gecko-dev/mfbt/ThreadSafeWeakPtr.h

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/* A thread-safe weak pointer */
/**
* Derive from SupportsThreadSafeWeakPtr to allow thread-safe weak pointers to
* an atomically refcounted derived class. These thread-safe weak pointers may
* be safely accessed and converted to strong pointers on multiple threads.
*
* Note that SupportsThreadSafeWeakPtr necessarily already inherits from
* AtomicRefCounted, so you should not separately inherit from AtomicRefCounted.
*
* ThreadSafeWeakPtr and its implementation is distinct from the normal WeakPtr
* which is not thread-safe. The interface discipline and implementation details
* are different enough that these two implementations are separated for now for
* efficiency reasons. If you don't actually need to use weak pointers on
* multiple threads, you can just use WeakPtr instead.
*
* When deriving from SupportsThreadSafeWeakPtr, you should add
* MOZ_DECLARE_THREADSAFEWEAKREFERENCE_TYPENAME(ClassName) and
* MOZ_DECLARE_REFCOUNTED_TYPENAME(ClassName) to the public section of your
* class, where ClassName is the name of your class.
*
* Example usage:
*
* class C : public SupportsThreadSafeWeakPtr<C>
* {
* public:
* MOZ_DECLARE_THREADSAFEWEAKREFERENCE_TYPENAME(C)
* MOZ_DECLARE_REFCOUNTED_TYPENAME(C)
* void doStuff();
* };
*
* ThreadSafeWeakPtr<C> weak;
* {
* RefPtr<C> strong = new C;
* if (strong) {
* strong->doStuff();
* }
* // Make a new weak reference to the object from the strong reference.
* weak = strong;
* }
* MOZ_ASSERT(!bool(weak), "Weak pointers are cleared after all "
* "strong references are released.");
*
* // Convert the weak reference to a strong reference for usage.
* RefPtr<C> other(weak);
* if (other) {
* other->doStuff();
* }
*/
#ifndef mozilla_ThreadSafeWeakPtr_h
#define mozilla_ThreadSafeWeakPtr_h
#include "mozilla/Assertions.h"
#include "mozilla/Atomics.h"
#include "mozilla/RefCounted.h"
#include "mozilla/RefPtr.h"
#include "mozilla/TypeTraits.h"
#include "mozilla/Unused.h"
#include <limits>
namespace mozilla {
template <typename T>
class ThreadSafeWeakPtr;
template <typename T>
class SupportsThreadSafeWeakPtr;
#ifdef MOZ_REFCOUNTED_LEAK_CHECKING
# define MOZ_DECLARE_THREADSAFEWEAKREFERENCE_TYPENAME(T) \
static const char* threadSafeWeakReferenceTypeName() { \
return "ThreadSafeWeakReference<" #T ">"; \
}
#else
# define MOZ_DECLARE_THREADSAFEWEAKREFERENCE_TYPENAME(T)
#endif
namespace detail {
// A multiple reader, single writer spin-lock.
// This lock maintains an atomic counter which is incremented every time the
// lock is acquired reading. So long as the counter remains positive, it may be
// incremented for reading multiple times. When acquiring the lock for writing,
// we must ensure the counter is 0 (no readers), and if so, set it to a negative
// value to indicate that no new readers may take the lock.
class ReadWriteSpinLock {
// Only need a type large enough to represent the number of simultaneously
// accessing threads.
typedef int32_t CounterType;
public:
// Try to increment the counter for reading, so long as it is positive.
void readLock() {
for (;;) {
CounterType oldCounter =
mCounter & std::numeric_limits<CounterType>::max();
CounterType newCounter = oldCounter + 1;
if (mCounter.compareExchange(oldCounter, newCounter)) {
break;
}
}
}
// Decrement the counter to remove a read lock.
void readUnlock() { mCounter--; }
// Try to acquire the write lock, but only if there are no readers.
// If successful, sets the counter to a negative value.
bool tryWriteLock() {
return mCounter.compareExchange(0, std::numeric_limits<CounterType>::min());
}
// Reset the counter to 0.
void writeUnlock() { mCounter = 0; }
private:
Atomic<CounterType> mCounter;
};
// A shared weak reference that is used to track a SupportsThreadSafeWeakPtr
// object. It guards access to that object via a read-write spinlock.
template <typename T>
class ThreadSafeWeakReference
: public external::AtomicRefCounted<ThreadSafeWeakReference<T>> {
public:
typedef T ElementType;
explicit ThreadSafeWeakReference(T* aPtr) { mPtr = aPtr; }
#ifdef MOZ_REFCOUNTED_LEAK_CHECKING
const char* typeName() const {
// The first time this is called mPtr is null, so don't
// invoke any methods on mPtr.
return T::threadSafeWeakReferenceTypeName();
}
size_t typeSize() const { return sizeof(*this); }
#endif
private:
friend class mozilla::SupportsThreadSafeWeakPtr<T>;
template <typename U>
friend class mozilla::ThreadSafeWeakPtr;
// Does an unsafe read of the raw weak pointer.
T* get() const { return mPtr; }
// Creates a new RefPtr to the tracked object.
// We need to acquire the read lock while we do this, as we need to atomically
// both read the pointer and then increment the refcount on it within the
// scope of the lock. This guards against the object being destroyed while in
// the middle of creating the new RefPtr.
already_AddRefed<T> getRefPtr() {
mLock.readLock();
RefPtr<T> result(get());
mLock.readUnlock();
return result.forget();
}
// Try to detach the weak reference from the tracked object.
// We need to acquire the write lock while we do this, to ensure that no
// RefPtr is created to this while detaching. Once acquired, it is safe
// to check the refcount and verify that this is the last reference to
// the tracked object, so the weak reference can be safely detached.
void tryDetach(const SupportsThreadSafeWeakPtr<T>* aOwner) {
if (mLock.tryWriteLock()) {
if (aOwner->hasOneRef()) {
mPtr = nullptr;
}
mLock.writeUnlock();
}
}
ReadWriteSpinLock mLock;
Atomic<T*> mPtr;
};
} // namespace detail
template <typename T>
class SupportsThreadSafeWeakPtr : public external::AtomicRefCounted<T> {
protected:
typedef external::AtomicRefCounted<T> AtomicRefCounted;
typedef detail::ThreadSafeWeakReference<T> ThreadSafeWeakReference;
public:
~SupportsThreadSafeWeakPtr() {
// Clean up the shared weak reference if one exists.
if (ThreadSafeWeakReference* ptr = mRef) {
ptr->Release();
}
}
void Release() const {
// If there is only one remaining reference to the object when trying to
// release, then attempt to detach it from its weak reference. New
// references could possibly be created to the object while this happens, so
// take care to do this atomically inside tryDetach.
if (AtomicRefCounted::hasOneRef()) {
if (ThreadSafeWeakReference* ptr = mRef) {
ptr->tryDetach(this);
}
}
// Once possibly detached, it is now safe to continue to decrement the
// refcount.
AtomicRefCounted::Release();
}
private:
template <typename U>
friend class ThreadSafeWeakPtr;
// Creates a shared weak reference for the object if one does not exist. Note
// that the object may be of an actual derived type U, but the weak reference
// is created for the supplied type T of SupportsThreadSafeWeakPtr<T>.
already_AddRefed<ThreadSafeWeakReference> getThreadSafeWeakReference() {
static_assert(std::is_base_of<SupportsThreadSafeWeakPtr<T>, T>::value,
"T must derive from SupportsThreadSafeWeakPtr<T>");
if (!mRef) {
RefPtr<ThreadSafeWeakReference> ptr(
new ThreadSafeWeakReference(static_cast<T*>(this)));
// Only set the new weak reference if one does not exist (== nullptr).
// If there is already a weak reference, just let this superflous weak
// reference get destroyed when it goes out of scope.
if (mRef.compareExchange(nullptr, ptr)) {
// If successful, forget the refcount so that the weak reference stays
// alive.
Unused << ptr.forget();
}
}
// Create a new RefPtr to weak reference.
RefPtr<ThreadSafeWeakReference> ptr(mRef);
return ptr.forget();
}
Atomic<ThreadSafeWeakReference*> mRef;
};
// A thread-safe variant of a weak pointer
template <typename T>
class ThreadSafeWeakPtr {
// Be careful to use the weak reference type T in the
// SupportsThreadSafeWeakPtr<T> definition.
typedef typename T::ThreadSafeWeakReference ThreadSafeWeakReference;
public:
ThreadSafeWeakPtr() {}
ThreadSafeWeakPtr& operator=(const ThreadSafeWeakPtr& aOther) {
mRef = aOther.mRef;
return *this;
}
ThreadSafeWeakPtr(const ThreadSafeWeakPtr& aOther) : mRef(aOther.mRef) {}
ThreadSafeWeakPtr& operator=(ThreadSafeWeakPtr&& aOther) {
mRef = aOther.mRef.forget();
return *this;
}
ThreadSafeWeakPtr(ThreadSafeWeakPtr&& aOther) : mRef(aOther.mRef.forget()) {}
ThreadSafeWeakPtr& operator=(const RefPtr<T>& aOther) {
if (aOther) {
// Get the underlying shared weak reference to the object, creating one if
// necessary.
mRef = aOther->getThreadSafeWeakReference();
} else {
mRef = nullptr;
}
return *this;
}
explicit ThreadSafeWeakPtr(const RefPtr<T>& aOther) { *this = aOther; }
ThreadSafeWeakPtr& operator=(decltype(nullptr)) {
mRef = nullptr;
return *this;
}
explicit ThreadSafeWeakPtr(decltype(nullptr)) {}
explicit operator bool() const { return !!get(); }
bool operator==(const ThreadSafeWeakPtr& aOther) const {
return get() == aOther.get();
}
bool operator==(const RefPtr<T>& aOther) const {
return get() == aOther.get();
}
bool operator==(const T* aOther) const { return get() == aOther; }
template <typename U>
bool operator!=(const U& aOther) const {
return !(*this == aOther);
}
// Convert the weak pointer to a strong RefPtr.
explicit operator RefPtr<T>() const { return getRefPtr(); }
private:
// Gets a new strong reference of the proper type T to the tracked object.
already_AddRefed<T> getRefPtr() const {
static_assert(std::is_base_of<typename ThreadSafeWeakReference::ElementType,
T>::value,
"T must derive from ThreadSafeWeakReference::ElementType");
return mRef ? mRef->getRefPtr().template downcast<T>() : nullptr;
}
// Get a pointer to the tracked object, downcasting to the proper type T.
// Note that this operation is unsafe as it may cause races if downwind
// code depends on the value not to change after reading.
T* get() const {
static_assert(std::is_base_of<typename ThreadSafeWeakReference::ElementType,
T>::value,
"T must derive from ThreadSafeWeakReference::ElementType");
return mRef ? static_cast<T*>(mRef->get()) : nullptr;
}
// A shared weak reference to an object. Note that this may be null so as to
// save memory (at the slight cost of an extra null check) if no object is
// being tracked.
RefPtr<ThreadSafeWeakReference> mRef;
};
} // namespace mozilla
template <typename T>
inline already_AddRefed<T> do_AddRef(
const mozilla::ThreadSafeWeakPtr<T>& aObj) {
RefPtr<T> ref(aObj);
return ref.forget();
}
#endif /* mozilla_ThreadSafeWeakPtr_h */