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35eaf64b42
Autogenerated by modeline.py.
379 lines
13 KiB
C++
379 lines
13 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=8 sts=2 et sw=2 tw=80: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#if !defined(StateMirroring_h_)
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#define StateMirroring_h_
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#include "mozilla/Maybe.h"
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#include "mozilla/MozPromise.h"
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#include "mozilla/StateWatching.h"
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#include "mozilla/TaskDispatcher.h"
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#include "mozilla/UniquePtr.h"
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#include "mozilla/unused.h"
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#include "mozilla/Logging.h"
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#include "nsISupportsImpl.h"
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/*
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* The state-mirroring machinery allows pieces of interesting state to be
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* observed on multiple thread without locking. The basic strategy is to track
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* changes in a canonical value and post updates to other threads that hold
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* mirrors for that value.
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*
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* One problem with the naive implementation of such a system is that some pieces
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* of state need to be updated atomically, and certain other operations need to
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* wait for these atomic updates to complete before executing. The state-mirroring
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* machinery solves this problem by requiring that its owner thread uses tail
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* dispatch, and posting state update events (which should always be run first by
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* TaskDispatcher implementations) to that tail dispatcher. This ensures that
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* state changes are always atomic from the perspective of observing threads.
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*
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* Given that state-mirroring is an automatic background process, we try to avoid
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* burdening the caller with worrying too much about teardown. To that end, we
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* don't assert dispatch success for any of the notifications, and assume that
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* any canonical or mirror owned by a thread for whom dispatch fails will soon
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* be disconnected by its holder anyway.
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*
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* Given that semantics may change and comments tend to go out of date, we
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* deliberately don't provide usage examples here. Grep around to find them.
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*/
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namespace mozilla {
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// Mirror<T> and Canonical<T> inherit WatchTarget, so we piggy-back on the
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// logging that WatchTarget already does. Given that, it makes sense to share
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// the same log module.
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#define MIRROR_LOG(x, ...) \
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MOZ_ASSERT(gStateWatchingLog); \
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MOZ_LOG(gStateWatchingLog, LogLevel::Debug, (x, ##__VA_ARGS__))
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template<typename T> class AbstractMirror;
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/*
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* AbstractCanonical is a superclass from which all Canonical values must
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* inherit. It serves as the interface of operations which may be performed (via
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* asynchronous dispatch) by other threads, in particular by the corresponding
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* Mirror value.
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*/
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template<typename T>
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class AbstractCanonical
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{
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public:
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NS_INLINE_DECL_THREADSAFE_REFCOUNTING(AbstractCanonical)
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AbstractCanonical(AbstractThread* aThread) : mOwnerThread(aThread) {}
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virtual void AddMirror(AbstractMirror<T>* aMirror) = 0;
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virtual void RemoveMirror(AbstractMirror<T>* aMirror) = 0;
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AbstractThread* OwnerThread() const { return mOwnerThread; }
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protected:
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virtual ~AbstractCanonical() {}
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RefPtr<AbstractThread> mOwnerThread;
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};
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/*
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* AbstractMirror is a superclass from which all Mirror values must
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* inherit. It serves as the interface of operations which may be performed (via
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* asynchronous dispatch) by other threads, in particular by the corresponding
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* Canonical value.
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*/
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template<typename T>
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class AbstractMirror
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{
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public:
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NS_INLINE_DECL_THREADSAFE_REFCOUNTING(AbstractMirror)
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AbstractMirror(AbstractThread* aThread) : mOwnerThread(aThread) {}
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virtual void UpdateValue(const T& aNewValue) = 0;
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virtual void NotifyDisconnected() = 0;
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AbstractThread* OwnerThread() const { return mOwnerThread; }
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protected:
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virtual ~AbstractMirror() {}
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RefPtr<AbstractThread> mOwnerThread;
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};
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/*
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* Canonical<T> is a wrapper class that allows a given value to be mirrored by other
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* threads. It maintains a list of active mirrors, and queues updates for them
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* when the internal value changes. When changing the value, the caller needs to
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* pass a TaskDispatcher object, which fires the updates at the appropriate time.
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* Canonical<T> is also a WatchTarget, and may be set up to trigger other routines
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* (on the same thread) when the canonical value changes.
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*
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* Canonical<T> is intended to be used as a member variable, so it doesn't actually
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* inherit AbstractCanonical<T> (a refcounted type). Rather, it contains an inner
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* class called |Impl| that implements most of the interesting logic.
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*/
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template<typename T>
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class Canonical
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{
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public:
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Canonical(AbstractThread* aThread, const T& aInitialValue, const char* aName)
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{
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mImpl = new Impl(aThread, aInitialValue, aName);
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}
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~Canonical() {}
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private:
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class Impl : public AbstractCanonical<T>, public WatchTarget
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{
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public:
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using AbstractCanonical<T>::OwnerThread;
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Impl(AbstractThread* aThread, const T& aInitialValue, const char* aName)
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: AbstractCanonical<T>(aThread), WatchTarget(aName), mValue(aInitialValue)
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{
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MIRROR_LOG("%s [%p] initialized", mName, this);
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MOZ_ASSERT(aThread->SupportsTailDispatch(), "Can't get coherency without tail dispatch");
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}
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void AddMirror(AbstractMirror<T>* aMirror) override
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{
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MIRROR_LOG("%s [%p] adding mirror %p", mName, this, aMirror);
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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MOZ_ASSERT(!mMirrors.Contains(aMirror));
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mMirrors.AppendElement(aMirror);
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aMirror->OwnerThread()->DispatchStateChange(MakeNotifier(aMirror));
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}
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void RemoveMirror(AbstractMirror<T>* aMirror) override
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{
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MIRROR_LOG("%s [%p] removing mirror %p", mName, this, aMirror);
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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MOZ_ASSERT(mMirrors.Contains(aMirror));
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mMirrors.RemoveElement(aMirror);
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}
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void DisconnectAll()
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{
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MIRROR_LOG("%s [%p] Disconnecting all mirrors", mName, this);
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for (size_t i = 0; i < mMirrors.Length(); ++i) {
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mMirrors[i]->OwnerThread()->Dispatch(NewRunnableMethod(mMirrors[i],
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&AbstractMirror<T>::NotifyDisconnected),
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AbstractThread::DontAssertDispatchSuccess);
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}
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mMirrors.Clear();
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}
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operator const T&()
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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return mValue;
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}
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void Set(const T& aNewValue)
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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if (aNewValue == mValue) {
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return;
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}
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// Notify same-thread watchers. The state watching machinery will make sure
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// that notifications run at the right time.
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NotifyWatchers();
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// Check if we've already got a pending update. If so we won't schedule another
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// one.
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bool alreadyNotifying = mInitialValue.isSome();
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// Stash the initial value if needed, then update to the new value.
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if (mInitialValue.isNothing()) {
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mInitialValue.emplace(mValue);
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}
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mValue = aNewValue;
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// We wait until things have stablized before sending state updates so that
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// we can avoid sending multiple updates, and possibly avoid sending any
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// updates at all if the value ends up where it started.
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if (!alreadyNotifying) {
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AbstractThread::DispatchDirectTask(NewRunnableMethod(this, &Impl::DoNotify));
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}
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}
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Impl& operator=(const T& aNewValue) { Set(aNewValue); return *this; }
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Impl& operator=(const Impl& aOther) { Set(aOther); return *this; }
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Impl(const Impl& aOther) = delete;
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protected:
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~Impl() { MOZ_DIAGNOSTIC_ASSERT(mMirrors.IsEmpty()); }
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private:
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void DoNotify()
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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MOZ_ASSERT(mInitialValue.isSome());
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bool same = mInitialValue.ref() == mValue;
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mInitialValue.reset();
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if (same) {
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MIRROR_LOG("%s [%p] unchanged - not sending update", mName, this);
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return;
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}
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for (size_t i = 0; i < mMirrors.Length(); ++i) {
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mMirrors[i]->OwnerThread()->DispatchStateChange(MakeNotifier(mMirrors[i]));
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}
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}
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already_AddRefed<nsIRunnable> MakeNotifier(AbstractMirror<T>* aMirror)
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{
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return NewRunnableMethod<T>(aMirror, &AbstractMirror<T>::UpdateValue, mValue);;
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}
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T mValue;
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Maybe<T> mInitialValue;
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nsTArray<RefPtr<AbstractMirror<T>>> mMirrors;
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};
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public:
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// NB: Because mirror-initiated disconnection can race with canonical-
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// initiated disconnection, a canonical should never be reinitialized.
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// Forward control operations to the Impl.
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void DisconnectAll() { return mImpl->DisconnectAll(); }
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// Access to the Impl.
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operator Impl&() { return *mImpl; }
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Impl* operator&() { return mImpl; }
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// Access to the T.
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const T& Ref() const { return *mImpl; }
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operator const T&() const { return Ref(); }
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void Set(const T& aNewValue) { mImpl->Set(aNewValue); }
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Canonical& operator=(const T& aNewValue) { Set(aNewValue); return *this; }
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Canonical& operator=(const Canonical& aOther) { Set(aOther); return *this; }
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Canonical(const Canonical& aOther) = delete;
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private:
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RefPtr<Impl> mImpl;
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};
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/*
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* Mirror<T> is a wrapper class that allows a given value to mirror that of a
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* Canonical<T> owned by another thread. It registers itself with a Canonical<T>,
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* and is periodically updated with new values. Mirror<T> is also a WatchTarget,
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* and may be set up to trigger other routines (on the same thread) when the
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* mirrored value changes.
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*
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* Mirror<T> is intended to be used as a member variable, so it doesn't actually
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* inherit AbstractMirror<T> (a refcounted type). Rather, it contains an inner
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* class called |Impl| that implements most of the interesting logic.
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*/
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template<typename T>
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class Mirror
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{
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public:
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Mirror(AbstractThread* aThread, const T& aInitialValue, const char* aName)
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{
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mImpl = new Impl(aThread, aInitialValue, aName);
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}
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~Mirror()
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{
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// As a member of complex objects, a Mirror<T> may be destroyed on a
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// different thread than its owner, or late in shutdown during CC. Given
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// that, we require manual disconnection so that callers can put things in
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// the right place.
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MOZ_DIAGNOSTIC_ASSERT(!mImpl->IsConnected());
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}
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private:
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class Impl : public AbstractMirror<T>, public WatchTarget
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{
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public:
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using AbstractMirror<T>::OwnerThread;
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Impl(AbstractThread* aThread, const T& aInitialValue, const char* aName)
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: AbstractMirror<T>(aThread), WatchTarget(aName), mValue(aInitialValue)
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{
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MIRROR_LOG("%s [%p] initialized", mName, this);
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MOZ_ASSERT(aThread->SupportsTailDispatch(), "Can't get coherency without tail dispatch");
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}
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operator const T&()
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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return mValue;
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}
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virtual void UpdateValue(const T& aNewValue) override
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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if (mValue != aNewValue) {
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mValue = aNewValue;
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WatchTarget::NotifyWatchers();
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}
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}
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virtual void NotifyDisconnected() override
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{
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MIRROR_LOG("%s [%p] Notifed of disconnection from %p", mName, this, mCanonical.get());
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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mCanonical = nullptr;
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}
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bool IsConnected() const { return !!mCanonical; }
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void Connect(AbstractCanonical<T>* aCanonical)
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{
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MIRROR_LOG("%s [%p] Connecting to %p", mName, this, aCanonical);
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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MOZ_ASSERT(!IsConnected());
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MOZ_ASSERT(OwnerThread()->RequiresTailDispatch(aCanonical->OwnerThread()), "Can't get coherency without tail dispatch");
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nsCOMPtr<nsIRunnable> r = NewRunnableMethod<StorensRefPtrPassByPtr<AbstractMirror<T>>>
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(aCanonical, &AbstractCanonical<T>::AddMirror, this);
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aCanonical->OwnerThread()->Dispatch(r.forget(), AbstractThread::DontAssertDispatchSuccess);
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mCanonical = aCanonical;
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}
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public:
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void DisconnectIfConnected()
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{
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MOZ_ASSERT(OwnerThread()->IsCurrentThreadIn());
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if (!IsConnected()) {
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return;
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}
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MIRROR_LOG("%s [%p] Disconnecting from %p", mName, this, mCanonical.get());
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nsCOMPtr<nsIRunnable> r = NewRunnableMethod<StorensRefPtrPassByPtr<AbstractMirror<T>>>
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(mCanonical, &AbstractCanonical<T>::RemoveMirror, this);
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mCanonical->OwnerThread()->Dispatch(r.forget(), AbstractThread::DontAssertDispatchSuccess);
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mCanonical = nullptr;
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}
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protected:
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~Impl() { MOZ_DIAGNOSTIC_ASSERT(!IsConnected()); }
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private:
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T mValue;
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RefPtr<AbstractCanonical<T>> mCanonical;
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};
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public:
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// Forward control operations to the Impl<T>.
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void Connect(AbstractCanonical<T>* aCanonical) { mImpl->Connect(aCanonical); }
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void DisconnectIfConnected() { mImpl->DisconnectIfConnected(); }
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// Access to the Impl<T>.
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operator Impl&() { return *mImpl; }
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Impl* operator&() { return mImpl; }
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// Access to the T.
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const T& Ref() const { return *mImpl; }
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operator const T&() const { return Ref(); }
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private:
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RefPtr<Impl> mImpl;
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};
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#undef MIRROR_LOG
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} // namespace mozilla
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#endif
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