media/libaaudio/src/client/IsochronousClockModel.h - third_party/android/platform/frameworks/av - Git at Google

 /*
  * Copyright (C) 2016 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.
  */

 #ifndef ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H
 #define ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H

 #include <stdint.h>
 #include "utility/AudioClock.h"

 namespace aaudio {

 /**
  * Model an isochronous data stream using occasional timestamps as input.
  * This can be used to predict the position of the stream at a given time.
  *
  * This class is not thread safe and should only be called from one thread.
  */
 class IsochronousClockModel {

 public:
     IsochronousClockModel();
     virtual ~IsochronousClockModel();

     void start(int64_t nanoTime);
     void stop(int64_t nanoTime);

     /**
      * @return true if the model is starting up
      */
     bool isStarting() const;

     /**
      * @return true if the model is running and producing valid results
      */
     bool isRunning() const;

     void processTimestamp(int64_t framePosition, int64_t nanoTime);

     /**
      * @param sampleRate rate of the stream in frames per second
      */
     void setSampleRate(int32_t sampleRate);

     void setPositionAndTime(int64_t framePosition, int64_t nanoTime);

     int32_t getSampleRate() const {
         return mSampleRate;
     }

     /**
      * This must be set accurately in order to track the isochronous stream.
      *
      * @param framesPerBurst number of frames that stream advance at one time.
      */
     void setFramesPerBurst(int32_t framesPerBurst);

     int32_t getFramesPerBurst() const {
         return mFramesPerBurst;
     }

     /**
      * Calculate an estimated time when the stream will be at that position.
      *
      * @param framePosition position of the stream in frames
      * @return time in nanoseconds
      */
     int64_t convertPositionToTime(int64_t framePosition) const;

     /**
      * Calculate the latest estimated time that the stream will be at that position.
      * The more jittery the clock is then the later this will be.
      *
      * @param framePosition
      * @return time in nanoseconds
      */
     int64_t convertPositionToLatestTime(int64_t framePosition) const;

     /**
      * Calculate an estimated position where the stream will be at the specified time.
      *
      * @param nanoTime time of interest
      * @return position in frames
      */
     int64_t convertTimeToPosition(int64_t nanoTime) const;

     /**
      * Calculate the corresponding estimated position based on the specified time being
      * the latest possible time.
      *
      * For the same nanoTime, this may return an earlier position than
      * convertTimeToPosition().
      *
      * @param nanoTime
      * @return position in frames
      */
     int64_t convertLatestTimeToPosition(int64_t nanoTime) const;

     /**
      * @param framesDelta difference in frames
      * @return duration in nanoseconds
      */
     int64_t convertDeltaPositionToTime(int64_t framesDelta) const;

     /**
      * @param nanosDelta duration in nanoseconds
      * @return frames that stream will advance in that time
      */
     int64_t convertDeltaTimeToPosition(int64_t nanosDelta) const;

     void dump() const;

 private:

     int32_t getLateTimeOffsetNanos() const;

     enum clock_model_state_t {
         STATE_STOPPED,
         STATE_STARTING,
         STATE_SYNCING,
         STATE_RUNNING
     };

     // Amount of time to drift forward when we get a late timestamp.
     // This value was calculated to allow tracking of a clock with 50 ppm error.
     static constexpr int32_t   kDriftNanos         =  10 * 1000;
     // TODO review value of kExtraLatenessNanos
     static constexpr int32_t   kExtraLatenessNanos = 100 * 1000;

     int64_t             mMarkerFramePosition;
     int64_t             mMarkerNanoTime;
     int32_t             mSampleRate;
     int32_t             mFramesPerBurst;
     int32_t             mBurstPeriodNanos;
     // Includes mBurstPeriodNanos because we sample randomly over time.
     int32_t             mMaxMeasuredLatenessNanos;
     clock_model_state_t mState;

     int32_t             mTimestampCount = 0;

     void update();
 };

 } /* namespace aaudio */

 #endif //ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H
	/*
	* Copyright (C) 2016 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.
	*/

	#ifndef ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H
	#define ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H

	#include <stdint.h>
	#include "utility/AudioClock.h"

	namespace aaudio {

	/**
	* Model an isochronous data stream using occasional timestamps as input.
	* This can be used to predict the position of the stream at a given time.
	*
	* This class is not thread safe and should only be called from one thread.
	*/
	class IsochronousClockModel {

	public:
	IsochronousClockModel();
	virtual ~IsochronousClockModel();

	void start(int64_t nanoTime);
	void stop(int64_t nanoTime);

	/**
	* @return true if the model is starting up
	*/
	bool isStarting() const;

	/**
	* @return true if the model is running and producing valid results
	*/
	bool isRunning() const;

	void processTimestamp(int64_t framePosition, int64_t nanoTime);

	/**
	* @param sampleRate rate of the stream in frames per second
	*/
	void setSampleRate(int32_t sampleRate);

	void setPositionAndTime(int64_t framePosition, int64_t nanoTime);

	int32_t getSampleRate() const {
	return mSampleRate;
	}

	/**
	* This must be set accurately in order to track the isochronous stream.
	*
	* @param framesPerBurst number of frames that stream advance at one time.
	*/
	void setFramesPerBurst(int32_t framesPerBurst);

	int32_t getFramesPerBurst() const {
	return mFramesPerBurst;
	}

	/**
	* Calculate an estimated time when the stream will be at that position.
	*
	* @param framePosition position of the stream in frames
	* @return time in nanoseconds
	*/
	int64_t convertPositionToTime(int64_t framePosition) const;

	/**
	* Calculate the latest estimated time that the stream will be at that position.
	* The more jittery the clock is then the later this will be.
	*
	* @param framePosition
	* @return time in nanoseconds
	*/
	int64_t convertPositionToLatestTime(int64_t framePosition) const;

	/**
	* Calculate an estimated position where the stream will be at the specified time.
	*
	* @param nanoTime time of interest
	* @return position in frames
	*/
	int64_t convertTimeToPosition(int64_t nanoTime) const;

	/**
	* Calculate the corresponding estimated position based on the specified time being
	* the latest possible time.
	*
	* For the same nanoTime, this may return an earlier position than
	* convertTimeToPosition().
	*
	* @param nanoTime
	* @return position in frames
	*/
	int64_t convertLatestTimeToPosition(int64_t nanoTime) const;

	/**
	* @param framesDelta difference in frames
	* @return duration in nanoseconds
	*/
	int64_t convertDeltaPositionToTime(int64_t framesDelta) const;

	/**
	* @param nanosDelta duration in nanoseconds
	* @return frames that stream will advance in that time
	*/
	int64_t convertDeltaTimeToPosition(int64_t nanosDelta) const;

	void dump() const;

	private:

	int32_t getLateTimeOffsetNanos() const;

	enum clock_model_state_t {
	STATE_STOPPED,
	STATE_STARTING,
	STATE_SYNCING,
	STATE_RUNNING
	};

	// Amount of time to drift forward when we get a late timestamp.
	// This value was calculated to allow tracking of a clock with 50 ppm error.
	static constexpr int32_t kDriftNanos = 10 * 1000;
	// TODO review value of kExtraLatenessNanos
	static constexpr int32_t kExtraLatenessNanos = 100 * 1000;

	int64_t mMarkerFramePosition;
	int64_t mMarkerNanoTime;
	int32_t mSampleRate;
	int32_t mFramesPerBurst;
	int32_t mBurstPeriodNanos;
	// Includes mBurstPeriodNanos because we sample randomly over time.
	int32_t mMaxMeasuredLatenessNanos;
	clock_model_state_t mState;

	int32_t mTimestampCount = 0;

	void update();
	};

	} /* namespace aaudio */

	#endif //ANDROID_AAUDIO_ISOCHRONOUS_CLOCK_MODEL_H