/* -*- 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 js_RootingAPI_h #define js_RootingAPI_h #include "mozilla/Attributes.h" #include "mozilla/DebugOnly.h" #include "mozilla/GuardObjects.h" #include "mozilla/LinkedList.h" #include "mozilla/TypeTraits.h" #include "jspubtd.h" #include "js/GCAPI.h" #include "js/HeapAPI.h" #include "js/TypeDecls.h" #include "js/Utility.h" /* * Moving GC Stack Rooting * * A moving GC may change the physical location of GC allocated things, even * when they are rooted, updating all pointers to the thing to refer to its new * location. The GC must therefore know about all live pointers to a thing, * not just one of them, in order to behave correctly. * * The |Rooted| and |Handle| classes below are used to root stack locations * whose value may be held live across a call that can trigger GC. For a * code fragment such as: * * JSObject* obj = NewObject(cx); * DoSomething(cx); * ... = obj->lastProperty(); * * If |DoSomething()| can trigger a GC, the stack location of |obj| must be * rooted to ensure that the GC does not move the JSObject referred to by * |obj| without updating |obj|'s location itself. This rooting must happen * regardless of whether there are other roots which ensure that the object * itself will not be collected. * * If |DoSomething()| cannot trigger a GC, and the same holds for all other * calls made between |obj|'s definitions and its last uses, then no rooting * is required. * * SpiderMonkey can trigger a GC at almost any time and in ways that are not * always clear. For example, the following innocuous-looking actions can * cause a GC: allocation of any new GC thing; JSObject::hasProperty; * JS_ReportError and friends; and ToNumber, among many others. The following * dangerous-looking actions cannot trigger a GC: js_malloc, cx->malloc_, * rt->malloc_, and friends and JS_ReportOutOfMemory. * * The following family of three classes will exactly root a stack location. * Incorrect usage of these classes will result in a compile error in almost * all cases. Therefore, it is very hard to be incorrectly rooted if you use * these classes exclusively. These classes are all templated on the type T of * the value being rooted. * * - Rooted declares a variable of type T, whose value is always rooted. * Rooted may be automatically coerced to a Handle, below. Rooted * should be used whenever a local variable's value may be held live across a * call which can trigger a GC. * * - Handle is a const reference to a Rooted. Functions which take GC * things or values as arguments and need to root those arguments should * generally use handles for those arguments and avoid any explicit rooting. * This has two benefits. First, when several such functions call each other * then redundant rooting of multiple copies of the GC thing can be avoided. * Second, if the caller does not pass a rooted value a compile error will be * generated, which is quicker and easier to fix than when relying on a * separate rooting analysis. * * - MutableHandle is a non-const reference to Rooted. It is used in the * same way as Handle and includes a |set(const T& v)| method to allow * updating the value of the referenced Rooted. A MutableHandle can be * created from a Rooted by using |Rooted::operator&()|. * * In some cases the small performance overhead of exact rooting (measured to * be a few nanoseconds on desktop) is too much. In these cases, try the * following: * * - Move all Rooted above inner loops: this allows you to re-use the root * on each iteration of the loop. * * - Pass Handle through your hot call stack to avoid re-rooting costs at * every invocation. * * The following diagram explains the list of supported, implicit type * conversions between classes of this family: * * Rooted ----> Handle * | ^ * | | * | | * +---> MutableHandle * (via &) * * All of these types have an implicit conversion to raw pointers. */ namespace js { template struct GCMethods {}; template class RootedBase {}; template class HandleBase {}; template class MutableHandleBase {}; template class HeapBase {}; template class PersistentRootedBase {}; /* * js::NullPtr acts like a nullptr pointer in contexts that require a Handle. * * Handle provides an implicit constructor for js::NullPtr so that, given: * foo(Handle h); * callers can simply write: * foo(js::NullPtr()); * which avoids creating a Rooted just to pass nullptr. * * This is the SpiderMonkey internal variant. js::NullPtr should be used in * preference to JS::NullPtr to avoid the GOT access required for JS_PUBLIC_API * symbols. */ struct NullPtr { static void * const constNullValue; }; namespace gc { struct Cell; template struct PersistentRootedMarker; } /* namespace gc */ #define DECLARE_POINTER_COMPARISON_OPS(T) \ bool operator==(const T& other) const { return get() == other; } \ bool operator!=(const T& other) const { return get() != other; } // Important: Return a reference so passing a Rooted, etc. to // something that takes a |const T&| is not a GC hazard. #define DECLARE_POINTER_CONSTREF_OPS(T) \ operator const T&() const { return get(); } \ const T& operator->() const { return get(); } // Assignment operators on a base class are hidden by the implicitly defined // operator= on the derived class. Thus, define the operator= directly on the // class as we would need to manually pass it through anyway. #define DECLARE_POINTER_ASSIGN_OPS(Wrapper, T) \ Wrapper& operator=(const T& p) { \ set(p); \ return *this; \ } \ Wrapper& operator=(const Wrapper& other) { \ set(other.get()); \ return *this; \ } \ #define DELETE_ASSIGNMENT_OPS(Wrapper, T) \ template Wrapper& operator=(S) = delete; \ Wrapper& operator=(const Wrapper&) = delete; #define DECLARE_NONPOINTER_ACCESSOR_METHODS(ptr) \ const T* address() const { return &(ptr); } \ const T& get() const { return (ptr); } \ #define DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(ptr) \ T* address() { return &(ptr); } \ T& get() { return (ptr); } \ } /* namespace js */ namespace JS { template class Rooted; template class PersistentRooted; /* This is exposing internal state of the GC for inlining purposes. */ JS_FRIEND_API(bool) isGCEnabled(); /* * JS::NullPtr acts like a nullptr pointer in contexts that require a Handle. * * Handle provides an implicit constructor for JS::NullPtr so that, given: * foo(Handle h); * callers can simply write: * foo(JS::NullPtr()); * which avoids creating a Rooted just to pass nullptr. */ struct JS_PUBLIC_API(NullPtr) { static void * const constNullValue; }; JS_FRIEND_API(void) HeapCellPostBarrier(js::gc::Cell** cellp); JS_FRIEND_API(void) HeapCellRelocate(js::gc::Cell** cellp); #ifdef JS_DEBUG /* * For generational GC, assert that an object is in the tenured generation as * opposed to being in the nursery. */ extern JS_FRIEND_API(void) AssertGCThingMustBeTenured(JSObject* obj); #else inline void AssertGCThingMustBeTenured(JSObject* obj) {} #endif /* * The Heap class is a heap-stored reference to a JS GC thing. All members of * heap classes that refer to GC things should use Heap (or possibly * TenuredHeap, described below). * * Heap is an abstraction that hides some of the complexity required to * maintain GC invariants for the contained reference. It uses operator * overloading to provide a normal pointer interface, but notifies the GC every * time the value it contains is updated. This is necessary for generational GC, * which keeps track of all pointers into the nursery. * * Heap instances must be traced when their containing object is traced to * keep the pointed-to GC thing alive. * * Heap objects should only be used on the heap. GC references stored on the * C/C++ stack must use Rooted/Handle/MutableHandle instead. * * Type T must be one of: JS::Value, jsid, JSObject*, JSString*, JSScript* */ template class Heap : public js::HeapBase { public: Heap() { static_assert(sizeof(T) == sizeof(Heap), "Heap must be binary compatible with T."); init(js::GCMethods::initial()); } explicit Heap(T p) { init(p); } /* * For Heap, move semantics are equivalent to copy semantics. In C++, a * copy constructor taking const-ref is the way to get a single function * that will be used for both lvalue and rvalue copies, so we can simply * omit the rvalue variant. */ explicit Heap(const Heap& p) { init(p.ptr); } ~Heap() { if (js::GCMethods::needsPostBarrier(ptr)) relocate(); } DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_POINTER_ASSIGN_OPS(Heap, T); DECLARE_NONPOINTER_ACCESSOR_METHODS(ptr); T* unsafeGet() { return &ptr; } /* * Set the pointer to a value which will cause a crash if it is * dereferenced. */ void setToCrashOnTouch() { ptr = reinterpret_cast(crashOnTouchPointer); } bool isSetToCrashOnTouch() { return ptr == crashOnTouchPointer; } private: void init(T newPtr) { ptr = newPtr; if (js::GCMethods::needsPostBarrier(ptr)) post(); } void set(T newPtr) { if (js::GCMethods::needsPostBarrier(newPtr)) { ptr = newPtr; post(); } else if (js::GCMethods::needsPostBarrier(ptr)) { relocate(); /* Called before overwriting ptr. */ ptr = newPtr; } else { ptr = newPtr; } } void post() { MOZ_ASSERT(js::GCMethods::needsPostBarrier(ptr)); js::GCMethods::postBarrier(&ptr); } void relocate() { js::GCMethods::relocate(&ptr); } enum { crashOnTouchPointer = 1 }; T ptr; }; /* * The TenuredHeap class is similar to the Heap class above in that it * encapsulates the GC concerns of an on-heap reference to a JS object. However, * it has two important differences: * * 1) Pointers which are statically known to only reference "tenured" objects * can avoid the extra overhead of SpiderMonkey's write barriers. * * 2) Objects in the "tenured" heap have stronger alignment restrictions than * those in the "nursery", so it is possible to store flags in the lower * bits of pointers known to be tenured. TenuredHeap wraps a normal tagged * pointer with a nice API for accessing the flag bits and adds various * assertions to ensure that it is not mis-used. * * GC things are said to be "tenured" when they are located in the long-lived * heap: e.g. they have gained tenure as an object by surviving past at least * one GC. For performance, SpiderMonkey allocates some things which are known * to normally be long lived directly into the tenured generation; for example, * global objects. Additionally, SpiderMonkey does not visit individual objects * when deleting non-tenured objects, so object with finalizers are also always * tenured; for instance, this includes most DOM objects. * * The considerations to keep in mind when using a TenuredHeap vs a normal * Heap are: * * - It is invalid for a TenuredHeap to refer to a non-tenured thing. * - It is however valid for a Heap to refer to a tenured thing. * - It is not possible to store flag bits in a Heap. */ template class TenuredHeap : public js::HeapBase { public: TenuredHeap() : bits(0) { static_assert(sizeof(T) == sizeof(TenuredHeap), "TenuredHeap must be binary compatible with T."); } explicit TenuredHeap(T p) : bits(0) { setPtr(p); } explicit TenuredHeap(const TenuredHeap& p) : bits(0) { setPtr(p.getPtr()); } bool operator==(const TenuredHeap& other) { return bits == other.bits; } bool operator!=(const TenuredHeap& other) { return bits != other.bits; } void setPtr(T newPtr) { MOZ_ASSERT((reinterpret_cast(newPtr) & flagsMask) == 0); if (newPtr) AssertGCThingMustBeTenured(newPtr); bits = (bits & flagsMask) | reinterpret_cast(newPtr); } void setFlags(uintptr_t flagsToSet) { MOZ_ASSERT((flagsToSet & ~flagsMask) == 0); bits |= flagsToSet; } void unsetFlags(uintptr_t flagsToUnset) { MOZ_ASSERT((flagsToUnset & ~flagsMask) == 0); bits &= ~flagsToUnset; } bool hasFlag(uintptr_t flag) const { MOZ_ASSERT((flag & ~flagsMask) == 0); return (bits & flag) != 0; } T getPtr() const { return reinterpret_cast(bits & ~flagsMask); } uintptr_t getFlags() const { return bits & flagsMask; } operator T() const { return getPtr(); } T operator->() const { return getPtr(); } TenuredHeap& operator=(T p) { setPtr(p); return *this; } TenuredHeap& operator=(const TenuredHeap& other) { bits = other.bits; return *this; } private: enum { maskBits = 3, flagsMask = (1 << maskBits) - 1, }; uintptr_t bits; }; /* * Reference to a T that has been rooted elsewhere. This is most useful * as a parameter type, which guarantees that the T lvalue is properly * rooted. See "Move GC Stack Rooting" above. * * If you want to add additional methods to Handle for a specific * specialization, define a HandleBase specialization containing them. */ template class MOZ_NONHEAP_CLASS Handle : public js::HandleBase { friend class JS::MutableHandle; public: /* Creates a handle from a handle of a type convertible to T. */ template Handle(Handle handle, typename mozilla::EnableIf::value, int>::Type dummy = 0) { static_assert(sizeof(Handle) == sizeof(T*), "Handle must be binary compatible with T*."); ptr = reinterpret_cast(handle.address()); } /* Create a handle for a nullptr pointer. */ MOZ_IMPLICIT Handle(js::NullPtr) { static_assert(mozilla::IsPointer::value, "js::NullPtr overload not valid for non-pointer types"); ptr = reinterpret_cast(&js::NullPtr::constNullValue); } /* Create a handle for a nullptr pointer. */ MOZ_IMPLICIT Handle(JS::NullPtr) { static_assert(mozilla::IsPointer::value, "JS::NullPtr overload not valid for non-pointer types"); ptr = reinterpret_cast(&JS::NullPtr::constNullValue); } MOZ_IMPLICIT Handle(MutableHandle handle) { ptr = handle.address(); } /* * Take care when calling this method! * * This creates a Handle from the raw location of a T. * * It should be called only if the following conditions hold: * * 1) the location of the T is guaranteed to be marked (for some reason * other than being a Rooted), e.g., if it is guaranteed to be reachable * from an implicit root. * * 2) the contents of the location are immutable, or at least cannot change * for the lifetime of the handle, as its users may not expect its value * to change underneath them. */ static MOZ_CONSTEXPR Handle fromMarkedLocation(const T* p) { return Handle(p, DeliberatelyChoosingThisOverload, ImUsingThisOnlyInFromFromMarkedLocation); } /* * Construct a handle from an explicitly rooted location. This is the * normal way to create a handle, and normally happens implicitly. */ template inline Handle(const Rooted& root, typename mozilla::EnableIf::value, int>::Type dummy = 0); template inline Handle(const PersistentRooted& root, typename mozilla::EnableIf::value, int>::Type dummy = 0); /* Construct a read only handle from a mutable handle. */ template inline Handle(MutableHandle& root, typename mozilla::EnableIf::value, int>::Type dummy = 0); DECLARE_POINTER_COMPARISON_OPS(T); DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_NONPOINTER_ACCESSOR_METHODS(*ptr); private: Handle() {} DELETE_ASSIGNMENT_OPS(Handle, T); enum Disambiguator { DeliberatelyChoosingThisOverload = 42 }; enum CallerIdentity { ImUsingThisOnlyInFromFromMarkedLocation = 17 }; MOZ_CONSTEXPR Handle(const T* p, Disambiguator, CallerIdentity) : ptr(p) {} const T* ptr; }; /* * Similar to a handle, but the underlying storage can be changed. This is * useful for outparams. * * If you want to add additional methods to MutableHandle for a specific * specialization, define a MutableHandleBase specialization containing * them. */ template class MOZ_STACK_CLASS MutableHandle : public js::MutableHandleBase { public: inline MOZ_IMPLICIT MutableHandle(Rooted* root); inline MOZ_IMPLICIT MutableHandle(PersistentRooted* root); private: // Disallow nullptr for overloading purposes. MutableHandle(decltype(nullptr)) = delete; public: void set(T v) { *ptr = v; } /* * This may be called only if the location of the T is guaranteed * to be marked (for some reason other than being a Rooted), * e.g., if it is guaranteed to be reachable from an implicit root. * * Create a MutableHandle from a raw location of a T. */ static MutableHandle fromMarkedLocation(T* p) { MutableHandle h; h.ptr = p; return h; } DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_NONPOINTER_ACCESSOR_METHODS(*ptr); DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(*ptr); private: MutableHandle() {} DELETE_ASSIGNMENT_OPS(MutableHandle, T); T* ptr; }; } /* namespace JS */ namespace js { /* * InternalHandle is a handle to an internal pointer into a gcthing. Use * InternalHandle when you have a pointer to a direct field of a gcthing, or * when you need a parameter type for something that *may* be a pointer to a * direct field of a gcthing. */ template class InternalHandle {}; template class InternalHandle { void * const* holder; size_t offset; public: /* * Create an InternalHandle using a Handle to the gcthing containing the * field in question, and a pointer to the field. */ template InternalHandle(const JS::Handle& handle, T* field) : holder((void**)handle.address()), offset(uintptr_t(field) - uintptr_t(handle.get())) {} /* * Create an InternalHandle to a field within a Rooted<>. */ template InternalHandle(const JS::Rooted& root, T* field) : holder((void**)root.address()), offset(uintptr_t(field) - uintptr_t(root.get())) {} InternalHandle(const InternalHandle& other) : holder(other.holder), offset(other.offset) {} T* get() const { return reinterpret_cast(uintptr_t(*holder) + offset); } const T& operator*() const { return *get(); } T* operator->() const { return get(); } static InternalHandle fromMarkedLocation(T* fieldPtr) { return InternalHandle(fieldPtr); } private: /* * Create an InternalHandle to something that is not a pointer to a * gcthing, and so does not need to be rooted in the first place. Use these * InternalHandles to pass pointers into functions that also need to accept * regular InternalHandles to gcthing fields. * * Make this private to prevent accidental misuse; this is only for * fromMarkedLocation(). */ explicit InternalHandle(T* field) : holder(reinterpret_cast(&js::NullPtr::constNullValue)), offset(uintptr_t(field)) {} void operator=(InternalHandle other) = delete; }; /* * By default, things should use the inheritance hierarchy to find their * ThingRootKind. Some pointer types are explicitly set in jspubtd.h so that * Rooted may be used without the class definition being available. */ template struct RootKind { static ThingRootKind rootKind() { return T::rootKind(); } }; template struct RootKind { static ThingRootKind rootKind() { return T::rootKind(); } }; template struct GCMethods { static T* initial() { return nullptr; } static bool needsPostBarrier(T* v) { return false; } static void postBarrier(T** vp) {} static void relocate(T** vp) {} }; template <> struct GCMethods { static JSObject* initial() { return nullptr; } static gc::Cell* asGCThingOrNull(JSObject* v) { if (!v) return nullptr; MOZ_ASSERT(uintptr_t(v) > 32); return reinterpret_cast(v); } static bool needsPostBarrier(JSObject* v) { return v != nullptr && gc::IsInsideNursery(reinterpret_cast(v)); } static void postBarrier(JSObject** vp) { JS::HeapCellPostBarrier(reinterpret_cast(vp)); } static void relocate(JSObject** vp) { JS::HeapCellRelocate(reinterpret_cast(vp)); } }; template <> struct GCMethods { static JSFunction* initial() { return nullptr; } static bool needsPostBarrier(JSFunction* v) { return v != nullptr && gc::IsInsideNursery(reinterpret_cast(v)); } static void postBarrier(JSFunction** vp) { JS::HeapCellPostBarrier(reinterpret_cast(vp)); } static void relocate(JSFunction** vp) { JS::HeapCellRelocate(reinterpret_cast(vp)); } }; } /* namespace js */ namespace JS { /* * Local variable of type T whose value is always rooted. This is typically * used for local variables, or for non-rooted values being passed to a * function that requires a handle, e.g. Foo(Root(cx, x)). * * If you want to add additional methods to Rooted for a specific * specialization, define a RootedBase specialization containing them. */ template class MOZ_STACK_CLASS Rooted : public js::RootedBase { /* Note: CX is a subclass of either ContextFriendFields or PerThreadDataFriendFields. */ template void init(CX* cx) { js::ThingRootKind kind = js::RootKind::rootKind(); this->stack = &cx->thingGCRooters[kind]; this->prev = *stack; *stack = reinterpret_cast*>(this); } public: explicit Rooted(JSContext* cx MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(js::GCMethods::initial()) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(js::ContextFriendFields::get(cx)); } Rooted(JSContext* cx, T initial MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(initial) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(js::ContextFriendFields::get(cx)); } explicit Rooted(js::ContextFriendFields* cx MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(js::GCMethods::initial()) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(cx); } Rooted(js::ContextFriendFields* cx, T initial MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(initial) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(cx); } explicit Rooted(js::PerThreadDataFriendFields* pt MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(js::GCMethods::initial()) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(pt); } Rooted(js::PerThreadDataFriendFields* pt, T initial MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(initial) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(pt); } explicit Rooted(JSRuntime* rt MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(js::GCMethods::initial()) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(js::PerThreadDataFriendFields::getMainThread(rt)); } Rooted(JSRuntime* rt, T initial MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(initial) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; init(js::PerThreadDataFriendFields::getMainThread(rt)); } ~Rooted() { MOZ_ASSERT(*stack == reinterpret_cast*>(this)); *stack = prev; } Rooted* previous() { return reinterpret_cast*>(prev); } /* * This method is public for Rooted so that Codegen.py can use a Rooted * interchangeably with a MutableHandleValue. */ void set(T value) { ptr = value; } DECLARE_POINTER_COMPARISON_OPS(T); DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_POINTER_ASSIGN_OPS(Rooted, T); DECLARE_NONPOINTER_ACCESSOR_METHODS(ptr); DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(ptr); private: /* * These need to be templated on void* to avoid aliasing issues between, for * example, Rooted and Rooted, which use the same * stack head pointer for different classes. */ Rooted** stack; Rooted* prev; /* * |ptr| must be the last field in Rooted because the analysis treats all * Rooted as Rooted during the analysis. See bug 829372. */ T ptr; MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER Rooted(const Rooted&) = delete; }; } /* namespace JS */ namespace js { /* * Augment the generic Rooted interface when T = JSObject* with * class-querying and downcasting operations. * * Given a Rooted obj, one can view * Handle h = obj.as(); * as an optimization of * Rooted rooted(cx, &obj->as()); * Handle h = rooted; */ template <> class RootedBase { public: template JS::Handle as() const; }; /* * Augment the generic Handle interface when T = JSObject* with * downcasting operations. * * Given a Handle obj, one can view * Handle h = obj.as(); * as an optimization of * Rooted rooted(cx, &obj->as()); * Handle h = rooted; */ template <> class HandleBase { public: template JS::Handle as() const; }; /* Interface substitute for Rooted which does not root the variable's memory. */ template class FakeRooted : public RootedBase { public: template FakeRooted(CX* cx MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(GCMethods::initial()) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; } template FakeRooted(CX* cx, T initial MOZ_GUARD_OBJECT_NOTIFIER_PARAM) : ptr(initial) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; } DECLARE_POINTER_COMPARISON_OPS(T); DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_POINTER_ASSIGN_OPS(FakeRooted, T); DECLARE_NONPOINTER_ACCESSOR_METHODS(ptr); DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(ptr); private: T ptr; void set(const T& value) { ptr = value; } MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER FakeRooted(const FakeRooted&) = delete; }; /* Interface substitute for MutableHandle which is not required to point to rooted memory. */ template class FakeMutableHandle : public js::MutableHandleBase { public: MOZ_IMPLICIT FakeMutableHandle(T* t) { ptr = t; } MOZ_IMPLICIT FakeMutableHandle(FakeRooted* root) { ptr = root->address(); } void set(T v) { *ptr = v; } DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_NONPOINTER_ACCESSOR_METHODS(*ptr); DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(*ptr); private: FakeMutableHandle() {} DELETE_ASSIGNMENT_OPS(FakeMutableHandle, T); T* ptr; }; /* * Types for a variable that either should or shouldn't be rooted, depending on * the template parameter allowGC. Used for implementing functions that can * operate on either rooted or unrooted data. * * The toHandle() and toMutableHandle() functions are for calling functions * which require handle types and are only called in the CanGC case. These * allow the calling code to type check. */ enum AllowGC { NoGC = 0, CanGC = 1 }; template class MaybeRooted { }; template class MaybeRooted { public: typedef JS::Handle HandleType; typedef JS::Rooted RootType; typedef JS::MutableHandle MutableHandleType; static inline JS::Handle toHandle(HandleType v) { return v; } static inline JS::MutableHandle toMutableHandle(MutableHandleType v) { return v; } template static inline JS::Handle downcastHandle(HandleType v) { return v.template as(); } }; template class MaybeRooted { public: typedef T HandleType; typedef FakeRooted RootType; typedef FakeMutableHandle MutableHandleType; static JS::Handle toHandle(HandleType v) { MOZ_CRASH("Bad conversion"); } static JS::MutableHandle toMutableHandle(MutableHandleType v) { MOZ_CRASH("Bad conversion"); } template static inline T2* downcastHandle(HandleType v) { return &v->template as(); } }; } /* namespace js */ namespace JS { template template inline Handle::Handle(const Rooted& root, typename mozilla::EnableIf::value, int>::Type dummy) { ptr = reinterpret_cast(root.address()); } template template inline Handle::Handle(const PersistentRooted& root, typename mozilla::EnableIf::value, int>::Type dummy) { ptr = reinterpret_cast(root.address()); } template template inline Handle::Handle(MutableHandle& root, typename mozilla::EnableIf::value, int>::Type dummy) { ptr = reinterpret_cast(root.address()); } template inline MutableHandle::MutableHandle(Rooted* root) { static_assert(sizeof(MutableHandle) == sizeof(T*), "MutableHandle must be binary compatible with T*."); ptr = root->address(); } template inline MutableHandle::MutableHandle(PersistentRooted* root) { static_assert(sizeof(MutableHandle) == sizeof(T*), "MutableHandle must be binary compatible with T*."); ptr = root->address(); } /* * A copyable, assignable global GC root type with arbitrary lifetime, an * infallible constructor, and automatic unrooting on destruction. * * These roots can be used in heap-allocated data structures, so they are not * associated with any particular JSContext or stack. They are registered with * the JSRuntime itself, without locking, so they require a full JSContext to be * initialized, not one of its more restricted superclasses. Initialization may * take place on construction, or in two phases if the no-argument constructor * is called followed by init(). * * Note that you must not use an PersistentRooted in an object owned by a JS * object: * * Whenever one object whose lifetime is decided by the GC refers to another * such object, that edge must be traced only if the owning JS object is traced. * This applies not only to JS objects (which obviously are managed by the GC) * but also to C++ objects owned by JS objects. * * If you put a PersistentRooted in such a C++ object, that is almost certainly * a leak. When a GC begins, the referent of the PersistentRooted is treated as * live, unconditionally (because a PersistentRooted is a *root*), even if the * JS object that owns it is unreachable. If there is any path from that * referent back to the JS object, then the C++ object containing the * PersistentRooted will not be destructed, and the whole blob of objects will * not be freed, even if there are no references to them from the outside. * * In the context of Firefox, this is a severe restriction: almost everything in * Firefox is owned by some JS object or another, so using PersistentRooted in * such objects would introduce leaks. For these kinds of edges, Heap or * TenuredHeap would be better types. It's up to the implementor of the type * containing Heap or TenuredHeap members to make sure their referents get * marked when the object itself is marked. */ template class PersistentRooted : public js::PersistentRootedBase, private mozilla::LinkedListElement> { typedef mozilla::LinkedListElement> ListBase; friend class mozilla::LinkedList; friend class mozilla::LinkedListElement; friend struct js::gc::PersistentRootedMarker; friend void js::gc::FinishPersistentRootedChains(JSRuntime* rt); void registerWithRuntime(JSRuntime* rt) { MOZ_ASSERT(!initialized()); JS::shadow::Runtime* srt = JS::shadow::Runtime::asShadowRuntime(rt); srt->getPersistentRootedList().insertBack(this); } public: PersistentRooted() : ptr(js::GCMethods::initial()) {} explicit PersistentRooted(JSContext* cx) { init(cx); } PersistentRooted(JSContext* cx, T initial) { init(cx, initial); } explicit PersistentRooted(JSRuntime* rt) { init(rt); } PersistentRooted(JSRuntime* rt, T initial) { init(rt, initial); } PersistentRooted(const PersistentRooted& rhs) : mozilla::LinkedListElement>(), ptr(rhs.ptr) { /* * Copy construction takes advantage of the fact that the original * is already inserted, and simply adds itself to whatever list the * original was on - no JSRuntime pointer needed. * * This requires mutating rhs's links, but those should be 'mutable' * anyway. C++ doesn't let us declare mutable base classes. */ const_cast(rhs).setNext(this); } bool initialized() { return ListBase::isInList(); } void init(JSContext* cx) { init(cx, js::GCMethods::initial()); } void init(JSContext* cx, T initial) { ptr = initial; registerWithRuntime(js::GetRuntime(cx)); } void init(JSRuntime* rt) { init(rt, js::GCMethods::initial()); } void init(JSRuntime* rt, T initial) { ptr = initial; registerWithRuntime(rt); } void reset() { if (initialized()) { set(js::GCMethods::initial()); ListBase::remove(); } } DECLARE_POINTER_COMPARISON_OPS(T); DECLARE_POINTER_CONSTREF_OPS(T); DECLARE_POINTER_ASSIGN_OPS(PersistentRooted, T); DECLARE_NONPOINTER_ACCESSOR_METHODS(ptr); DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS(ptr); private: void set(T value) { MOZ_ASSERT(initialized()); ptr = value; } T ptr; }; class JS_PUBLIC_API(ObjectPtr) { Heap value; public: ObjectPtr() : value(nullptr) {} explicit ObjectPtr(JSObject* obj) : value(obj) {} /* Always call finalize before the destructor. */ ~ObjectPtr() { MOZ_ASSERT(!value); } void finalize(JSRuntime* rt) { if (IsIncrementalBarrierNeeded(rt)) IncrementalObjectBarrier(value); value = nullptr; } void init(JSObject* obj) { value = obj; } JSObject* get() const { return value; } void writeBarrierPre(JSRuntime* rt) { IncrementalObjectBarrier(value); } void updateWeakPointerAfterGC(); ObjectPtr& operator=(JSObject* obj) { IncrementalObjectBarrier(value); value = obj; return *this; } void trace(JSTracer* trc, const char* name); JSObject& operator*() const { return *value; } JSObject* operator->() const { return value; } operator JSObject*() const { return value; } }; } /* namespace JS */ namespace js { namespace gc { template void CallTraceCallbackOnNonHeap(T* v, const TraceCallbacks& aCallbacks, const char* aName, void* aClosure) { static_assert(sizeof(T) == sizeof(JS::Heap), "T and Heap must be compatible."); MOZ_ASSERT(v); mozilla::DebugOnly cell = GCMethods::asGCThingOrNull(*v); MOZ_ASSERT(cell); MOZ_ASSERT(!IsInsideNursery(cell)); JS::Heap* asHeapT = reinterpret_cast*>(v); aCallbacks.Trace(asHeapT, aName, aClosure); } } /* namespace gc */ } /* namespace js */ #undef DELETE_ASSIGNMENT_OPS #undef DECLARE_NONPOINTER_MUTABLE_ACCESSOR_METHODS #undef DECLARE_NONPOINTER_ACCESSOR_METHODS #endif /* js_RootingAPI_h */