services/surfaceflinger/FrameTimeline/FrameTimeline.h - android_frameworks_native - Gitiles

 /*
  * Copyright 2020 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 <../TimeStats/TimeStats.h>
 #include <gui/ISurfaceComposer.h>
 #include <gui/JankInfo.h>
 #include <perfetto/trace/android/frame_timeline_event.pbzero.h>
 #include <perfetto/tracing.h>
 #include <ui/FenceTime.h>
 #include <utils/RefBase.h>
 #include <utils/String16.h>
 #include <utils/Timers.h>
 #include <utils/Vector.h>

 #include <deque>
 #include <mutex>

 namespace android::frametimeline {

 enum JankMetadata {
     // Frame was presented earlier than expected
     EarlyPresent = 0x1,
     // Frame was presented later than expected
     LatePresent = 0x2,
     // App/SF started earlier than expected
     EarlyStart = 0x4,
     // App/SF started later than expected
     LateStart = 0x8,
     // App/SF finished work earlier than the deadline
     EarlyFinish = 0x10,
     // App/SF finished work later than the deadline
     LateFinish = 0x20,
     // SF was in GPU composition
     GpuComposition = 0x40,
 };

 class FrameTimelineTest;

 /*
  * Collection of timestamps that can be used for both predictions and actual times.
  */
 struct TimelineItem {
     TimelineItem(const nsecs_t startTime = 0, const nsecs_t endTime = 0,
                  const nsecs_t presentTime = 0)
           : startTime(startTime), endTime(endTime), presentTime(presentTime) {}

     nsecs_t startTime;
     nsecs_t endTime;
     nsecs_t presentTime;

     bool operator==(const TimelineItem& other) const {
         return startTime == other.startTime && endTime == other.endTime &&
                 presentTime == other.presentTime;
     }

     bool operator!=(const TimelineItem& other) const { return !(*this == other); }
 };

 /*
  * TokenManager generates a running number token for a set of predictions made by VsyncPredictor. It
  * saves these predictions for a short period of time and returns the predictions for a given token,
  * if it hasn't expired.
  */
 class TokenManager {
 public:
     virtual ~TokenManager() = default;

     // Generates a token for the given set of predictions. Stores the predictions for 120ms and
     // destroys it later.
     virtual int64_t generateTokenForPredictions(TimelineItem&& prediction) = 0;
 };

 enum class PredictionState {
     Valid,   // Predictions obtained successfully from the TokenManager
     Expired, // TokenManager no longer has the predictions
     None,    // Predictions are either not present or didn't come from TokenManager
 };

 /*
  * Stores a set of predictions and the corresponding actual timestamps pertaining to a single frame
  * from the app
  */
 class SurfaceFrame {
 public:
     enum class PresentState {
         Presented, // Buffer was latched and presented by SurfaceFlinger
         Dropped,   // Buffer was dropped by SurfaceFlinger
         Unknown,   // Initial state, SurfaceFlinger hasn't seen this buffer yet
     };

     virtual ~SurfaceFrame() = default;

     virtual TimelineItem getPredictions() const = 0;
     virtual TimelineItem getActuals() const = 0;
     virtual nsecs_t getActualQueueTime() const = 0;
     virtual PresentState getPresentState() const = 0;
     virtual PredictionState getPredictionState() const = 0;
     virtual pid_t getOwnerPid() const = 0;

     virtual void setPresentState(PresentState state) = 0;

     // Actual timestamps of the app are set individually at different functions.
     // Start time (if the app provides) and Queue time are accessible after queueing the frame,
     // whereas Acquire Fence time is available only during latch.
     virtual void setActualStartTime(nsecs_t actualStartTime) = 0;
     virtual void setActualQueueTime(nsecs_t actualQueueTime) = 0;
     virtual void setAcquireFenceTime(nsecs_t acquireFenceTime) = 0;
 };

 /*
  * Maintains a history of SurfaceFrames grouped together by the vsync time in which they were
  * presented
  */
 class FrameTimeline {
 public:
     virtual ~FrameTimeline() = default;
     virtual TokenManager* getTokenManager() = 0;

     // Initializes the Perfetto DataSource that emits DisplayFrame and SurfaceFrame events. Test
     // classes can avoid double registration by mocking this function.
     virtual void onBootFinished() = 0;

     // Create a new surface frame, set the predictions based on a token and return it to the caller.
     // Sets the PredictionState of SurfaceFrame.
     // Debug name is the human-readable debugging string for dumpsys.
     virtual std::unique_ptr<SurfaceFrame> createSurfaceFrameForToken(
             pid_t ownerPid, uid_t ownerUid, std::string layerName, std::string debugName,
             std::optional<int64_t> token) = 0;

     // Adds a new SurfaceFrame to the current DisplayFrame. Frames from multiple layers can be
     // composited into one display frame.
     virtual void addSurfaceFrame(std::unique_ptr<SurfaceFrame> surfaceFrame,
                                  SurfaceFrame::PresentState state) = 0;

     // The first function called by SF for the current DisplayFrame. Fetches SF predictions based on
     // the token and sets the actualSfWakeTime for the current DisplayFrame.
     virtual void setSfWakeUp(int64_t token, nsecs_t wakeupTime) = 0;

     // Sets the sfPresentTime and finalizes the current DisplayFrame. Tracks the given present fence
     // until it's signaled, and updates the present timestamps of all presented SurfaceFrames in
     // that vsync.
     virtual void setSfPresent(nsecs_t sfPresentTime,
                               const std::shared_ptr<FenceTime>& presentFence) = 0;

     // Args:
     // -jank : Dumps only the Display Frames that are either janky themselves
     //         or contain janky Surface Frames.
     // -all : Dumps the entire list of DisplayFrames and the SurfaceFrames contained within
     virtual void parseArgs(const Vector<String16>& args, std::string& result) = 0;

     // Sets the max number of display frames that can be stored. Called by SF backdoor.
     virtual void setMaxDisplayFrames(uint32_t size);

     // Restores the max number of display frames to default. Called by SF backdoor.
     virtual void reset() = 0;
 };

 namespace impl {

 using namespace std::chrono_literals;

 class TokenManager : public android::frametimeline::TokenManager {
 public:
     TokenManager() : mCurrentToken(ISurfaceComposer::INVALID_VSYNC_ID + 1) {}
     ~TokenManager() = default;

     int64_t generateTokenForPredictions(TimelineItem&& predictions) override;
     std::optional<TimelineItem> getPredictionsForToken(int64_t token);

 private:
     // Friend class for testing
     friend class android::frametimeline::FrameTimelineTest;

     void flushTokens(nsecs_t flushTime) REQUIRES(mMutex);

     std::unordered_map<int64_t, TimelineItem> mPredictions GUARDED_BY(mMutex);
     std::vector<std::pair<int64_t, nsecs_t>> mTokens GUARDED_BY(mMutex);
     int64_t mCurrentToken GUARDED_BY(mMutex);
     std::mutex mMutex;
     static constexpr nsecs_t kMaxRetentionTime =
             std::chrono::duration_cast<std::chrono::nanoseconds>(120ms).count();
 };

 class SurfaceFrame : public android::frametimeline::SurfaceFrame {
 public:
     SurfaceFrame(int64_t token, pid_t ownerPid, uid_t ownerUid, std::string layerName,
                  std::string debugName, PredictionState predictionState,
                  TimelineItem&& predictions);
     ~SurfaceFrame() = default;

     TimelineItem getPredictions() const override { return mPredictions; };
     TimelineItem getActuals() const override;
     nsecs_t getActualQueueTime() const override;
     PresentState getPresentState() const override;
     PredictionState getPredictionState() const override { return mPredictionState; };
     pid_t getOwnerPid() const override { return mOwnerPid; };
     JankType getJankType() const;
     int64_t getToken() const { return mToken; };
     nsecs_t getBaseTime() const;
     uid_t getOwnerUid() const { return mOwnerUid; };
     const std::string& getName() const { return mLayerName; };

     void setActualStartTime(nsecs_t actualStartTime) override;
     void setActualQueueTime(nsecs_t actualQueueTime) override;
     void setAcquireFenceTime(nsecs_t acquireFenceTime) override;
     void setPresentState(PresentState state) override;
     void setActualPresentTime(nsecs_t presentTime);
     void setJankInfo(JankType jankType, int32_t jankMetadata);

     // All the timestamps are dumped relative to the baseTime
     void dump(std::string& result, const std::string& indent, nsecs_t baseTime);

     // Emits a packet for perfetto tracing. The function body will be executed only if tracing is
     // enabled. The displayFrameToken is needed to link the SurfaceFrame to the corresponding
     // DisplayFrame at the trace processor side.
     void traceSurfaceFrame(int64_t displayFrameToken);

 private:
     const int64_t mToken;
     const pid_t mOwnerPid;
     const uid_t mOwnerUid;
     const std::string mLayerName;
     const std::string mDebugName;
     PresentState mPresentState GUARDED_BY(mMutex);
     const PredictionState mPredictionState;
     const TimelineItem mPredictions;
     TimelineItem mActuals GUARDED_BY(mMutex);
     nsecs_t mActualQueueTime GUARDED_BY(mMutex);
     mutable std::mutex mMutex;
     JankType mJankType GUARDED_BY(mMutex); // Enum for the type of jank
     int32_t mJankMetadata GUARDED_BY(mMutex); // Additional details about the jank
 };

 class FrameTimeline : public android::frametimeline::FrameTimeline {
 public:
     class FrameTimelineDataSource : public perfetto::DataSource<FrameTimelineDataSource> {
         void OnSetup(const SetupArgs&) override{};
         void OnStart(const StartArgs&) override{};
         void OnStop(const StopArgs&) override{};
     };

     FrameTimeline(std::shared_ptr<TimeStats> timeStats);
     ~FrameTimeline() = default;

     frametimeline::TokenManager* getTokenManager() override { return &mTokenManager; }
     std::unique_ptr<frametimeline::SurfaceFrame> createSurfaceFrameForToken(
             pid_t ownerPid, uid_t ownerUid, std::string layerName, std::string debugName,
             std::optional<int64_t> token) override;
     void addSurfaceFrame(std::unique_ptr<frametimeline::SurfaceFrame> surfaceFrame,
                          SurfaceFrame::PresentState state) override;
     void setSfWakeUp(int64_t token, nsecs_t wakeupTime) override;
     void setSfPresent(nsecs_t sfPresentTime,
                       const std::shared_ptr<FenceTime>& presentFence) override;
     void parseArgs(const Vector<String16>& args, std::string& result) override;
     void setMaxDisplayFrames(uint32_t size) override;
     void reset() override;

     // Sets up the perfetto tracing backend and data source.
     void onBootFinished() override;
     // Registers the data source with the perfetto backend. Called as part of onBootFinished()
     // and should not be called manually outside of tests.
     void registerDataSource();

     static constexpr char kFrameTimelineDataSource[] = "android.surfaceflinger.frametimeline";

 private:
     // Friend class for testing
     friend class android::frametimeline::FrameTimelineTest;

     /*
      * DisplayFrame should be used only internally within FrameTimeline.
      */
     struct DisplayFrame {
         DisplayFrame();

         int64_t token = ISurfaceComposer::INVALID_VSYNC_ID;

         /* Usage of TimelineItem w.r.t SurfaceFlinger
          * startTime    Time when SurfaceFlinger wakes up to handle transactions and buffer updates
          * endTime      Time when SurfaceFlinger sends a composited frame to Display
          * presentTime  Time when the composited frame was presented on screen
          */
         TimelineItem surfaceFlingerPredictions;
         TimelineItem surfaceFlingerActuals;

         // Collection of predictions and actual values sent over by Layers
         std::vector<std::unique_ptr<SurfaceFrame>> surfaceFrames;

         PredictionState predictionState = PredictionState::None;
         JankType jankType = JankType::None; // Enum for the type of jank
         int32_t jankMetadata = 0x0; // Additional details about the jank
     };

     void flushPendingPresentFences() REQUIRES(mMutex);
     void finalizeCurrentDisplayFrame() REQUIRES(mMutex);
     // BaseTime is the smallest timestamp in a DisplayFrame.
     // Used for dumping all timestamps relative to the oldest, making it easy to read.
     nsecs_t findBaseTime(const std::shared_ptr<DisplayFrame>&) REQUIRES(mMutex);
     void dumpDisplayFrame(std::string& result, const std::shared_ptr<DisplayFrame>&,
                           nsecs_t baseTime) REQUIRES(mMutex);
     void dumpAll(std::string& result);
     void dumpJank(std::string& result);

     // Emits a packet for perfetto tracing. The function body will be executed only if tracing is
     // enabled.
     void traceDisplayFrame(const DisplayFrame& displayFrame) REQUIRES(mMutex);

     // Sliding window of display frames. TODO(b/168072834): compare perf with fixed size array
     std::deque<std::shared_ptr<DisplayFrame>> mDisplayFrames GUARDED_BY(mMutex);
     std::vector<std::pair<std::shared_ptr<FenceTime>, std::shared_ptr<DisplayFrame>>>
             mPendingPresentFences GUARDED_BY(mMutex);
     std::shared_ptr<DisplayFrame> mCurrentDisplayFrame GUARDED_BY(mMutex);
     TokenManager mTokenManager;
     std::mutex mMutex;
     uint32_t mMaxDisplayFrames;
     std::shared_ptr<TimeStats> mTimeStats;
     static constexpr uint32_t kDefaultMaxDisplayFrames = 64;
     // The initial container size for the vector<SurfaceFrames> inside display frame. Although
     // this number doesn't represent any bounds on the number of surface frames that can go in a
     // display frame, this is a good starting size for the vector so that we can avoid the
     // internal vector resizing that happens with push_back.
     static constexpr uint32_t kNumSurfaceFramesInitial = 10;
     // The various thresholds for App and SF. If the actual timestamp falls within the threshold
     // compared to prediction, we don't treat it as a jank.
     static constexpr nsecs_t kPresentThreshold =
             std::chrono::duration_cast<std::chrono::nanoseconds>(2ms).count();
     static constexpr nsecs_t kDeadlineThreshold =
             std::chrono::duration_cast<std::chrono::nanoseconds>(2ms).count();
     static constexpr nsecs_t kSFStartThreshold =
             std::chrono::duration_cast<std::chrono::nanoseconds>(1ms).count();
 };

 } // namespace impl
 } // namespace android::frametimeline
	/*
	* Copyright 2020 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 <../TimeStats/TimeStats.h>
	#include <gui/ISurfaceComposer.h>
	#include <gui/JankInfo.h>
	#include <perfetto/trace/android/frame_timeline_event.pbzero.h>
	#include <perfetto/tracing.h>
	#include <ui/FenceTime.h>
	#include <utils/RefBase.h>
	#include <utils/String16.h>
	#include <utils/Timers.h>
	#include <utils/Vector.h>

	#include <deque>
	#include <mutex>

	namespace android::frametimeline {

	enum JankMetadata {
	// Frame was presented earlier than expected
	EarlyPresent = 0x1,
	// Frame was presented later than expected
	LatePresent = 0x2,
	// App/SF started earlier than expected
	EarlyStart = 0x4,
	// App/SF started later than expected
	LateStart = 0x8,
	// App/SF finished work earlier than the deadline
	EarlyFinish = 0x10,
	// App/SF finished work later than the deadline
	LateFinish = 0x20,
	// SF was in GPU composition
	GpuComposition = 0x40,
	};

	class FrameTimelineTest;

	/*
	* Collection of timestamps that can be used for both predictions and actual times.
	*/
	struct TimelineItem {
	TimelineItem(const nsecs_t startTime = 0, const nsecs_t endTime = 0,
	const nsecs_t presentTime = 0)
	: startTime(startTime), endTime(endTime), presentTime(presentTime) {}

	nsecs_t startTime;
	nsecs_t endTime;
	nsecs_t presentTime;

	bool operator==(const TimelineItem& other) const {
	return startTime == other.startTime && endTime == other.endTime &&
	presentTime == other.presentTime;
	}

	bool operator!=(const TimelineItem& other) const { return !(*this == other); }
	};

	/*
	* TokenManager generates a running number token for a set of predictions made by VsyncPredictor. It
	* saves these predictions for a short period of time and returns the predictions for a given token,
	* if it hasn't expired.
	*/
	class TokenManager {
	public:
	virtual ~TokenManager() = default;

	// Generates a token for the given set of predictions. Stores the predictions for 120ms and
	// destroys it later.
	virtual int64_t generateTokenForPredictions(TimelineItem&& prediction) = 0;
	};

	enum class PredictionState {
	Valid, // Predictions obtained successfully from the TokenManager
	Expired, // TokenManager no longer has the predictions
	None, // Predictions are either not present or didn't come from TokenManager
	};

	/*
	* Stores a set of predictions and the corresponding actual timestamps pertaining to a single frame
	* from the app
	*/
	class SurfaceFrame {
	public:
	enum class PresentState {
	Presented, // Buffer was latched and presented by SurfaceFlinger
	Dropped, // Buffer was dropped by SurfaceFlinger
	Unknown, // Initial state, SurfaceFlinger hasn't seen this buffer yet
	};

	virtual ~SurfaceFrame() = default;

	virtual TimelineItem getPredictions() const = 0;
	virtual TimelineItem getActuals() const = 0;
	virtual nsecs_t getActualQueueTime() const = 0;
	virtual PresentState getPresentState() const = 0;
	virtual PredictionState getPredictionState() const = 0;
	virtual pid_t getOwnerPid() const = 0;

	virtual void setPresentState(PresentState state) = 0;

	// Actual timestamps of the app are set individually at different functions.
	// Start time (if the app provides) and Queue time are accessible after queueing the frame,
	// whereas Acquire Fence time is available only during latch.
	virtual void setActualStartTime(nsecs_t actualStartTime) = 0;
	virtual void setActualQueueTime(nsecs_t actualQueueTime) = 0;
	virtual void setAcquireFenceTime(nsecs_t acquireFenceTime) = 0;
	};

	/*
	* Maintains a history of SurfaceFrames grouped together by the vsync time in which they were
	* presented
	*/
	class FrameTimeline {
	public:
	virtual ~FrameTimeline() = default;
	virtual TokenManager* getTokenManager() = 0;

	// Initializes the Perfetto DataSource that emits DisplayFrame and SurfaceFrame events. Test
	// classes can avoid double registration by mocking this function.
	virtual void onBootFinished() = 0;

	// Create a new surface frame, set the predictions based on a token and return it to the caller.
	// Sets the PredictionState of SurfaceFrame.
	// Debug name is the human-readable debugging string for dumpsys.
	virtual std::unique_ptr<SurfaceFrame> createSurfaceFrameForToken(
	pid_t ownerPid, uid_t ownerUid, std::string layerName, std::string debugName,
	std::optional<int64_t> token) = 0;

	// Adds a new SurfaceFrame to the current DisplayFrame. Frames from multiple layers can be
	// composited into one display frame.
	virtual void addSurfaceFrame(std::unique_ptr<SurfaceFrame> surfaceFrame,
	SurfaceFrame::PresentState state) = 0;

	// The first function called by SF for the current DisplayFrame. Fetches SF predictions based on
	// the token and sets the actualSfWakeTime for the current DisplayFrame.
	virtual void setSfWakeUp(int64_t token, nsecs_t wakeupTime) = 0;

	// Sets the sfPresentTime and finalizes the current DisplayFrame. Tracks the given present fence
	// until it's signaled, and updates the present timestamps of all presented SurfaceFrames in
	// that vsync.
	virtual void setSfPresent(nsecs_t sfPresentTime,
	const std::shared_ptr<FenceTime>& presentFence) = 0;

	// Args:
	// -jank : Dumps only the Display Frames that are either janky themselves
	// or contain janky Surface Frames.
	// -all : Dumps the entire list of DisplayFrames and the SurfaceFrames contained within
	virtual void parseArgs(const Vector<String16>& args, std::string& result) = 0;

	// Sets the max number of display frames that can be stored. Called by SF backdoor.
	virtual void setMaxDisplayFrames(uint32_t size);

	// Restores the max number of display frames to default. Called by SF backdoor.
	virtual void reset() = 0;
	};

	namespace impl {

	using namespace std::chrono_literals;

	class TokenManager : public android::frametimeline::TokenManager {
	public:
	TokenManager() : mCurrentToken(ISurfaceComposer::INVALID_VSYNC_ID + 1) {}
	~TokenManager() = default;

	int64_t generateTokenForPredictions(TimelineItem&& predictions) override;
	std::optional<TimelineItem> getPredictionsForToken(int64_t token);

	private:
	// Friend class for testing
	friend class android::frametimeline::FrameTimelineTest;

	void flushTokens(nsecs_t flushTime) REQUIRES(mMutex);

	std::unordered_map<int64_t, TimelineItem> mPredictions GUARDED_BY(mMutex);
	std::vector<std::pair<int64_t, nsecs_t>> mTokens GUARDED_BY(mMutex);
	int64_t mCurrentToken GUARDED_BY(mMutex);
	std::mutex mMutex;
	static constexpr nsecs_t kMaxRetentionTime =
	std::chrono::duration_cast<std::chrono::nanoseconds>(120ms).count();
	};

	class SurfaceFrame : public android::frametimeline::SurfaceFrame {
	public:
	SurfaceFrame(int64_t token, pid_t ownerPid, uid_t ownerUid, std::string layerName,
	std::string debugName, PredictionState predictionState,
	TimelineItem&& predictions);
	~SurfaceFrame() = default;

	TimelineItem getPredictions() const override { return mPredictions; };
	TimelineItem getActuals() const override;
	nsecs_t getActualQueueTime() const override;
	PresentState getPresentState() const override;
	PredictionState getPredictionState() const override { return mPredictionState; };
	pid_t getOwnerPid() const override { return mOwnerPid; };
	JankType getJankType() const;
	int64_t getToken() const { return mToken; };
	nsecs_t getBaseTime() const;
	uid_t getOwnerUid() const { return mOwnerUid; };
	const std::string& getName() const { return mLayerName; };

	void setActualStartTime(nsecs_t actualStartTime) override;
	void setActualQueueTime(nsecs_t actualQueueTime) override;
	void setAcquireFenceTime(nsecs_t acquireFenceTime) override;
	void setPresentState(PresentState state) override;
	void setActualPresentTime(nsecs_t presentTime);
	void setJankInfo(JankType jankType, int32_t jankMetadata);

	// All the timestamps are dumped relative to the baseTime
	void dump(std::string& result, const std::string& indent, nsecs_t baseTime);

	// Emits a packet for perfetto tracing. The function body will be executed only if tracing is
	// enabled. The displayFrameToken is needed to link the SurfaceFrame to the corresponding
	// DisplayFrame at the trace processor side.
	void traceSurfaceFrame(int64_t displayFrameToken);

	private:
	const int64_t mToken;
	const pid_t mOwnerPid;
	const uid_t mOwnerUid;
	const std::string mLayerName;
	const std::string mDebugName;
	PresentState mPresentState GUARDED_BY(mMutex);
	const PredictionState mPredictionState;
	const TimelineItem mPredictions;
	TimelineItem mActuals GUARDED_BY(mMutex);
	nsecs_t mActualQueueTime GUARDED_BY(mMutex);
	mutable std::mutex mMutex;
	JankType mJankType GUARDED_BY(mMutex); // Enum for the type of jank
	int32_t mJankMetadata GUARDED_BY(mMutex); // Additional details about the jank
	};

	class FrameTimeline : public android::frametimeline::FrameTimeline {
	public:
	class FrameTimelineDataSource : public perfetto::DataSource<FrameTimelineDataSource> {
	void OnSetup(const SetupArgs&) override{};
	void OnStart(const StartArgs&) override{};
	void OnStop(const StopArgs&) override{};
	};

	FrameTimeline(std::shared_ptr<TimeStats> timeStats);
	~FrameTimeline() = default;

	frametimeline::TokenManager* getTokenManager() override { return &mTokenManager; }
	std::unique_ptr<frametimeline::SurfaceFrame> createSurfaceFrameForToken(
	pid_t ownerPid, uid_t ownerUid, std::string layerName, std::string debugName,
	std::optional<int64_t> token) override;
	void addSurfaceFrame(std::unique_ptr<frametimeline::SurfaceFrame> surfaceFrame,
	SurfaceFrame::PresentState state) override;
	void setSfWakeUp(int64_t token, nsecs_t wakeupTime) override;
	void setSfPresent(nsecs_t sfPresentTime,
	const std::shared_ptr<FenceTime>& presentFence) override;
	void parseArgs(const Vector<String16>& args, std::string& result) override;
	void setMaxDisplayFrames(uint32_t size) override;
	void reset() override;

	// Sets up the perfetto tracing backend and data source.
	void onBootFinished() override;
	// Registers the data source with the perfetto backend. Called as part of onBootFinished()
	// and should not be called manually outside of tests.
	void registerDataSource();

	static constexpr char kFrameTimelineDataSource[] = "android.surfaceflinger.frametimeline";

	private:
	// Friend class for testing
	friend class android::frametimeline::FrameTimelineTest;

	/*
	* DisplayFrame should be used only internally within FrameTimeline.
	*/
	struct DisplayFrame {
	DisplayFrame();

	int64_t token = ISurfaceComposer::INVALID_VSYNC_ID;

	/* Usage of TimelineItem w.r.t SurfaceFlinger
	* startTime Time when SurfaceFlinger wakes up to handle transactions and buffer updates
	* endTime Time when SurfaceFlinger sends a composited frame to Display
	* presentTime Time when the composited frame was presented on screen
	*/
	TimelineItem surfaceFlingerPredictions;
	TimelineItem surfaceFlingerActuals;

	// Collection of predictions and actual values sent over by Layers
	std::vector<std::unique_ptr<SurfaceFrame>> surfaceFrames;

	PredictionState predictionState = PredictionState::None;
	JankType jankType = JankType::None; // Enum for the type of jank
	int32_t jankMetadata = 0x0; // Additional details about the jank
	};

	void flushPendingPresentFences() REQUIRES(mMutex);
	void finalizeCurrentDisplayFrame() REQUIRES(mMutex);
	// BaseTime is the smallest timestamp in a DisplayFrame.
	// Used for dumping all timestamps relative to the oldest, making it easy to read.
	nsecs_t findBaseTime(const std::shared_ptr<DisplayFrame>&) REQUIRES(mMutex);
	void dumpDisplayFrame(std::string& result, const std::shared_ptr<DisplayFrame>&,
	nsecs_t baseTime) REQUIRES(mMutex);
	void dumpAll(std::string& result);
	void dumpJank(std::string& result);

	// Emits a packet for perfetto tracing. The function body will be executed only if tracing is
	// enabled.
	void traceDisplayFrame(const DisplayFrame& displayFrame) REQUIRES(mMutex);

	// Sliding window of display frames. TODO(b/168072834): compare perf with fixed size array
	std::deque<std::shared_ptr<DisplayFrame>> mDisplayFrames GUARDED_BY(mMutex);
	std::vector<std::pair<std::shared_ptr<FenceTime>, std::shared_ptr<DisplayFrame>>>
	mPendingPresentFences GUARDED_BY(mMutex);
	std::shared_ptr<DisplayFrame> mCurrentDisplayFrame GUARDED_BY(mMutex);
	TokenManager mTokenManager;
	std::mutex mMutex;
	uint32_t mMaxDisplayFrames;
	std::shared_ptr<TimeStats> mTimeStats;
	static constexpr uint32_t kDefaultMaxDisplayFrames = 64;
	// The initial container size for the vector<SurfaceFrames> inside display frame. Although
	// this number doesn't represent any bounds on the number of surface frames that can go in a
	// display frame, this is a good starting size for the vector so that we can avoid the
	// internal vector resizing that happens with push_back.
	static constexpr uint32_t kNumSurfaceFramesInitial = 10;
	// The various thresholds for App and SF. If the actual timestamp falls within the threshold
	// compared to prediction, we don't treat it as a jank.
	static constexpr nsecs_t kPresentThreshold =
	std::chrono::duration_cast<std::chrono::nanoseconds>(2ms).count();
	static constexpr nsecs_t kDeadlineThreshold =
	std::chrono::duration_cast<std::chrono::nanoseconds>(2ms).count();
	static constexpr nsecs_t kSFStartThreshold =
	std::chrono::duration_cast<std::chrono::nanoseconds>(1ms).count();
	};

	} // namespace impl
	} // namespace android::frametimeline