services/surfaceflinger/Scheduler/Scheduler.h - third_party/android/platform/frameworks/native - Git at Google

 /*
  * Copyright 2018 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.
  */

 #pragma once

 #include <cstdint>
 #include <functional>
 #include <memory>

 #include <ui/DisplayStatInfo.h>
 #include <ui/GraphicTypes.h>

 #include "DispSync.h"
 #include "EventControlThread.h"
 #include "EventThread.h"
 #include "IdleTimer.h"
 #include "InjectVSyncSource.h"
 #include "LayerHistory.h"
 #include "RefreshRateConfigs.h"
 #include "SchedulerUtils.h"

 namespace android {

 class EventControlThread;

 class Scheduler {
 public:
     // Enum to keep track of whether we trigger event to notify choreographer of config changes.
     enum class ConfigEvent { None, Changed };

     // logical or operator with the semantics of at least one of the events is Changed
     friend ConfigEvent operator|(const ConfigEvent& first, const ConfigEvent& second) {
         if (first == ConfigEvent::Changed) return ConfigEvent::Changed;
         if (second == ConfigEvent::Changed) return ConfigEvent::Changed;
         return ConfigEvent::None;
     }

     using RefreshRateType = scheduler::RefreshRateConfigs::RefreshRateType;
     using GetCurrentRefreshRateTypeCallback = std::function<RefreshRateType()>;
     using ChangeRefreshRateCallback = std::function<void(RefreshRateType, ConfigEvent)>;
     using GetVsyncPeriod = std::function<nsecs_t()>;

     // Enum to indicate whether to start the transaction early, or at vsync time.
     enum class TransactionStart { EARLY, NORMAL };

     /* The scheduler handle is a BBinder object passed to the client from which we can extract
      * an ID for subsequent operations.
      */
     class ConnectionHandle : public BBinder {
     public:
         ConnectionHandle(int64_t id) : id(id) {}

         ~ConnectionHandle() = default;

         const int64_t id;
     };

     class Connection {
     public:
         Connection(sp<ConnectionHandle> handle, sp<EventThreadConnection> eventConnection,
                    std::unique_ptr<EventThread> eventThread)
               : handle(handle), eventConnection(eventConnection), thread(std::move(eventThread)) {}

         ~Connection() = default;

         sp<ConnectionHandle> handle;
         sp<EventThreadConnection> eventConnection;
         const std::unique_ptr<EventThread> thread;
     };

     // Stores per-display state about VSYNC.
     struct VsyncState {
         explicit VsyncState(Scheduler& scheduler) : scheduler(scheduler) {}

         void resync(const GetVsyncPeriod&);

         Scheduler& scheduler;
         std::atomic<nsecs_t> lastResyncTime = 0;
     };

     explicit Scheduler(impl::EventControlThread::SetVSyncEnabledFunction function,
                        const scheduler::RefreshRateConfigs& refreshRateConfig);

     virtual ~Scheduler();

     /** Creates an EventThread connection. */
     sp<ConnectionHandle> createConnection(const char* connectionName, nsecs_t phaseOffsetNs,
                                           nsecs_t offsetThresholdForNextVsync, ResyncCallback,
                                           impl::EventThread::InterceptVSyncsCallback);

     sp<IDisplayEventConnection> createDisplayEventConnection(
             const sp<ConnectionHandle>& handle, ResyncCallback,
             ISurfaceComposer::ConfigChanged configChanged);

     // Getter methods.
     EventThread* getEventThread(const sp<ConnectionHandle>& handle);

     // Provides access to the DispSync object for the primary display.
     void withPrimaryDispSync(std::function<void(DispSync&)> const& fn);

     sp<EventThreadConnection> getEventConnection(const sp<ConnectionHandle>& handle);

     // Should be called when receiving a hotplug event.
     void hotplugReceived(const sp<ConnectionHandle>& handle, PhysicalDisplayId displayId,
                          bool connected);

     // Should be called after the screen is turned on.
     void onScreenAcquired(const sp<ConnectionHandle>& handle);

     // Should be called before the screen is turned off.
     void onScreenReleased(const sp<ConnectionHandle>& handle);

     // Should be called when display config changed
     void onConfigChanged(const sp<ConnectionHandle>& handle, PhysicalDisplayId displayId,
                          int32_t configId);

     // Should be called when dumpsys command is received.
     void dump(const sp<ConnectionHandle>& handle, std::string& result) const;

     // Offers ability to modify phase offset in the event thread.
     void setPhaseOffset(const sp<ConnectionHandle>& handle, nsecs_t phaseOffset);

     void getDisplayStatInfo(DisplayStatInfo* stats);

     void enableHardwareVsync();
     void disableHardwareVsync(bool makeUnavailable);
     // Resyncs the scheduler to hardware vsync.
     // If makeAvailable is true, then hardware vsync will be turned on.
     // Otherwise, if hardware vsync is not already enabled then this method will
     // no-op.
     // The period is the vsync period from the current display configuration.
     void resyncToHardwareVsync(bool makeAvailable, nsecs_t period);
     // Creates a callback for resyncing.
     ResyncCallback makeResyncCallback(GetVsyncPeriod&& getVsyncPeriod);
     void setRefreshSkipCount(int count);
     // Passes a vsync sample to DispSync. periodFlushed will be true if
     // DispSync detected that the vsync period changed, and false otherwise.
     void addResyncSample(const nsecs_t timestamp, bool* periodFlushed);
     void addPresentFence(const std::shared_ptr<FenceTime>& fenceTime);
     void setIgnorePresentFences(bool ignore);
     nsecs_t getDispSyncExpectedPresentTime();
     // Registers the layer in the scheduler, and returns the handle for future references.
     std::unique_ptr<scheduler::LayerHistory::LayerHandle> registerLayer(std::string const& name,
                                                                         int windowType);

     // Stores present time for a layer.
     void addLayerPresentTimeAndHDR(
             const std::unique_ptr<scheduler::LayerHistory::LayerHandle>& layerHandle,
             nsecs_t presentTime, bool isHDR);
     // Stores visibility for a layer.
     void setLayerVisibility(
             const std::unique_ptr<scheduler::LayerHistory::LayerHandle>& layerHandle, bool visible);
     // Updates FPS based on the most content presented.
     void updateFpsBasedOnContent();
     // Callback that gets invoked when Scheduler wants to change the refresh rate.
     void setChangeRefreshRateCallback(const ChangeRefreshRateCallback&& changeRefreshRateCallback);
     void setGetCurrentRefreshRateTypeCallback(
             const GetCurrentRefreshRateTypeCallback&& getCurrentRefreshRateType);
     void setGetVsyncPeriodCallback(const GetVsyncPeriod&& getVsyncPeriod);

     // Returns whether idle timer is enabled or not
     bool isIdleTimerEnabled() { return mSetIdleTimerMs > 0; }

     // Function that resets the idle timer.
     void resetIdleTimer();

     // Function that resets the touch timer.
     void notifyTouchEvent();

     // Function that sets whether display power mode is normal or not.
     void setDisplayPowerState(bool normal);

     // Returns relevant information about Scheduler for dumpsys purposes.
     std::string doDump();

     // calls DispSync::dump() on primary disp sync
     void dumpPrimaryDispSync(std::string& result) const;

     // Get the appropriate refresh type for current conditions.
     RefreshRateType getPreferredRefreshRateType();

 protected:
     virtual std::unique_ptr<EventThread> makeEventThread(
             const char* connectionName, DispSync* dispSync, nsecs_t phaseOffsetNs,
             nsecs_t offsetThresholdForNextVsync,
             impl::EventThread::InterceptVSyncsCallback interceptCallback);

 private:
     friend class TestableScheduler;

     // In order to make sure that the features don't override themselves, we need a state machine
     // to keep track which feature requested the config change.
     enum class ContentFeatureState { CONTENT_DETECTION_ON, CONTENT_DETECTION_OFF };
     enum class IdleTimerState { EXPIRED, RESET };
     enum class TouchState { INACTIVE, ACTIVE };
     enum class DisplayPowerTimerState { EXPIRED, RESET };

     // Creates a connection on the given EventThread and forwards the given callbacks.
     sp<EventThreadConnection> createConnectionInternal(EventThread*, ResyncCallback&&,
                                                        ISurfaceComposer::ConfigChanged);

     nsecs_t calculateAverage() const;
     void updateFrameSkipping(const int64_t skipCount);

     // Function that is called when the timer resets.
     void resetTimerCallback();
     // Function that is called when the timer expires.
     void expiredTimerCallback();
     // Function that is called when the timer resets when paired with a display
     // driver timeout in the kernel. This enables hardware vsync when we move
     // out from idle.
     void resetKernelTimerCallback();
     // Function that is called when the timer expires when paired with a display
     // driver timeout in the kernel. This disables hardware vsync when we move
     // into idle.
     void expiredKernelTimerCallback();
     // Function that is called when the touch timer resets.
     void resetTouchTimerCallback();
     // Function that is called when the touch timer expires.
     void expiredTouchTimerCallback();
     // Function that is called when the display power timer resets.
     void resetDisplayPowerTimerCallback();
     // Function that is called when the display power timer expires.
     void expiredDisplayPowerTimerCallback();
     // Sets vsync period.
     void setVsyncPeriod(const nsecs_t period);
     // handles various timer features to change the refresh rate.
     template <class T>
     void handleTimerStateChanged(T* currentState, T newState, bool eventOnContentDetection);
     // Calculate the new refresh rate type
     RefreshRateType calculateRefreshRateType() REQUIRES(mFeatureStateLock);
     // Acquires a lock and calls the ChangeRefreshRateCallback() with given parameters.
     void changeRefreshRate(RefreshRateType refreshRateType, ConfigEvent configEvent);

     // Helper function to calculate error frames
     float getErrorFrames(float contentFps, float configFps);

     // If fences from sync Framework are supported.
     const bool mHasSyncFramework;

     // The offset in nanoseconds to use, when DispSync timestamps present fence
     // signaling time.
     nsecs_t mDispSyncPresentTimeOffset;

     // Each connection has it's own ID. This variable keeps track of the count.
     static std::atomic<int64_t> sNextId;

     // Connections are stored in a map <connection ID, connection> for easy retrieval.
     std::unordered_map<int64_t, std::unique_ptr<Connection>> mConnections;

     std::mutex mHWVsyncLock;
     bool mPrimaryHWVsyncEnabled GUARDED_BY(mHWVsyncLock);
     bool mHWVsyncAvailable GUARDED_BY(mHWVsyncLock);
     const std::shared_ptr<VsyncState> mPrimaryVsyncState{std::make_shared<VsyncState>(*this)};

     std::unique_ptr<DispSync> mPrimaryDispSync;
     std::unique_ptr<EventControlThread> mEventControlThread;

     // TODO(b/113612090): The following set of variables needs to be revised. For now, this is
     // a proof of concept. We turn on frame skipping if the difference between the timestamps
     // is between 32 and 34ms. We expect this currently for 30fps videos, so we render them at 30Hz.
     nsecs_t mPreviousFrameTimestamp = 0;
     // Keeping track of whether we are skipping the refresh count. If we want to
     // simulate 30Hz rendering, we skip every other frame, and this variable is set
     // to 1.
     int64_t mSkipCount = 0;
     std::array<int64_t, scheduler::ARRAY_SIZE> mTimeDifferences{};
     size_t mCounter = 0;

     // Historical information about individual layers. Used for predicting the refresh rate.
     scheduler::LayerHistory mLayerHistory;

     // Timer that records time between requests for next vsync. If the time is higher than a given
     // interval, a callback is fired. Set this variable to >0 to use this feature.
     int64_t mSetIdleTimerMs = 0;
     std::unique_ptr<scheduler::IdleTimer> mIdleTimer;
     // Enables whether to use idle timer callbacks that support the kernel
     // timer.
     bool mSupportKernelTimer;

     // Timer used to monitor touch events.
     int64_t mSetTouchTimerMs = 0;
     std::unique_ptr<scheduler::IdleTimer> mTouchTimer;

     // Timer used to monitor display power mode.
     int64_t mSetDisplayPowerTimerMs = 0;
     std::unique_ptr<scheduler::IdleTimer> mDisplayPowerTimer;

     std::mutex mCallbackLock;
     GetCurrentRefreshRateTypeCallback mGetCurrentRefreshRateTypeCallback GUARDED_BY(mCallbackLock);
     ChangeRefreshRateCallback mChangeRefreshRateCallback GUARDED_BY(mCallbackLock);
     GetVsyncPeriod mGetVsyncPeriod GUARDED_BY(mCallbackLock);

     // In order to make sure that the features don't override themselves, we need a state machine
     // to keep track which feature requested the config change.
     std::mutex mFeatureStateLock;
     ContentFeatureState mCurrentContentFeatureState GUARDED_BY(mFeatureStateLock) =
             ContentFeatureState::CONTENT_DETECTION_OFF;
     IdleTimerState mCurrentIdleTimerState GUARDED_BY(mFeatureStateLock) = IdleTimerState::RESET;
     TouchState mCurrentTouchState GUARDED_BY(mFeatureStateLock) = TouchState::INACTIVE;
     DisplayPowerTimerState mDisplayPowerTimerState GUARDED_BY(mFeatureStateLock) =
             DisplayPowerTimerState::EXPIRED;
     uint32_t mContentRefreshRate GUARDED_BY(mFeatureStateLock);
     RefreshRateType mRefreshRateType GUARDED_BY(mFeatureStateLock);
     bool mIsHDRContent GUARDED_BY(mFeatureStateLock) = false;
     bool mIsDisplayPowerStateNormal GUARDED_BY(mFeatureStateLock) = true;

     const scheduler::RefreshRateConfigs& mRefreshRateConfigs;

     // Global config to force HDR content to work on DEFAULT refreshRate
     static constexpr bool mForceHDRContentToDefaultRefreshRate = false;
 };

 } // namespace android
	/*
	* Copyright 2018 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.
	*/

	#pragma once

	#include <cstdint>
	#include <functional>
	#include <memory>

	#include <ui/DisplayStatInfo.h>
	#include <ui/GraphicTypes.h>

	#include "DispSync.h"
	#include "EventControlThread.h"
	#include "EventThread.h"
	#include "IdleTimer.h"
	#include "InjectVSyncSource.h"
	#include "LayerHistory.h"
	#include "RefreshRateConfigs.h"
	#include "SchedulerUtils.h"

	namespace android {

	class EventControlThread;

	class Scheduler {
	public:
	// Enum to keep track of whether we trigger event to notify choreographer of config changes.
	enum class ConfigEvent { None, Changed };

	// logical or operator with the semantics of at least one of the events is Changed
	friend ConfigEvent operator\|(const ConfigEvent& first, const ConfigEvent& second) {
	if (first == ConfigEvent::Changed) return ConfigEvent::Changed;
	if (second == ConfigEvent::Changed) return ConfigEvent::Changed;
	return ConfigEvent::None;
	}

	using RefreshRateType = scheduler::RefreshRateConfigs::RefreshRateType;
	using GetCurrentRefreshRateTypeCallback = std::function<RefreshRateType()>;
	using ChangeRefreshRateCallback = std::function<void(RefreshRateType, ConfigEvent)>;
	using GetVsyncPeriod = std::function<nsecs_t()>;

	// Enum to indicate whether to start the transaction early, or at vsync time.
	enum class TransactionStart { EARLY, NORMAL };

	/* The scheduler handle is a BBinder object passed to the client from which we can extract
	* an ID for subsequent operations.
	*/
	class ConnectionHandle : public BBinder {
	public:
	ConnectionHandle(int64_t id) : id(id) {}

	~ConnectionHandle() = default;

	const int64_t id;
	};

	class Connection {
	public:
	Connection(sp<ConnectionHandle> handle, sp<EventThreadConnection> eventConnection,
	std::unique_ptr<EventThread> eventThread)
	: handle(handle), eventConnection(eventConnection), thread(std::move(eventThread)) {}

	~Connection() = default;

	sp<ConnectionHandle> handle;
	sp<EventThreadConnection> eventConnection;
	const std::unique_ptr<EventThread> thread;
	};

	// Stores per-display state about VSYNC.
	struct VsyncState {
	explicit VsyncState(Scheduler& scheduler) : scheduler(scheduler) {}

	void resync(const GetVsyncPeriod&);

	Scheduler& scheduler;
	std::atomic<nsecs_t> lastResyncTime = 0;
	};

	explicit Scheduler(impl::EventControlThread::SetVSyncEnabledFunction function,
	const scheduler::RefreshRateConfigs& refreshRateConfig);

	virtual ~Scheduler();

	/** Creates an EventThread connection. */
	sp<ConnectionHandle> createConnection(const char* connectionName, nsecs_t phaseOffsetNs,
	nsecs_t offsetThresholdForNextVsync, ResyncCallback,
	impl::EventThread::InterceptVSyncsCallback);

	sp<IDisplayEventConnection> createDisplayEventConnection(
	const sp<ConnectionHandle>& handle, ResyncCallback,
	ISurfaceComposer::ConfigChanged configChanged);

	// Getter methods.
	EventThread* getEventThread(const sp<ConnectionHandle>& handle);

	// Provides access to the DispSync object for the primary display.
	void withPrimaryDispSync(std::function<void(DispSync&)> const& fn);

	sp<EventThreadConnection> getEventConnection(const sp<ConnectionHandle>& handle);

	// Should be called when receiving a hotplug event.
	void hotplugReceived(const sp<ConnectionHandle>& handle, PhysicalDisplayId displayId,
	bool connected);

	// Should be called after the screen is turned on.
	void onScreenAcquired(const sp<ConnectionHandle>& handle);

	// Should be called before the screen is turned off.
	void onScreenReleased(const sp<ConnectionHandle>& handle);

	// Should be called when display config changed
	void onConfigChanged(const sp<ConnectionHandle>& handle, PhysicalDisplayId displayId,
	int32_t configId);

	// Should be called when dumpsys command is received.
	void dump(const sp<ConnectionHandle>& handle, std::string& result) const;

	// Offers ability to modify phase offset in the event thread.
	void setPhaseOffset(const sp<ConnectionHandle>& handle, nsecs_t phaseOffset);

	void getDisplayStatInfo(DisplayStatInfo* stats);

	void enableHardwareVsync();
	void disableHardwareVsync(bool makeUnavailable);
	// Resyncs the scheduler to hardware vsync.
	// If makeAvailable is true, then hardware vsync will be turned on.
	// Otherwise, if hardware vsync is not already enabled then this method will
	// no-op.
	// The period is the vsync period from the current display configuration.
	void resyncToHardwareVsync(bool makeAvailable, nsecs_t period);
	// Creates a callback for resyncing.
	ResyncCallback makeResyncCallback(GetVsyncPeriod&& getVsyncPeriod);
	void setRefreshSkipCount(int count);
	// Passes a vsync sample to DispSync. periodFlushed will be true if
	// DispSync detected that the vsync period changed, and false otherwise.
	void addResyncSample(const nsecs_t timestamp, bool* periodFlushed);
	void addPresentFence(const std::shared_ptr<FenceTime>& fenceTime);
	void setIgnorePresentFences(bool ignore);
	nsecs_t getDispSyncExpectedPresentTime();
	// Registers the layer in the scheduler, and returns the handle for future references.
	std::unique_ptr<scheduler::LayerHistory::LayerHandle> registerLayer(std::string const& name,
	int windowType);

	// Stores present time for a layer.
	void addLayerPresentTimeAndHDR(
	const std::unique_ptr<scheduler::LayerHistory::LayerHandle>& layerHandle,
	nsecs_t presentTime, bool isHDR);
	// Stores visibility for a layer.
	void setLayerVisibility(
	const std::unique_ptr<scheduler::LayerHistory::LayerHandle>& layerHandle, bool visible);
	// Updates FPS based on the most content presented.
	void updateFpsBasedOnContent();
	// Callback that gets invoked when Scheduler wants to change the refresh rate.
	void setChangeRefreshRateCallback(const ChangeRefreshRateCallback&& changeRefreshRateCallback);
	void setGetCurrentRefreshRateTypeCallback(
	const GetCurrentRefreshRateTypeCallback&& getCurrentRefreshRateType);
	void setGetVsyncPeriodCallback(const GetVsyncPeriod&& getVsyncPeriod);

	// Returns whether idle timer is enabled or not
	bool isIdleTimerEnabled() { return mSetIdleTimerMs > 0; }

	// Function that resets the idle timer.
	void resetIdleTimer();

	// Function that resets the touch timer.
	void notifyTouchEvent();

	// Function that sets whether display power mode is normal or not.
	void setDisplayPowerState(bool normal);

	// Returns relevant information about Scheduler for dumpsys purposes.
	std::string doDump();

	// calls DispSync::dump() on primary disp sync
	void dumpPrimaryDispSync(std::string& result) const;

	// Get the appropriate refresh type for current conditions.
	RefreshRateType getPreferredRefreshRateType();

	protected:
	virtual std::unique_ptr<EventThread> makeEventThread(
	const char* connectionName, DispSync* dispSync, nsecs_t phaseOffsetNs,
	nsecs_t offsetThresholdForNextVsync,
	impl::EventThread::InterceptVSyncsCallback interceptCallback);

	private:
	friend class TestableScheduler;

	// In order to make sure that the features don't override themselves, we need a state machine
	// to keep track which feature requested the config change.
	enum class ContentFeatureState { CONTENT_DETECTION_ON, CONTENT_DETECTION_OFF };
	enum class IdleTimerState { EXPIRED, RESET };
	enum class TouchState { INACTIVE, ACTIVE };
	enum class DisplayPowerTimerState { EXPIRED, RESET };

	// Creates a connection on the given EventThread and forwards the given callbacks.
	sp<EventThreadConnection> createConnectionInternal(EventThread*, ResyncCallback&&,
	ISurfaceComposer::ConfigChanged);

	nsecs_t calculateAverage() const;
	void updateFrameSkipping(const int64_t skipCount);

	// Function that is called when the timer resets.
	void resetTimerCallback();
	// Function that is called when the timer expires.
	void expiredTimerCallback();
	// Function that is called when the timer resets when paired with a display
	// driver timeout in the kernel. This enables hardware vsync when we move
	// out from idle.
	void resetKernelTimerCallback();
	// Function that is called when the timer expires when paired with a display
	// driver timeout in the kernel. This disables hardware vsync when we move
	// into idle.
	void expiredKernelTimerCallback();
	// Function that is called when the touch timer resets.
	void resetTouchTimerCallback();
	// Function that is called when the touch timer expires.
	void expiredTouchTimerCallback();
	// Function that is called when the display power timer resets.
	void resetDisplayPowerTimerCallback();
	// Function that is called when the display power timer expires.
	void expiredDisplayPowerTimerCallback();
	// Sets vsync period.
	void setVsyncPeriod(const nsecs_t period);
	// handles various timer features to change the refresh rate.
	template <class T>
	void handleTimerStateChanged(T* currentState, T newState, bool eventOnContentDetection);
	// Calculate the new refresh rate type
	RefreshRateType calculateRefreshRateType() REQUIRES(mFeatureStateLock);
	// Acquires a lock and calls the ChangeRefreshRateCallback() with given parameters.
	void changeRefreshRate(RefreshRateType refreshRateType, ConfigEvent configEvent);

	// Helper function to calculate error frames
	float getErrorFrames(float contentFps, float configFps);

	// If fences from sync Framework are supported.
	const bool mHasSyncFramework;

	// The offset in nanoseconds to use, when DispSync timestamps present fence
	// signaling time.
	nsecs_t mDispSyncPresentTimeOffset;

	// Each connection has it's own ID. This variable keeps track of the count.
	static std::atomic<int64_t> sNextId;

	// Connections are stored in a map <connection ID, connection> for easy retrieval.
	std::unordered_map<int64_t, std::unique_ptr<Connection>> mConnections;

	std::mutex mHWVsyncLock;
	bool mPrimaryHWVsyncEnabled GUARDED_BY(mHWVsyncLock);
	bool mHWVsyncAvailable GUARDED_BY(mHWVsyncLock);
	const std::shared_ptr<VsyncState> mPrimaryVsyncState{std::make_shared<VsyncState>(*this)};

	std::unique_ptr<DispSync> mPrimaryDispSync;
	std::unique_ptr<EventControlThread> mEventControlThread;

	// TODO(b/113612090): The following set of variables needs to be revised. For now, this is
	// a proof of concept. We turn on frame skipping if the difference between the timestamps
	// is between 32 and 34ms. We expect this currently for 30fps videos, so we render them at 30Hz.
	nsecs_t mPreviousFrameTimestamp = 0;
	// Keeping track of whether we are skipping the refresh count. If we want to
	// simulate 30Hz rendering, we skip every other frame, and this variable is set
	// to 1.
	int64_t mSkipCount = 0;
	std::array<int64_t, scheduler::ARRAY_SIZE> mTimeDifferences{};
	size_t mCounter = 0;

	// Historical information about individual layers. Used for predicting the refresh rate.
	scheduler::LayerHistory mLayerHistory;

	// Timer that records time between requests for next vsync. If the time is higher than a given
	// interval, a callback is fired. Set this variable to >0 to use this feature.
	int64_t mSetIdleTimerMs = 0;
	std::unique_ptr<scheduler::IdleTimer> mIdleTimer;
	// Enables whether to use idle timer callbacks that support the kernel
	// timer.
	bool mSupportKernelTimer;

	// Timer used to monitor touch events.
	int64_t mSetTouchTimerMs = 0;
	std::unique_ptr<scheduler::IdleTimer> mTouchTimer;

	// Timer used to monitor display power mode.
	int64_t mSetDisplayPowerTimerMs = 0;
	std::unique_ptr<scheduler::IdleTimer> mDisplayPowerTimer;

	std::mutex mCallbackLock;
	GetCurrentRefreshRateTypeCallback mGetCurrentRefreshRateTypeCallback GUARDED_BY(mCallbackLock);
	ChangeRefreshRateCallback mChangeRefreshRateCallback GUARDED_BY(mCallbackLock);
	GetVsyncPeriod mGetVsyncPeriod GUARDED_BY(mCallbackLock);

	// In order to make sure that the features don't override themselves, we need a state machine
	// to keep track which feature requested the config change.
	std::mutex mFeatureStateLock;
	ContentFeatureState mCurrentContentFeatureState GUARDED_BY(mFeatureStateLock) =
	ContentFeatureState::CONTENT_DETECTION_OFF;
	IdleTimerState mCurrentIdleTimerState GUARDED_BY(mFeatureStateLock) = IdleTimerState::RESET;
	TouchState mCurrentTouchState GUARDED_BY(mFeatureStateLock) = TouchState::INACTIVE;
	DisplayPowerTimerState mDisplayPowerTimerState GUARDED_BY(mFeatureStateLock) =
	DisplayPowerTimerState::EXPIRED;
	uint32_t mContentRefreshRate GUARDED_BY(mFeatureStateLock);
	RefreshRateType mRefreshRateType GUARDED_BY(mFeatureStateLock);
	bool mIsHDRContent GUARDED_BY(mFeatureStateLock) = false;
	bool mIsDisplayPowerStateNormal GUARDED_BY(mFeatureStateLock) = true;

	const scheduler::RefreshRateConfigs& mRefreshRateConfigs;

	// Global config to force HDR content to work on DEFAULT refreshRate
	static constexpr bool mForceHDRContentToDefaultRefreshRate = false;
	};

	} // namespace android