services/surfaceflinger/Scheduler/MessageQueue.cpp - LeafOS-Project/android_frameworks_native - Gitiles

 /*
  * Copyright (C) 2009 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #define ATRACE_TAG ATRACE_TAG_GRAPHICS

 #include <binder/IPCThreadState.h>
 #include <utils/Log.h>
 #include <utils/Timers.h>
 #include <utils/threads.h>

 #include <scheduler/interface/ICompositor.h>

 #include "EventThread.h"
 #include "FrameTimeline.h"
 #include "MessageQueue.h"

 namespace android::impl {

 void MessageQueue::Handler::dispatchFrame(VsyncId vsyncId, TimePoint expectedVsyncTime) {
     if (!mFramePending.exchange(true)) {
         mVsyncId = vsyncId;
         mExpectedVsyncTime = expectedVsyncTime;
         mQueue.mLooper->sendMessage(sp<MessageHandler>::fromExisting(this), Message());
     }
 }

 bool MessageQueue::Handler::isFramePending() const {
     return mFramePending.load();
 }

 void MessageQueue::Handler::handleMessage(const Message&) {
     mFramePending.store(false);
     mQueue.onFrameSignal(mQueue.mCompositor, mVsyncId, mExpectedVsyncTime);
 }

 MessageQueue::MessageQueue(ICompositor& compositor)
       : MessageQueue(compositor, sp<Handler>::make(*this)) {}

 constexpr bool kAllowNonCallbacks = true;

 MessageQueue::MessageQueue(ICompositor& compositor, sp<Handler> handler)
       : mCompositor(compositor),
         mLooper(sp<Looper>::make(kAllowNonCallbacks)),
         mHandler(std::move(handler)) {}

 void MessageQueue::vsyncCallback(nsecs_t vsyncTime, nsecs_t targetWakeupTime, nsecs_t readyTime) {
     ATRACE_CALL();
     // Trace VSYNC-sf
     mVsync.value = (mVsync.value + 1) % 2;

     const auto expectedVsyncTime = TimePoint::fromNs(vsyncTime);
     {
         std::lock_guard lock(mVsync.mutex);
         mVsync.lastCallbackTime = expectedVsyncTime;
         mVsync.scheduledFrameTimeOpt.reset();
     }

     const auto vsyncId = VsyncId{mVsync.tokenManager->generateTokenForPredictions(
             {targetWakeupTime, readyTime, vsyncTime})};

     mHandler->dispatchFrame(vsyncId, expectedVsyncTime);
 }

 void MessageQueue::initVsyncInternal(std::shared_ptr<scheduler::VSyncDispatch> dispatch,
                                      frametimeline::TokenManager& tokenManager,
                                      std::chrono::nanoseconds workDuration) {
     std::unique_ptr<scheduler::VSyncCallbackRegistration> oldRegistration;
     {
         std::lock_guard lock(mVsync.mutex);
         mVsync.workDuration = workDuration;
         mVsync.tokenManager = &tokenManager;
         oldRegistration = onNewVsyncScheduleLocked(std::move(dispatch));
     }

     // See comments in onNewVsyncSchedule. Today, oldRegistration should be
     // empty, but nothing prevents us from calling initVsyncInternal multiple times, so
     // go ahead and destruct it outside the lock for safety.
     oldRegistration.reset();
 }

 void MessageQueue::onNewVsyncSchedule(std::shared_ptr<scheduler::VSyncDispatch> dispatch) {
     std::unique_ptr<scheduler::VSyncCallbackRegistration> oldRegistration;
     {
         std::lock_guard lock(mVsync.mutex);
         oldRegistration = onNewVsyncScheduleLocked(std::move(dispatch));
     }

     // The old registration needs to be deleted after releasing mVsync.mutex to
     // avoid deadlock. This is because the callback may be running on the timer
     // thread. In that case, timerCallback sets
     // VSyncDispatchTimerQueueEntry::mRunning to true, then attempts to lock
     // mVsync.mutex. But if it's already locked, the VSyncCallbackRegistration's
     // destructor has to wait until VSyncDispatchTimerQueueEntry::mRunning is
     // set back to false, but it won't be until mVsync.mutex is released.
     oldRegistration.reset();
 }

 std::unique_ptr<scheduler::VSyncCallbackRegistration> MessageQueue::onNewVsyncScheduleLocked(
         std::shared_ptr<scheduler::VSyncDispatch> dispatch) {
     const bool reschedule = mVsync.registration &&
             mVsync.registration->cancel() == scheduler::CancelResult::Cancelled;
     auto oldRegistration = std::move(mVsync.registration);
     mVsync.registration = std::make_unique<
             scheduler::VSyncCallbackRegistration>(std::move(dispatch),
                                                   std::bind(&MessageQueue::vsyncCallback, this,
                                                             std::placeholders::_1,
                                                             std::placeholders::_2,
                                                             std::placeholders::_3),
                                                   "sf");
     if (reschedule) {
         mVsync.scheduledFrameTimeOpt =
                 mVsync.registration->schedule({.workDuration = mVsync.workDuration.get().count(),
                                                .readyDuration = 0,
                                                .lastVsync = mVsync.lastCallbackTime.ns()});
     }
     return oldRegistration;
 }

 void MessageQueue::destroyVsync() {
     std::lock_guard lock(mVsync.mutex);
     mVsync.tokenManager = nullptr;
     mVsync.registration.reset();
 }

 void MessageQueue::setDuration(std::chrono::nanoseconds workDuration) {
     ATRACE_CALL();
     std::lock_guard lock(mVsync.mutex);
     mVsync.workDuration = workDuration;
     mVsync.scheduledFrameTimeOpt =
             mVsync.registration->update({.workDuration = mVsync.workDuration.get().count(),
                                          .readyDuration = 0,
                                          .lastVsync = mVsync.lastCallbackTime.ns()});
 }

 void MessageQueue::waitMessage() {
     do {
         IPCThreadState::self()->flushCommands();
         int32_t ret = mLooper->pollOnce(-1);
         switch (ret) {
             case Looper::POLL_WAKE:
             case Looper::POLL_CALLBACK:
                 continue;
             case Looper::POLL_ERROR:
                 ALOGE("Looper::POLL_ERROR");
                 continue;
             case Looper::POLL_TIMEOUT:
                 // timeout (should not happen)
                 continue;
             default:
                 // should not happen
                 ALOGE("Looper::pollOnce() returned unknown status %d", ret);
                 continue;
         }
     } while (true);
 }

 void MessageQueue::postMessage(sp<MessageHandler>&& handler) {
     mLooper->sendMessage(handler, Message());
 }

 void MessageQueue::postMessageDelayed(sp<MessageHandler>&& handler, nsecs_t uptimeDelay) {
     mLooper->sendMessageDelayed(uptimeDelay, handler, Message());
 }

 void MessageQueue::scheduleConfigure() {
     struct ConfigureHandler : MessageHandler {
         explicit ConfigureHandler(ICompositor& compositor) : compositor(compositor) {}

         void handleMessage(const Message&) override { compositor.configure(); }

         ICompositor& compositor;
     };

     // TODO(b/241285876): Batch configure tasks that happen within some duration.
     postMessage(sp<ConfigureHandler>::make(mCompositor));
 }

 void MessageQueue::scheduleFrame() {
     ATRACE_CALL();

     std::lock_guard lock(mVsync.mutex);
     mVsync.scheduledFrameTimeOpt =
             mVsync.registration->schedule({.workDuration = mVsync.workDuration.get().count(),
                                            .readyDuration = 0,
                                            .lastVsync = mVsync.lastCallbackTime.ns()});
 }

 std::optional<scheduler::ScheduleResult> MessageQueue::getScheduledFrameResult() const {
     if (mHandler->isFramePending()) {
         return scheduler::ScheduleResult{TimePoint::now(), mHandler->getExpectedVsyncTime()};
     }
     std::lock_guard lock(mVsync.mutex);
     if (const auto scheduledFrameTimeline = mVsync.scheduledFrameTimeOpt) {
         return scheduledFrameTimeline;
     }
     return std::nullopt;
 }

 } // namespace android::impl
	/*
	* Copyright (C) 2009 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#define ATRACE_TAG ATRACE_TAG_GRAPHICS

	#include <binder/IPCThreadState.h>
	#include <utils/Log.h>
	#include <utils/Timers.h>
	#include <utils/threads.h>

	#include <scheduler/interface/ICompositor.h>

	#include "EventThread.h"
	#include "FrameTimeline.h"
	#include "MessageQueue.h"

	namespace android::impl {

	void MessageQueue::Handler::dispatchFrame(VsyncId vsyncId, TimePoint expectedVsyncTime) {
	if (!mFramePending.exchange(true)) {
	mVsyncId = vsyncId;
	mExpectedVsyncTime = expectedVsyncTime;
	mQueue.mLooper->sendMessage(sp<MessageHandler>::fromExisting(this), Message());
	}
	}

	bool MessageQueue::Handler::isFramePending() const {
	return mFramePending.load();
	}

	void MessageQueue::Handler::handleMessage(const Message&) {
	mFramePending.store(false);
	mQueue.onFrameSignal(mQueue.mCompositor, mVsyncId, mExpectedVsyncTime);
	}

	MessageQueue::MessageQueue(ICompositor& compositor)
	: MessageQueue(compositor, sp<Handler>::make(*this)) {}

	constexpr bool kAllowNonCallbacks = true;

	MessageQueue::MessageQueue(ICompositor& compositor, sp<Handler> handler)
	: mCompositor(compositor),
	mLooper(sp<Looper>::make(kAllowNonCallbacks)),
	mHandler(std::move(handler)) {}

	void MessageQueue::vsyncCallback(nsecs_t vsyncTime, nsecs_t targetWakeupTime, nsecs_t readyTime) {
	ATRACE_CALL();
	// Trace VSYNC-sf
	mVsync.value = (mVsync.value + 1) % 2;

	const auto expectedVsyncTime = TimePoint::fromNs(vsyncTime);
	{
	std::lock_guard lock(mVsync.mutex);
	mVsync.lastCallbackTime = expectedVsyncTime;
	mVsync.scheduledFrameTimeOpt.reset();
	}

	const auto vsyncId = VsyncId{mVsync.tokenManager->generateTokenForPredictions(
	{targetWakeupTime, readyTime, vsyncTime})};

	mHandler->dispatchFrame(vsyncId, expectedVsyncTime);
	}

	void MessageQueue::initVsyncInternal(std::shared_ptr<scheduler::VSyncDispatch> dispatch,
	frametimeline::TokenManager& tokenManager,
	std::chrono::nanoseconds workDuration) {
	std::unique_ptr<scheduler::VSyncCallbackRegistration> oldRegistration;
	{
	std::lock_guard lock(mVsync.mutex);
	mVsync.workDuration = workDuration;
	mVsync.tokenManager = &tokenManager;
	oldRegistration = onNewVsyncScheduleLocked(std::move(dispatch));
	}

	// See comments in onNewVsyncSchedule. Today, oldRegistration should be
	// empty, but nothing prevents us from calling initVsyncInternal multiple times, so
	// go ahead and destruct it outside the lock for safety.
	oldRegistration.reset();
	}

	void MessageQueue::onNewVsyncSchedule(std::shared_ptr<scheduler::VSyncDispatch> dispatch) {
	std::unique_ptr<scheduler::VSyncCallbackRegistration> oldRegistration;
	{
	std::lock_guard lock(mVsync.mutex);
	oldRegistration = onNewVsyncScheduleLocked(std::move(dispatch));
	}

	// The old registration needs to be deleted after releasing mVsync.mutex to
	// avoid deadlock. This is because the callback may be running on the timer
	// thread. In that case, timerCallback sets
	// VSyncDispatchTimerQueueEntry::mRunning to true, then attempts to lock
	// mVsync.mutex. But if it's already locked, the VSyncCallbackRegistration's
	// destructor has to wait until VSyncDispatchTimerQueueEntry::mRunning is
	// set back to false, but it won't be until mVsync.mutex is released.
	oldRegistration.reset();
	}

	std::unique_ptr<scheduler::VSyncCallbackRegistration> MessageQueue::onNewVsyncScheduleLocked(
	std::shared_ptr<scheduler::VSyncDispatch> dispatch) {
	const bool reschedule = mVsync.registration &&
	mVsync.registration->cancel() == scheduler::CancelResult::Cancelled;
	auto oldRegistration = std::move(mVsync.registration);
	mVsync.registration = std::make_unique<
	scheduler::VSyncCallbackRegistration>(std::move(dispatch),
	std::bind(&MessageQueue::vsyncCallback, this,
	std::placeholders::_1,
	std::placeholders::_2,
	std::placeholders::_3),
	"sf");
	if (reschedule) {
	mVsync.scheduledFrameTimeOpt =
	mVsync.registration->schedule({.workDuration = mVsync.workDuration.get().count(),
	.readyDuration = 0,
	.lastVsync = mVsync.lastCallbackTime.ns()});
	}
	return oldRegistration;
	}

	void MessageQueue::destroyVsync() {
	std::lock_guard lock(mVsync.mutex);
	mVsync.tokenManager = nullptr;
	mVsync.registration.reset();
	}

	void MessageQueue::setDuration(std::chrono::nanoseconds workDuration) {
	ATRACE_CALL();
	std::lock_guard lock(mVsync.mutex);
	mVsync.workDuration = workDuration;
	mVsync.scheduledFrameTimeOpt =
	mVsync.registration->update({.workDuration = mVsync.workDuration.get().count(),
	.readyDuration = 0,
	.lastVsync = mVsync.lastCallbackTime.ns()});
	}

	void MessageQueue::waitMessage() {
	do {
	IPCThreadState::self()->flushCommands();
	int32_t ret = mLooper->pollOnce(-1);
	switch (ret) {
	case Looper::POLL_WAKE:
	case Looper::POLL_CALLBACK:
	continue;
	case Looper::POLL_ERROR:
	ALOGE("Looper::POLL_ERROR");
	continue;
	case Looper::POLL_TIMEOUT:
	// timeout (should not happen)
	continue;
	default:
	// should not happen
	ALOGE("Looper::pollOnce() returned unknown status %d", ret);
	continue;
	}
	} while (true);
	}

	void MessageQueue::postMessage(sp<MessageHandler>&& handler) {
	mLooper->sendMessage(handler, Message());
	}

	void MessageQueue::postMessageDelayed(sp<MessageHandler>&& handler, nsecs_t uptimeDelay) {
	mLooper->sendMessageDelayed(uptimeDelay, handler, Message());
	}

	void MessageQueue::scheduleConfigure() {
	struct ConfigureHandler : MessageHandler {
	explicit ConfigureHandler(ICompositor& compositor) : compositor(compositor) {}

	void handleMessage(const Message&) override { compositor.configure(); }

	ICompositor& compositor;
	};

	// TODO(b/241285876): Batch configure tasks that happen within some duration.
	postMessage(sp<ConfigureHandler>::make(mCompositor));
	}

	void MessageQueue::scheduleFrame() {
	ATRACE_CALL();

	std::lock_guard lock(mVsync.mutex);
	mVsync.scheduledFrameTimeOpt =
	mVsync.registration->schedule({.workDuration = mVsync.workDuration.get().count(),
	.readyDuration = 0,
	.lastVsync = mVsync.lastCallbackTime.ns()});
	}

	std::optional<scheduler::ScheduleResult> MessageQueue::getScheduledFrameResult() const {
	if (mHandler->isFramePending()) {
	return scheduler::ScheduleResult{TimePoint::now(), mHandler->getExpectedVsyncTime()};
	}
	std::lock_guard lock(mVsync.mutex);
	if (const auto scheduledFrameTimeline = mVsync.scheduledFrameTimeOpt) {
	return scheduledFrameTimeline;
	}
	return std::nullopt;
	}

	} // namespace android::impl