^ Zone::UniqueIdToHash(lookup.proto.uniqueId()); hash = mozilla::RotateLeft(hash, 4) ^ Zone::UniqueIdToHash(lookup.getAssocId()); return hash; } static inline bool match(const ObjectGroupCompartment::NewEntry& key, const Lookup& lookup) { TaggedProto proto = key.group.unbarrieredGet()->proto().unbarrieredGet(); JSObject* assoc = key.associated; MOZ_ASSERT(proto.hasUniqueId()); MOZ_ASSERT_IF(assoc, assoc->zone()->hasUniqueId(assoc)); MOZ_ASSERT(lookup.proto.hasUniqueId()); MOZ_ASSERT(lookup.hasAssocId()); if (lookup.clasp && key.group.unbarrieredGet()->clasp() != lookup.clasp) return false; if (proto.uniqueId() != lookup.proto.uniqueId()) return false; return !assoc || assoc->zone()->getUniqueIdInfallible(assoc) == lookup.getAssocId(); } static void rekey(NewEntry& k, const NewEntry& newKey) { k = newKey; } bool needsSweep() { return (IsAboutToBeFinalized(&group) || (associated && IsAboutToBeFinalizedUnbarriered(&associated))); } }; namespace js { template <> struct FallibleHashMethods { template static bool hasHash(Lookup&& l) { return ObjectGroupCompartment::NewEntry::hasHash(mozilla::Forward(l)); } template static bool ensureHash(Lookup&& l) { return ObjectGroupCompartment::NewEntry::ensureHash(mozilla::Forward(l)); } }; } // namespace js class ObjectGroupCompartment::NewTable : public JS::WeakCache> { using Table = js::GCHashSet; using Base = JS::WeakCache; public: explicit NewTable(Zone* zone) : Base(zone, Table()) {} }; /* static */ ObjectGroup* ObjectGroup::defaultNewGroup(ExclusiveContext* cx, const Class* clasp, TaggedProto proto, JSObject* associated) { MOZ_ASSERT_IF(associated, proto.isObject()); MOZ_ASSERT_IF(proto.isObject(), cx->isInsideCurrentCompartment(proto.toObject())); // A null lookup clasp is used for 'new' groups with an associated // function. The group starts out as a plain object but might mutate into an // unboxed plain object. MOZ_ASSERT_IF(!clasp, !!associated); AutoEnterAnalysis enter(cx); ObjectGroupCompartment::NewTable*& table = cx->compartment()->objectGroups.defaultNewTable; if (!table) { table = cx->new_(cx->zone()); if (!table || !table->init()) { js_delete(table); table = nullptr; ReportOutOfMemory(cx); return nullptr; } } if (associated && !associated->is()) { MOZ_ASSERT(!clasp); if (associated->is()) { // Canonicalize new functions to use the original one associated with its script. associated = associated->as().maybeCanonicalFunction(); // If we have previously cleared the 'new' script information for this // function, don't try to construct another one. if (associated && associated->wasNewScriptCleared()) associated = nullptr; } else { associated = nullptr; } if (!associated) clasp = &PlainObject::class_; } if (proto.isObject() && !proto.toObject()->isDelegate()) { RootedObject protoObj(cx, proto.toObject()); if (!JSObject::setDelegate(cx, protoObj)) return nullptr; // Objects which are prototypes of one another should be singletons, so // that their type information can be tracked more precisely. Limit // this group change to plain objects, to avoid issues with other types // of singletons like typed arrays. if (protoObj->is() && !protoObj->isSingleton()) { if (!JSObject::changeToSingleton(cx->asJSContext(), protoObj)) return nullptr; } } ObjectGroupCompartment::NewTable::AddPtr p = table->lookupForAdd(ObjectGroupCompartment::NewEntry::Lookup(clasp, proto, associated)); if (p) { ObjectGroup* group = p->group; MOZ_ASSERT_IF(clasp, group->clasp() == clasp); MOZ_ASSERT_IF(!clasp, group->clasp() == &PlainObject::class_ || group->clasp() == &UnboxedPlainObject::class_); MOZ_ASSERT(group->proto() == proto); return group; } ObjectGroupFlags initialFlags = 0; if (proto.isDynamic() || (proto.isObject() && proto.toObject()->isNewGroupUnknown())) initialFlags = OBJECT_FLAG_DYNAMIC_MASK; Rooted protoRoot(cx, proto); ObjectGroup* group = ObjectGroupCompartment::makeGroup(cx, clasp ? clasp : &PlainObject::class_, protoRoot, initialFlags); if (!group) return nullptr; if (!table->add(p, ObjectGroupCompartment::NewEntry(group, associated))) { ReportOutOfMemory(cx); return nullptr; } if (associated) { if (associated->is()) { if (!TypeNewScript::make(cx->asJSContext(), group, &associated->as())) return nullptr; } else { group->setTypeDescr(&associated->as()); } } /* * Some builtin objects have slotful native properties baked in at * creation via the Shape::{insert,get}initialShape mechanism. Since * these properties are never explicitly defined on new objects, update * the type information for them here. */ const JSAtomState& names = cx->names(); if (clasp == &RegExpObject::class_) { AddTypePropertyId(cx, group, nullptr, NameToId(names.lastIndex), TypeSet::Int32Type()); } else if (clasp == &StringObject::class_) { AddTypePropertyId(cx, group, nullptr, NameToId(names.length), TypeSet::Int32Type()); } else if (ErrorObject::isErrorClass(clasp)) { AddTypePropertyId(cx, group, nullptr, NameToId(names.fileName), TypeSet::StringType()); AddTypePropertyId(cx, group, nullptr, NameToId(names.lineNumber), TypeSet::Int32Type()); AddTypePropertyId(cx, group, nullptr, NameToId(names.columnNumber), TypeSet::Int32Type()); } return group; } /* static */ ObjectGroup* ObjectGroup::lazySingletonGroup(ExclusiveContext* cx, const Class* clasp, TaggedProto proto) { MOZ_ASSERT_IF(proto.isObject(), cx->compartment() == proto.toObject()->compartment()); ObjectGroupCompartment::NewTable*& table = cx->compartment()->objectGroups.lazyTable; if (!table) { table = cx->new_(cx->zone()); if (!table || !table->init()) { ReportOutOfMemory(cx); js_delete(table); table = nullptr; return nullptr; } } ObjectGroupCompartment::NewTable::AddPtr p = table->lookupForAdd(ObjectGroupCompartment::NewEntry::Lookup(clasp, proto, nullptr)); if (p) { ObjectGroup* group = p->group; MOZ_ASSERT(group->lazy()); return group; } AutoEnterAnalysis enter(cx); Rooted protoRoot(cx, proto); ObjectGroup* group = ObjectGroupCompartment::makeGroup(cx, clasp, protoRoot, OBJECT_FLAG_SINGLETON | OBJECT_FLAG_LAZY_SINGLETON); if (!group) return nullptr; if (!table->add(p, ObjectGroupCompartment::NewEntry(group, nullptr))) { ReportOutOfMemory(cx); return nullptr; } return group; } /* static */ void ObjectGroup::setDefaultNewGroupUnknown(JSContext* cx, const Class* clasp, HandleObject obj) { // If the object already has a new group, mark that group as unknown. ObjectGroupCompartment::NewTable* table = cx->compartment()->objectGroups.defaultNewTable; if (table) { Rooted taggedProto(cx, TaggedProto(obj)); auto lookup = ObjectGroupCompartment::NewEntry::Lookup(clasp, taggedProto, nullptr); auto p = table->lookup(lookup); if (p) MarkObjectGroupUnknownProperties(cx, p->group); } } #ifdef DEBUG /* static */ bool ObjectGroup::hasDefaultNewGroup(JSObject* proto, const Class* clasp, ObjectGroup* group) { ObjectGroupCompartment::NewTable* table = proto->compartment()->objectGroups.defaultNewTable; if (table) { auto lookup = ObjectGroupCompartment::NewEntry::Lookup(clasp, TaggedProto(proto), nullptr); auto p = table->lookup(lookup); return p && p->group == group; } return false; } #endif /* DEBUG */ inline const Class* GetClassForProtoKey(JSProtoKey key) { switch (key) { case JSProto_Null: case JSProto_Object: return &PlainObject::class_; case JSProto_Array: return &ArrayObject::class_; case JSProto_Number: return &NumberObject::class_; case JSProto_Boolean: return &BooleanObject::class_; case JSProto_String: return &StringObject::class_; case JSProto_Symbol: return &SymbolObject::class_; case JSProto_RegExp: return &RegExpObject::class_; case JSProto_Int8Array: case JSProto_Uint8Array: case JSProto_Int16Array: case JSProto_Uint16Array: case JSProto_Int32Array: case JSProto_Uint32Array: case JSProto_Float32Array: case JSProto_Float64Array: case JSProto_Uint8ClampedArray: return &TypedArrayObject::classes[key - JSProto_Int8Array]; case JSProto_ArrayBuffer: return &ArrayBufferObject::class_; case JSProto_SharedArrayBuffer: return &SharedArrayBufferObject::class_; case JSProto_DataView: return &DataViewObject::class_; default: MOZ_CRASH("Bad proto key"); } } /* static */ ObjectGroup* ObjectGroup::defaultNewGroup(JSContext* cx, JSProtoKey key) { RootedObject proto(cx); if (key != JSProto_Null && !GetBuiltinPrototype(cx, key, &proto)) return nullptr; return defaultNewGroup(cx, GetClassForProtoKey(key), TaggedProto(proto.get())); } ///////////////////////////////////////////////////////////////////// // ObjectGroupCompartment ArrayObjectTable ///////////////////////////////////////////////////////////////////// struct ObjectGroupCompartment::ArrayObjectKey : public DefaultHasher { TypeSet::Type type; ArrayObjectKey() : type(TypeSet::UndefinedType()) {} explicit ArrayObjectKey(TypeSet::Type type) : type(type) {} static inline uint32_t hash(const ArrayObjectKey& v) { return v.type.raw(); } static inline bool match(const ArrayObjectKey& v1, const ArrayObjectKey& v2) { return v1.type == v2.type; } bool operator==(const ArrayObjectKey& other) { return type == other.type; } bool operator!=(const ArrayObjectKey& other) { return !(*this == other); } bool needsSweep() { MOZ_ASSERT(type.isUnknown() || !type.isSingleton()); if (!type.isUnknown() && type.isGroup()) { ObjectGroup* group = type.groupNoBarrier(); if (IsAboutToBeFinalizedUnbarriered(&group)) return true; if (group != type.groupNoBarrier()) type = TypeSet::ObjectType(group); } return false; } }; static inline bool NumberTypes(TypeSet::Type a, TypeSet::Type b) { return (a.isPrimitive(JSVAL_TYPE_INT32) || a.isPrimitive(JSVAL_TYPE_DOUBLE)) && (b.isPrimitive(JSVAL_TYPE_INT32) || b.isPrimitive(JSVAL_TYPE_DOUBLE)); } /* * As for GetValueType, but requires object types to be non-singletons with * their default prototype. These are the only values that should appear in * arrays and objects whose type can be fixed. */ static inline TypeSet::Type GetValueTypeForTable(const Value& v) { TypeSet::Type type = TypeSet::GetValueType(v); MOZ_ASSERT(!type.isSingleton()); return type; } /* static */ ArrayObject* ObjectGroup::newArrayObject(ExclusiveContext* cx, const Value* vp, size_t length, NewObjectKind newKind, NewArrayKind arrayKind) { MOZ_ASSERT(newKind != SingletonObject); // If we are making a copy on write array, don't try to adjust the group as // getOrFixupCopyOnWriteObject will do this before any objects are copied // from this one. if (arrayKind == NewArrayKind::CopyOnWrite) { ArrayObject* obj = NewDenseCopiedArray(cx, length, vp, nullptr, newKind); if (!obj || !ObjectElements::MakeElementsCopyOnWrite(cx, obj)) return nullptr; return obj; } // Get a type which captures all the elements in the array to be created. Rooted elementType(cx, TypeSet::UnknownType()); if (arrayKind != NewArrayKind::UnknownIndex && length != 0) { elementType = GetValueTypeForTable(vp[0]); for (unsigned i = 1; i < length; i++) { TypeSet::Type ntype = GetValueTypeForTable(vp[i]); if (ntype != elementType) { if (NumberTypes(elementType, ntype)) { elementType = TypeSet::DoubleType(); } else { elementType = TypeSet::UnknownType(); break; } } } } ObjectGroupCompartment::ArrayObjectTable*& table = cx->compartment()->objectGroups.arrayObjectTable; if (!table) { table = cx->new_(); if (!table || !table->init()) { ReportOutOfMemory(cx); js_delete(table); table = nullptr; return nullptr; } } ObjectGroupCompartment::ArrayObjectKey key(elementType); DependentAddPtr p(cx, *table, key); RootedObjectGroup group(cx); if (p) { group = p->value(); } else { RootedObject proto(cx); if (!GetBuiltinPrototype(cx, JSProto_Array, &proto)) return nullptr; Rooted taggedProto(cx, TaggedProto(proto)); group = ObjectGroupCompartment::makeGroup(cx, &ArrayObject::class_, taggedProto); if (!group) return nullptr; AddTypePropertyId(cx, group, nullptr, JSID_VOID, elementType); if (!p.add(cx, *table, ObjectGroupCompartment::ArrayObjectKey(elementType), group)) return nullptr; } // The type of the elements being added will already be reflected in type // information. ShouldUpdateTypes updateTypes = ShouldUpdateTypes::DontUpdate; return NewCopiedArrayTryUseGroup(cx, group, vp, length, newKind, updateTypes); } // Try to change the group of |source| to match that of |target|. static bool GiveObjectGroup(ExclusiveContext* cx, JSObject* source, JSObject* target) { MOZ_ASSERT(source->group() != target->group()); if (!target->is() || !source->is()) { return true; } source->setGroup(target->group()); for (size_t i = 0; i < source->as().getDenseInitializedLength(); i++) { Value v = source->as().getDenseElement(i); AddTypePropertyId(cx, source->group(), source, JSID_VOID, v); } return true; } static bool SameGroup(JSObject* first, JSObject* second) { return first->group() == second->group(); } // When generating a multidimensional array of literals, such as // [[1,2],[3,4],[5.5,6.5]], try to ensure that each element of the array has // the same group. This is mainly important when the elements might have // different native vs. unboxed layouts, or different unboxed layouts, and // accessing the heterogenous layouts from JIT code will be much slower than // if they were homogenous. // // To do this, with each new array element we compare it with one of the // previous ones, and try to mutate the group of the new element to fit that // of the old element. If this isn't possible, the groups for all old elements // are mutated to fit that of the new element. bool js::CombineArrayElementTypes(ExclusiveContext* cx, JSObject* newObj, const Value* compare, size_t ncompare) { if (!ncompare || !compare[0].isObject()) return true; JSObject* oldObj = &compare[0].toObject(); if (SameGroup(oldObj, newObj)) return true; if (!GiveObjectGroup(cx, newObj, oldObj)) return false; if (SameGroup(oldObj, newObj)) return true; if (!GiveObjectGroup(cx, oldObj, newObj)) return false; if (SameGroup(oldObj, newObj)) { for (size_t i = 1; i < ncompare; i++) { if (compare[i].isObject() && !SameGroup(&compare[i].toObject(), newObj)) { if (!GiveObjectGroup(cx, &compare[i].toObject(), newObj)) return false; } } } return true; } // Similarly to CombineArrayElementTypes, if we are generating an array of // plain objects with a consistent property layout, such as // [{p:[1,2]},{p:[3,4]},{p:[5.5,6.5]}], where those plain objects in // turn have arrays as their own properties, try to ensure that a consistent // group is given to each array held by the same property of the plain objects. bool js::CombinePlainObjectPropertyTypes(ExclusiveContext* cx, JSObject* newObj, const Value* compare, size_t ncompare) { if (!ncompare || !compare[0].isObject()) return true; JSObject* oldObj = &compare[0].toObject(); if (!SameGroup(oldObj, newObj)) return true; if (newObj->is()) { if (newObj->as().lastProperty() != oldObj->as().lastProperty()) return true; for (size_t slot = 0; slot < newObj->as().slotSpan(); slot++) { Value newValue = newObj->as().getSlot(slot); Value oldValue = oldObj->as().getSlot(slot); if (!newValue.isObject() || !oldValue.isObject()) continue; JSObject* newInnerObj = &newValue.toObject(); JSObject* oldInnerObj = &oldValue.toObject(); if (SameGroup(oldInnerObj, newInnerObj)) continue; if (!GiveObjectGroup(cx, newInnerObj, oldInnerObj)) return false; if (SameGroup(oldInnerObj, newInnerObj)) continue; if (!GiveObjectGroup(cx, oldInnerObj, newInnerObj)) return false; if (SameGroup(oldInnerObj, newInnerObj)) { for (size_t i = 1; i < ncompare; i++) { if (compare[i].isObject() && SameGroup(&compare[i].toObject(), newObj)) { Value otherValue = compare[i].toObject().as().getSlot(slot); if (otherValue.isObject() && !SameGroup(&otherValue.toObject(), newInnerObj)) { if (!GiveObjectGroup(cx, &otherValue.toObject(), newInnerObj)) return false; } } } } } } else if (newObj->is()) { const UnboxedLayout& layout = newObj->as().layout(); const int32_t* traceList = layout.traceList(); if (!traceList) return true; uint8_t* newData = newObj->as().data(); uint8_t* oldData = oldObj->as().data(); for (; *traceList != -1; traceList++) {} traceList++; for (; *traceList != -1; traceList++) { JSObject* newInnerObj = *reinterpret_cast(newData + *traceList); JSObject* oldInnerObj = *reinterpret_cast(oldData + *traceList); if (!newInnerObj || !oldInnerObj || SameGroup(oldInnerObj, newInnerObj)) continue; if (!GiveObjectGroup(cx, newInnerObj, oldInnerObj)) return false; if (SameGroup(oldInnerObj, newInnerObj)) continue; if (!GiveObjectGroup(cx, oldInnerObj, newInnerObj)) return false; if (SameGroup(oldInnerObj, newInnerObj)) { for (size_t i = 1; i < ncompare; i++) { if (compare[i].isObject() && SameGroup(&compare[i].toObject(), newObj)) { uint8_t* otherData = compare[i].toObject().as().data(); JSObject* otherInnerObj = *reinterpret_cast(otherData + *traceList); if (otherInnerObj && !SameGroup(otherInnerObj, newInnerObj)) { if (!GiveObjectGroup(cx, otherInnerObj, newInnerObj)) return false; } } } } } } return true; } ///////////////////////////////////////////////////////////////////// // ObjectGroupCompartment PlainObjectTable ///////////////////////////////////////////////////////////////////// struct ObjectGroupCompartment::PlainObjectKey { jsid* properties; uint32_t nproperties; struct Lookup { IdValuePair* properties; uint32_t nproperties; Lookup(IdValuePair* properties, uint32_t nproperties) : properties(properties), nproperties(nproperties) {} }; static inline HashNumber hash(const Lookup& lookup) { return (HashNumber) (HashId(lookup.properties[lookup.nproperties - 1].id) ^ lookup.nproperties); } static inline bool match(const PlainObjectKey& v, const Lookup& lookup) { if (lookup.nproperties != v.nproperties) return false; for (size_t i = 0; i < lookup.nproperties; i++) { if (lookup.properties[i].id != v.properties[i]) return false; } return true; } bool needsSweep() { for (unsigned i = 0; i < nproperties; i++) { if (gc::IsAboutToBeFinalizedUnbarriered(&properties[i])) return true; } return false; } }; struct ObjectGroupCompartment::PlainObjectEntry { ReadBarrieredObjectGroup group; ReadBarrieredShape shape; TypeSet::Type* types; bool needsSweep(unsigned nproperties) { if (IsAboutToBeFinalized(&group)) return true; if (IsAboutToBeFinalized(&shape)) return true; for (unsigned i = 0; i < nproperties; i++) { MOZ_ASSERT(!types[i].isSingleton()); if (types[i].isGroup()) { ObjectGroup* group = types[i].groupNoBarrier(); if (IsAboutToBeFinalizedUnbarriered(&group)) return true; if (group != types[i].groupNoBarrier()) types[i] = TypeSet::ObjectType(group); } } return false; } }; static bool CanShareObjectGroup(IdValuePair* properties, size_t nproperties) { // Don't reuse groups for objects containing indexed properties, which // might end up as dense elements. for (size_t i = 0; i < nproperties; i++) { uint32_t index; if (IdIsIndex(properties[i].id, &index)) return false; } return true; } static bool AddPlainObjectProperties(ExclusiveContext* cx, HandlePlainObject obj, IdValuePair* properties, size_t nproperties) { RootedId propid(cx); RootedValue value(cx); for (size_t i = 0; i < nproperties; i++) { propid = properties[i].id; value = properties[i].value; if (!NativeDefineProperty(cx, obj, propid, value, nullptr, nullptr, JSPROP_ENUMERATE)) return false; } return true; } PlainObject* js::NewPlainObjectWithProperties(ExclusiveContext* cx, IdValuePair* properties, size_t nproperties, NewObjectKind newKind) { gc::AllocKind allocKind = gc::GetGCObjectKind(nproperties); RootedPlainObject obj(cx, NewBuiltinClassInstance(cx, allocKind, newKind)); if (!obj || !AddPlainObjectProperties(cx, obj, properties, nproperties)) return nullptr; return obj; } /* static */ JSObject* ObjectGroup::newPlainObject(ExclusiveContext* cx, IdValuePair* properties, size_t nproperties, NewObjectKind newKind) { // Watch for simple cases where we don't try to reuse plain object groups. if (newKind == SingletonObject || nproperties == 0 || nproperties >= PropertyTree::MAX_HEIGHT) return NewPlainObjectWithProperties(cx, properties, nproperties, newKind); ObjectGroupCompartment::PlainObjectTable*& table = cx->compartment()->objectGroups.plainObjectTable; if (!table) { table = cx->new_(); if (!table || !table->init()) { ReportOutOfMemory(cx); js_delete(table); table = nullptr; return nullptr; } } ObjectGroupCompartment::PlainObjectKey::Lookup lookup(properties, nproperties); ObjectGroupCompartment::PlainObjectTable::Ptr p = table->lookup(lookup); if (!p) { if (!CanShareObjectGroup(properties, nproperties)) return NewPlainObjectWithProperties(cx, properties, nproperties, newKind); RootedObject proto(cx); if (!GetBuiltinPrototype(cx, JSProto_Object, &proto)) return nullptr; Rooted tagged(cx, TaggedProto(proto)); RootedObjectGroup group(cx, ObjectGroupCompartment::makeGroup(cx, &PlainObject::class_, tagged)); if (!group) return nullptr; gc::AllocKind allocKind = gc::GetGCObjectKind(nproperties); RootedPlainObject obj(cx, NewObjectWithGroup(cx, group, allocKind, TenuredObject)); if (!obj || !AddPlainObjectProperties(cx, obj, properties, nproperties)) return nullptr; // Don't make entries with duplicate property names, which will show up // here as objects with fewer properties than we thought we were // adding to the object. In this case, reset the object's group to the // default (which will have unknown properties) so that the group we // just created will be collected by the GC. if (obj->slotSpan() != nproperties) { ObjectGroup* group = defaultNewGroup(cx, obj->getClass(), obj->taggedProto()); if (!group) return nullptr; obj->setGroup(group); return obj; } // Keep track of the initial objects we create with this type. // If the initial ones have a consistent shape and property types, we // will try to use an unboxed layout for the group. PreliminaryObjectArrayWithTemplate* preliminaryObjects = cx->new_(obj->lastProperty()); if (!preliminaryObjects) return nullptr; group->setPreliminaryObjects(preliminaryObjects); preliminaryObjects->registerNewObject(obj); ScopedJSFreePtr ids(group->zone()->pod_calloc(nproperties)); if (!ids) { ReportOutOfMemory(cx); return nullptr; } ScopedJSFreePtr types( group->zone()->pod_calloc(nproperties)); if (!types) { ReportOutOfMemory(cx); return nullptr; } for (size_t i = 0; i < nproperties; i++) { ids[i] = properties[i].id; types[i] = GetValueTypeForTable(obj->getSlot(i)); AddTypePropertyId(cx, group, nullptr, IdToTypeId(ids[i]), types[i]); } ObjectGroupCompartment::PlainObjectKey key; key.properties = ids; key.nproperties = nproperties; MOZ_ASSERT(ObjectGroupCompartment::PlainObjectKey::match(key, lookup)); ObjectGroupCompartment::PlainObjectEntry entry; entry.group.set(group); entry.shape.set(obj->lastProperty()); entry.types = types; ObjectGroupCompartment::PlainObjectTable::AddPtr np = table->lookupForAdd(lookup); if (!table->add(np, key, entry)) { ReportOutOfMemory(cx); return nullptr; } ids.forget(); types.forget(); return obj; } RootedObjectGroup group(cx, p->value().group); // Watch for existing groups which now use an unboxed layout. if (group->maybeUnboxedLayout()) { MOZ_ASSERT(group->unboxedLayout().properties().length() == nproperties); return UnboxedPlainObject::createWithProperties(cx, group, newKind, properties); } // Update property types according to the properties we are about to add. // Do this before we do anything which can GC, which might move or remove // this table entry. if (!group->unknownProperties()) { for (size_t i = 0; i < nproperties; i++) { TypeSet::Type type = p->value().types[i]; TypeSet::Type ntype = GetValueTypeForTable(properties[i].value); if (ntype == type) continue; if (ntype.isPrimitive(JSVAL_TYPE_INT32) && type.isPrimitive(JSVAL_TYPE_DOUBLE)) { // The property types already reflect 'int32'. } else { if (ntype.isPrimitive(JSVAL_TYPE_DOUBLE) && type.isPrimitive(JSVAL_TYPE_INT32)) { // Include 'double' in the property types to avoid the update below later. p->value().types[i] = TypeSet::DoubleType(); } AddTypePropertyId(cx, group, nullptr, IdToTypeId(properties[i].id), ntype); } } } RootedShape shape(cx, p->value().shape); if (group->maybePreliminaryObjects()) newKind = TenuredObject; gc::AllocKind allocKind = gc::GetGCObjectKind(nproperties); RootedPlainObject obj(cx, NewObjectWithGroup(cx, group, allocKind, newKind)); if (!obj || !obj->setLastProperty(cx, shape)) return nullptr; for (size_t i = 0; i < nproperties; i++) obj->setSlot(i, properties[i].value); if (group->maybePreliminaryObjects()) { group->maybePreliminaryObjects()->registerNewObject(obj); group->maybePreliminaryObjects()->maybeAnalyze(cx, group); } return obj; } ///////////////////////////////////////////////////////////////////// // ObjectGroupCompartment AllocationSiteTable ///////////////////////////////////////////////////////////////////// struct ObjectGroupCompartment::AllocationSiteKey : public DefaultHasher { ReadBarrieredScript script; uint32_t offset : 24; JSProtoKey kind : 8; ReadBarrieredObject proto; static const uint32_t OFFSET_LIMIT = (1 << 23); AllocationSiteKey(JSScript* script_, uint32_t offset_, JSProtoKey kind_, JSObject* proto_) : script(script_), offset(offset_), kind(kind_), proto(proto_) { MOZ_ASSERT(offset_ < OFFSET_LIMIT); } AllocationSiteKey(const AllocationSiteKey& key) : script(key.script), offset(key.offset), kind(key.kind), proto(key.proto) { } AllocationSiteKey(AllocationSiteKey&& key) : script(mozilla::Move(key.script)), offset(key.offset), kind(key.kind), proto(mozilla::Move(key.proto)) { } void operator=(AllocationSiteKey&& key) { script = mozilla::Move(key.script); offset = key.offset; kind = key.kind; proto = mozilla::Move(key.proto); } static inline uint32_t hash(AllocationSiteKey key) { return uint32_t(size_t(key.script->offsetToPC(key.offset)) ^ key.kind ^ MovableCellHasher::hash(key.proto)); } static inline bool match(const AllocationSiteKey& a, const AllocationSiteKey& b) { return DefaultHasher::match(a.script, b.script) && a.offset == b.offset && a.kind == b.kind && MovableCellHasher::match(a.proto, b.proto); } void trace(JSTracer* trc) { TraceRoot(trc, &script, "AllocationSiteKey script"); TraceNullableRoot(trc, &proto, "AllocationSiteKey proto"); } bool needsSweep() { return IsAboutToBeFinalizedUnbarriered(script.unsafeGet()) || (proto && IsAboutToBeFinalizedUnbarriered(proto.unsafeGet())); } }; class ObjectGroupCompartment::AllocationSiteTable : public JS::WeakCache> { using Table = js::GCHashMap; using Base = JS::WeakCache
; public: explicit AllocationSiteTable(Zone* zone) : Base(zone, Table()) {} }; /* static */ ObjectGroup* ObjectGroup::allocationSiteGroup(JSContext* cx, JSScript* scriptArg, jsbytecode* pc, JSProtoKey kind, HandleObject protoArg /* = nullptr */) { MOZ_ASSERT(!useSingletonForAllocationSite(scriptArg, pc, kind)); MOZ_ASSERT_IF(protoArg, kind == JSProto_Array); uint32_t offset = scriptArg->pcToOffset(pc); if (offset >= ObjectGroupCompartment::AllocationSiteKey::OFFSET_LIMIT) { if (protoArg) return defaultNewGroup(cx, GetClassForProtoKey(kind), TaggedProto(protoArg)); return defaultNewGroup(cx, kind); } ObjectGroupCompartment::AllocationSiteTable*& table = cx->compartment()->objectGroups.allocationSiteTable; if (!table) { table = cx->new_(cx->zone()); if (!table || !table->init()) { ReportOutOfMemory(cx); js_delete(table); table = nullptr; return nullptr; } } RootedScript script(cx, scriptArg); RootedObject proto(cx, protoArg); if (!proto && kind != JSProto_Null && !GetBuiltinPrototype(cx, kind, &proto)) return nullptr; Rooted key(cx, ObjectGroupCompartment::AllocationSiteKey(script, offset, kind, proto)); ObjectGroupCompartment::AllocationSiteTable::AddPtr p = table->lookupForAdd(key); if (p) return p->value(); AutoEnterAnalysis enter(cx); Rooted tagged(cx, TaggedProto(proto)); ObjectGroup* res = ObjectGroupCompartment::makeGroup(cx, GetClassForProtoKey(kind), tagged, OBJECT_FLAG_FROM_ALLOCATION_SITE); if (!res) return nullptr; if (JSOp(*pc) == JSOP_NEWOBJECT) { // Keep track of the preliminary objects with this group, so we can try // to use an unboxed layout for the object once some are allocated. Shape* shape = script->getObject(pc)->as().lastProperty(); if (!shape->isEmptyShape()) { PreliminaryObjectArrayWithTemplate* preliminaryObjects = cx->new_(shape); if (preliminaryObjects) res->setPreliminaryObjects(preliminaryObjects); else cx->recoverFromOutOfMemory(); } } if (!table->add(p, key, res)) { ReportOutOfMemory(cx); return nullptr; } return res; } void ObjectGroupCompartment::replaceAllocationSiteGroup(JSScript* script, jsbytecode* pc, JSProtoKey kind, ObjectGroup* group) { AllocationSiteKey key(script, script->pcToOffset(pc), kind, group->proto().toObjectOrNull()); AllocationSiteTable::Ptr p = allocationSiteTable->lookup(key); MOZ_RELEASE_ASSERT(p); allocationSiteTable->get().remove(p); { AutoEnterOOMUnsafeRegion oomUnsafe; if (!allocationSiteTable->putNew(key, group)) oomUnsafe.crash("Inconsistent object table"); } } /* static */ ObjectGroup* ObjectGroup::callingAllocationSiteGroup(JSContext* cx, JSProtoKey key, HandleObject proto) { MOZ_ASSERT_IF(proto, key == JSProto_Array); jsbytecode* pc; RootedScript script(cx, cx->currentScript(&pc)); if (script) return allocationSiteGroup(cx, script, pc, key, proto); if (proto) return defaultNewGroup(cx, GetClassForProtoKey(key), TaggedProto(proto)); return defaultNewGroup(cx, key); } /* static */ bool ObjectGroup::setAllocationSiteObjectGroup(JSContext* cx, HandleScript script, jsbytecode* pc, HandleObject obj, bool singleton) { JSProtoKey key = JSCLASS_CACHED_PROTO_KEY(obj->getClass()); MOZ_ASSERT(key != JSProto_Null); MOZ_ASSERT(singleton == useSingletonForAllocationSite(script, pc, key)); if (singleton) { MOZ_ASSERT(obj->isSingleton()); /* * Inference does not account for types of run-once initializer * objects, as these may not be created until after the script * has been analyzed. */ TypeScript::Monitor(cx, script, pc, ObjectValue(*obj)); } else { ObjectGroup* group = allocationSiteGroup(cx, script, pc, key); if (!group) return false; obj->setGroup(group); } return true; } /* static */ ArrayObject* ObjectGroup::getOrFixupCopyOnWriteObject(JSContext* cx, HandleScript script, jsbytecode* pc) { // Make sure that the template object for script/pc has a type indicating // that the object and its copies have copy on write elements. RootedArrayObject obj(cx, &script->getObject(GET_UINT32_INDEX(pc))->as()); MOZ_ASSERT(obj->denseElementsAreCopyOnWrite()); if (obj->group()->fromAllocationSite()) { MOZ_ASSERT(obj->group()->hasAnyFlags(OBJECT_FLAG_COPY_ON_WRITE)); return obj; } RootedObjectGroup group(cx, allocationSiteGroup(cx, script, pc, JSProto_Array)); if (!group) return nullptr; group->addFlags(OBJECT_FLAG_COPY_ON_WRITE); // Update type information in the initializer object group. MOZ_ASSERT(obj->slotSpan() == 0); for (size_t i = 0; i < obj->getDenseInitializedLength(); i++) { const Value& v = obj->getDenseElement(i); AddTypePropertyId(cx, group, nullptr, JSID_VOID, v); } obj->setGroup(group); return obj; } /* static */ ArrayObject* ObjectGroup::getCopyOnWriteObject(JSScript* script, jsbytecode* pc) { // getOrFixupCopyOnWriteObject should already have been called for // script/pc, ensuring that the template object has a group with the // COPY_ON_WRITE flag. We don't assert this here, due to a corner case // where this property doesn't hold. See jsop_newarray_copyonwrite in // IonBuilder. ArrayObject* obj = &script->getObject(GET_UINT32_INDEX(pc))->as(); MOZ_ASSERT(obj->denseElementsAreCopyOnWrite()); return obj; } /* static */ bool ObjectGroup::findAllocationSite(JSContext* cx, ObjectGroup* group, JSScript** script, uint32_t* offset) { *script = nullptr; *offset = 0; const ObjectGroupCompartment::AllocationSiteTable* table = cx->compartment()->objectGroups.allocationSiteTable; if (!table) return false; for (ObjectGroupCompartment::AllocationSiteTable::Range r = table->all(); !r.empty(); r.popFront()) { if (group == r.front().value()) { *script = r.front().key().script; *offset = r.front().key().offset; return true; } } return false; } ///////////////////////////////////////////////////////////////////// // ObjectGroupCompartment ///////////////////////////////////////////////////////////////////// ObjectGroupCompartment::ObjectGroupCompartment() { PodZero(this); } ObjectGroupCompartment::~ObjectGroupCompartment() { js_delete(defaultNewTable); js_delete(lazyTable); js_delete(arrayObjectTable); js_delete(plainObjectTable); js_delete(allocationSiteTable); } void ObjectGroupCompartment::removeDefaultNewGroup(const Class* clasp, TaggedProto proto, JSObject* associated) { auto p = defaultNewTable->lookup(NewEntry::Lookup(clasp, proto, associated)); MOZ_RELEASE_ASSERT(p); defaultNewTable->get().remove(p); } void ObjectGroupCompartment::replaceDefaultNewGroup(const Class* clasp, TaggedProto proto, JSObject* associated, ObjectGroup* group) { NewEntry::Lookup lookup(clasp, proto, associated); auto p = defaultNewTable->lookup(lookup); MOZ_RELEASE_ASSERT(p); defaultNewTable->get().remove(p); { AutoEnterOOMUnsafeRegion oomUnsafe; if (!defaultNewTable->putNew(lookup, NewEntry(group, associated))) oomUnsafe.crash("Inconsistent object table"); } } /* static */ ObjectGroup* ObjectGroupCompartment::makeGroup(ExclusiveContext* cx, const Class* clasp, Handle proto, ObjectGroupFlags initialFlags /* = 0 */) { MOZ_ASSERT_IF(proto.isObject(), cx->isInsideCurrentCompartment(proto.toObject())); ObjectGroup* group = Allocate(cx); if (!group) return nullptr; new(group) ObjectGroup(clasp, proto, cx->compartment(), initialFlags); return group; } void ObjectGroupCompartment::addSizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf, size_t* allocationSiteTables, size_t* arrayObjectGroupTables, size_t* plainObjectGroupTables, size_t* compartmentTables) { if (allocationSiteTable) *allocationSiteTables += allocationSiteTable->sizeOfIncludingThis(mallocSizeOf); if (arrayObjectTable) *arrayObjectGroupTables += arrayObjectTable->sizeOfIncludingThis(mallocSizeOf); if (plainObjectTable) { *plainObjectGroupTables += plainObjectTable->sizeOfIncludingThis(mallocSizeOf); for (PlainObjectTable::Enum e(*plainObjectTable); !e.empty(); e.popFront()) { const PlainObjectKey& key = e.front().key(); const PlainObjectEntry& value = e.front().value(); /* key.ids and values.types have the same length. */ *plainObjectGroupTables += mallocSizeOf(key.properties) + mallocSizeOf(value.types); } } if (defaultNewTable) *compartmentTables += defaultNewTable->sizeOfIncludingThis(mallocSizeOf); if (lazyTable) *compartmentTables += lazyTable->sizeOfIncludingThis(mallocSizeOf); } void ObjectGroupCompartment::clearTables() { if (allocationSiteTable && allocationSiteTable->initialized()) allocationSiteTable->clear(); if (arrayObjectTable && arrayObjectTable->initialized()) arrayObjectTable->clear(); if (plainObjectTable && plainObjectTable->initialized()) { for (PlainObjectTable::Enum e(*plainObjectTable); !e.empty(); e.popFront()) { const PlainObjectKey& key = e.front().key(); PlainObjectEntry& entry = e.front().value(); js_free(key.properties); js_free(entry.types); } plainObjectTable->clear(); } if (defaultNewTable && defaultNewTable->initialized()) defaultNewTable->clear(); if (lazyTable && lazyTable->initialized()) lazyTable->clear(); } /* static */ bool ObjectGroupCompartment::PlainObjectTableSweepPolicy::needsSweep(PlainObjectKey* key, PlainObjectEntry* entry) { if (!(JS::GCPolicy::needsSweep(key) || entry->needsSweep(key->nproperties))) return false; js_free(key->properties); js_free(entry->types); return true; } void ObjectGroupCompartment::sweep(FreeOp* fop) { /* * Iterate through the array/object group tables and remove all entries * referencing collected data. These tables only hold weak references. */ if (arrayObjectTable) arrayObjectTable->sweep(); if (plainObjectTable) plainObjectTable->sweep(); } void ObjectGroupCompartment::fixupNewTableAfterMovingGC(NewTable* table) { /* * Each entry's hash depends on the object's prototype and we can't tell * whether that has been moved or not in sweepNewObjectGroupTable(). */ if (table && table->initialized()) { for (NewTable::Enum e(*table); !e.empty(); e.popFront()) { NewEntry& entry = e.mutableFront(); ObjectGroup* group = entry.group.unbarrieredGet(); if (IsForwarded(group)) { group = Forwarded(group); entry.group.set(group); } TaggedProto proto = group->proto(); if (proto.isObject() && IsForwarded(proto.toObject())) { proto = TaggedProto(Forwarded(proto.toObject())); // Update the group's proto here so that we are able to lookup // entries in this table before all object pointers are updated. group->proto() = proto; } if (entry.associated && IsForwarded(entry.associated)) entry.associated = Forwarded(entry.associated); } } } #ifdef JSGC_HASH_TABLE_CHECKS void ObjectGroupCompartment::checkNewTableAfterMovingGC(NewTable* table) { /* * Assert that nothing points into the nursery or needs to be relocated, and * that the hash table entries are discoverable. */ if (!table || !table->initialized()) return; for (NewTable::Enum e(*table); !e.empty(); e.popFront()) { NewEntry entry = e.front(); CheckGCThingAfterMovingGC(entry.group.unbarrieredGet()); TaggedProto proto = entry.group.unbarrieredGet()->proto(); if (proto.isObject()) CheckGCThingAfterMovingGC(proto.toObject()); CheckGCThingAfterMovingGC(entry.associated); const Class* clasp = entry.group.unbarrieredGet()->clasp(); if (entry.associated && entry.associated->is()) clasp = nullptr; NewEntry::Lookup lookup(clasp, proto, entry.associated); auto ptr = table->lookup(lookup); MOZ_RELEASE_ASSERT(ptr.found() && &*ptr == &e.front()); } } #endif // JSGC_HASH_TABLE_CHECKS