media/libaaudio/src/client/IsochronousClockModel.cpp - 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.
  */

 #define LOG_TAG "IsochronousClockModel"
 //#define LOG_NDEBUG 0
 #include <log/log.h>

 #include <stdint.h>

 #include "utility/AudioClock.h"
 #include "IsochronousClockModel.h"

 #define MIN_LATENESS_NANOS (10 * AAUDIO_NANOS_PER_MICROSECOND)

 using namespace aaudio;

 IsochronousClockModel::IsochronousClockModel()
         : mMarkerFramePosition(0)
         , mMarkerNanoTime(0)
         , mSampleRate(48000)
         , mFramesPerBurst(64)
         , mMaxLatenessInNanos(0)
         , mState(STATE_STOPPED)
 {
 }

 IsochronousClockModel::~IsochronousClockModel() {
 }

 void IsochronousClockModel::setPositionAndTime(int64_t framePosition, int64_t nanoTime) {
     ALOGV("setPositionAndTime(%lld, %lld)",
           (long long) framePosition, (long long) nanoTime);
     mMarkerFramePosition = framePosition;
     mMarkerNanoTime = nanoTime;
 }

 void IsochronousClockModel::start(int64_t nanoTime) {
     ALOGV("start(nanos = %lld)\n", (long long) nanoTime);
     mMarkerNanoTime = nanoTime;
     mState = STATE_STARTING;
 }

 void IsochronousClockModel::stop(int64_t nanoTime) {
     ALOGV("stop(nanos = %lld)\n", (long long) nanoTime);
     setPositionAndTime(convertTimeToPosition(nanoTime), nanoTime);
     // TODO should we set position?
     mState = STATE_STOPPED;
 }

 bool IsochronousClockModel::isStarting() const {
     return mState == STATE_STARTING;
 }

 bool IsochronousClockModel::isRunning() const {
     return mState == STATE_RUNNING;
 }

 void IsochronousClockModel::processTimestamp(int64_t framePosition, int64_t nanoTime) {
 //    ALOGD("processTimestamp() - framePosition = %lld at nanoTime %llu",
 //         (long long)framePosition,
 //         (long long)nanoTime);
     int64_t framesDelta = framePosition - mMarkerFramePosition;
     int64_t nanosDelta = nanoTime - mMarkerNanoTime;
     if (nanosDelta < 1000) {
         return;
     }

 //    ALOGD("processTimestamp() - mMarkerFramePosition = %lld at mMarkerNanoTime %llu",
 //         (long long)mMarkerFramePosition,
 //         (long long)mMarkerNanoTime);

     int64_t expectedNanosDelta = convertDeltaPositionToTime(framesDelta);
 //    ALOGD("processTimestamp() - expectedNanosDelta = %lld, nanosDelta = %llu",
 //         (long long)expectedNanosDelta,
 //         (long long)nanosDelta);

 //    ALOGD("processTimestamp() - mSampleRate = %d", mSampleRate);
 //    ALOGD("processTimestamp() - mState = %d", mState);
     switch (mState) {
     case STATE_STOPPED:
         break;
     case STATE_STARTING:
         setPositionAndTime(framePosition, nanoTime);
         mState = STATE_SYNCING;
         break;
     case STATE_SYNCING:
         // This will handle a burst of rapid transfer at the beginning.
         if (nanosDelta < expectedNanosDelta) {
             setPositionAndTime(framePosition, nanoTime);
         } else {
 //            ALOGD("processTimestamp() - advance to STATE_RUNNING");
             mState = STATE_RUNNING;
         }
         break;
     case STATE_RUNNING:
         if (nanosDelta < expectedNanosDelta) {
             // Earlier than expected timestamp.
             // This data is probably more accurate so use it.
             // or we may be drifting due to a slow HW clock.
 //            ALOGD("processTimestamp() - STATE_RUNNING - %d < %d micros - EARLY",
 //                 (int) (nanosDelta / 1000), (int)(expectedNanosDelta / 1000));
             setPositionAndTime(framePosition, nanoTime);
         } else if (nanosDelta > (expectedNanosDelta + mMaxLatenessInNanos)) {
             // Later than expected timestamp.
 //            ALOGD("processTimestamp() - STATE_RUNNING - %d > %d + %d micros - LATE",
 //                 (int) (nanosDelta / 1000), (int)(expectedNanosDelta / 1000),
 //                 (int) (mMaxLatenessInNanos / 1000));
             setPositionAndTime(framePosition - mFramesPerBurst,  nanoTime - mMaxLatenessInNanos);
         }
         break;
     default:
         break;
     }

 //    ALOGD("processTimestamp() - mState = %d", mState);
 }

 void IsochronousClockModel::setSampleRate(int32_t sampleRate) {
     mSampleRate = sampleRate;
     update();
 }

 void IsochronousClockModel::setFramesPerBurst(int32_t framesPerBurst) {
     mFramesPerBurst = framesPerBurst;
     update();
 }

 void IsochronousClockModel::update() {
     int64_t nanosLate = convertDeltaPositionToTime(mFramesPerBurst); // uses mSampleRate
     mMaxLatenessInNanos = (nanosLate > MIN_LATENESS_NANOS) ? nanosLate : MIN_LATENESS_NANOS;
 }

 int64_t IsochronousClockModel::convertDeltaPositionToTime(int64_t framesDelta) const {
     return (AAUDIO_NANOS_PER_SECOND * framesDelta) / mSampleRate;
 }

 int64_t IsochronousClockModel::convertDeltaTimeToPosition(int64_t nanosDelta) const {
     return (mSampleRate * nanosDelta) / AAUDIO_NANOS_PER_SECOND;
 }

 int64_t IsochronousClockModel::convertPositionToTime(int64_t framePosition) const {
     if (mState == STATE_STOPPED) {
         return mMarkerNanoTime;
     }
     int64_t nextBurstIndex = (framePosition + mFramesPerBurst - 1) / mFramesPerBurst;
     int64_t nextBurstPosition = mFramesPerBurst * nextBurstIndex;
     int64_t framesDelta = nextBurstPosition - mMarkerFramePosition;
     int64_t nanosDelta = convertDeltaPositionToTime(framesDelta);
     int64_t time = mMarkerNanoTime + nanosDelta;
 //    ALOGD("convertPositionToTime: pos = %llu --> time = %llu",
 //         (unsigned long long)framePosition,
 //         (unsigned long long)time);
     return time;
 }

 int64_t IsochronousClockModel::convertTimeToPosition(int64_t nanoTime) const {
     if (mState == STATE_STOPPED) {
         return mMarkerFramePosition;
     }
     int64_t nanosDelta = nanoTime - mMarkerNanoTime;
     int64_t framesDelta = convertDeltaTimeToPosition(nanosDelta);
     int64_t nextBurstPosition = mMarkerFramePosition + framesDelta;
     int64_t nextBurstIndex = nextBurstPosition / mFramesPerBurst;
     int64_t position = nextBurstIndex * mFramesPerBurst;
 //    ALOGD("convertTimeToPosition: time = %llu --> pos = %llu",
 //         (unsigned long long)nanoTime,
 //         (unsigned long long)position);
 //    ALOGD("convertTimeToPosition: framesDelta = %llu, mFramesPerBurst = %d",
 //         (long long) framesDelta, mFramesPerBurst);
     return position;
 }

 void IsochronousClockModel::dump() const {
     ALOGD("mMarkerFramePosition = %lld", (long long) mMarkerFramePosition);
     ALOGD("mMarkerNanoTime      = %lld", (long long) mMarkerNanoTime);
     ALOGD("mSampleRate          = %6d", mSampleRate);
     ALOGD("mFramesPerBurst      = %6d", mFramesPerBurst);
     ALOGD("mMaxLatenessInNanos  = %6d", mMaxLatenessInNanos);
     ALOGD("mState               = %6d", mState);
 }
	/*
	* 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.
	*/

	#define LOG_TAG "IsochronousClockModel"
	//#define LOG_NDEBUG 0
	#include <log/log.h>

	#include <stdint.h>

	#include "utility/AudioClock.h"
	#include "IsochronousClockModel.h"

	#define MIN_LATENESS_NANOS (10 * AAUDIO_NANOS_PER_MICROSECOND)

	using namespace aaudio;

	IsochronousClockModel::IsochronousClockModel()
	: mMarkerFramePosition(0)
	, mMarkerNanoTime(0)
	, mSampleRate(48000)
	, mFramesPerBurst(64)
	, mMaxLatenessInNanos(0)
	, mState(STATE_STOPPED)
	{
	}

	IsochronousClockModel::~IsochronousClockModel() {
	}

	void IsochronousClockModel::setPositionAndTime(int64_t framePosition, int64_t nanoTime) {
	ALOGV("setPositionAndTime(%lld, %lld)",
	(long long) framePosition, (long long) nanoTime);
	mMarkerFramePosition = framePosition;
	mMarkerNanoTime = nanoTime;
	}

	void IsochronousClockModel::start(int64_t nanoTime) {
	ALOGV("start(nanos = %lld)\n", (long long) nanoTime);
	mMarkerNanoTime = nanoTime;
	mState = STATE_STARTING;
	}

	void IsochronousClockModel::stop(int64_t nanoTime) {
	ALOGV("stop(nanos = %lld)\n", (long long) nanoTime);
	setPositionAndTime(convertTimeToPosition(nanoTime), nanoTime);
	// TODO should we set position?
	mState = STATE_STOPPED;
	}

	bool IsochronousClockModel::isStarting() const {
	return mState == STATE_STARTING;
	}

	bool IsochronousClockModel::isRunning() const {
	return mState == STATE_RUNNING;
	}

	void IsochronousClockModel::processTimestamp(int64_t framePosition, int64_t nanoTime) {
	// ALOGD("processTimestamp() - framePosition = %lld at nanoTime %llu",
	// (long long)framePosition,
	// (long long)nanoTime);
	int64_t framesDelta = framePosition - mMarkerFramePosition;
	int64_t nanosDelta = nanoTime - mMarkerNanoTime;
	if (nanosDelta < 1000) {
	return;
	}

	// ALOGD("processTimestamp() - mMarkerFramePosition = %lld at mMarkerNanoTime %llu",
	// (long long)mMarkerFramePosition,
	// (long long)mMarkerNanoTime);

	int64_t expectedNanosDelta = convertDeltaPositionToTime(framesDelta);
	// ALOGD("processTimestamp() - expectedNanosDelta = %lld, nanosDelta = %llu",
	// (long long)expectedNanosDelta,
	// (long long)nanosDelta);

	// ALOGD("processTimestamp() - mSampleRate = %d", mSampleRate);
	// ALOGD("processTimestamp() - mState = %d", mState);
	switch (mState) {
	case STATE_STOPPED:
	break;
	case STATE_STARTING:
	setPositionAndTime(framePosition, nanoTime);
	mState = STATE_SYNCING;
	break;
	case STATE_SYNCING:
	// This will handle a burst of rapid transfer at the beginning.
	if (nanosDelta < expectedNanosDelta) {
	setPositionAndTime(framePosition, nanoTime);
	} else {
	// ALOGD("processTimestamp() - advance to STATE_RUNNING");
	mState = STATE_RUNNING;
	}
	break;
	case STATE_RUNNING:
	if (nanosDelta < expectedNanosDelta) {
	// Earlier than expected timestamp.
	// This data is probably more accurate so use it.
	// or we may be drifting due to a slow HW clock.
	// ALOGD("processTimestamp() - STATE_RUNNING - %d < %d micros - EARLY",
	// (int) (nanosDelta / 1000), (int)(expectedNanosDelta / 1000));
	setPositionAndTime(framePosition, nanoTime);
	} else if (nanosDelta > (expectedNanosDelta + mMaxLatenessInNanos)) {
	// Later than expected timestamp.
	// ALOGD("processTimestamp() - STATE_RUNNING - %d > %d + %d micros - LATE",
	// (int) (nanosDelta / 1000), (int)(expectedNanosDelta / 1000),
	// (int) (mMaxLatenessInNanos / 1000));
	setPositionAndTime(framePosition - mFramesPerBurst, nanoTime - mMaxLatenessInNanos);
	}
	break;
	default:
	break;
	}

	// ALOGD("processTimestamp() - mState = %d", mState);
	}

	void IsochronousClockModel::setSampleRate(int32_t sampleRate) {
	mSampleRate = sampleRate;
	update();
	}

	void IsochronousClockModel::setFramesPerBurst(int32_t framesPerBurst) {
	mFramesPerBurst = framesPerBurst;
	update();
	}

	void IsochronousClockModel::update() {
	int64_t nanosLate = convertDeltaPositionToTime(mFramesPerBurst); // uses mSampleRate
	mMaxLatenessInNanos = (nanosLate > MIN_LATENESS_NANOS) ? nanosLate : MIN_LATENESS_NANOS;
	}

	int64_t IsochronousClockModel::convertDeltaPositionToTime(int64_t framesDelta) const {
	return (AAUDIO_NANOS_PER_SECOND * framesDelta) / mSampleRate;
	}

	int64_t IsochronousClockModel::convertDeltaTimeToPosition(int64_t nanosDelta) const {
	return (mSampleRate * nanosDelta) / AAUDIO_NANOS_PER_SECOND;
	}

	int64_t IsochronousClockModel::convertPositionToTime(int64_t framePosition) const {
	if (mState == STATE_STOPPED) {
	return mMarkerNanoTime;
	}
	int64_t nextBurstIndex = (framePosition + mFramesPerBurst - 1) / mFramesPerBurst;
	int64_t nextBurstPosition = mFramesPerBurst * nextBurstIndex;
	int64_t framesDelta = nextBurstPosition - mMarkerFramePosition;
	int64_t nanosDelta = convertDeltaPositionToTime(framesDelta);
	int64_t time = mMarkerNanoTime + nanosDelta;
	// ALOGD("convertPositionToTime: pos = %llu --> time = %llu",
	// (unsigned long long)framePosition,
	// (unsigned long long)time);
	return time;
	}

	int64_t IsochronousClockModel::convertTimeToPosition(int64_t nanoTime) const {
	if (mState == STATE_STOPPED) {
	return mMarkerFramePosition;
	}
	int64_t nanosDelta = nanoTime - mMarkerNanoTime;
	int64_t framesDelta = convertDeltaTimeToPosition(nanosDelta);
	int64_t nextBurstPosition = mMarkerFramePosition + framesDelta;
	int64_t nextBurstIndex = nextBurstPosition / mFramesPerBurst;
	int64_t position = nextBurstIndex * mFramesPerBurst;
	// ALOGD("convertTimeToPosition: time = %llu --> pos = %llu",
	// (unsigned long long)nanoTime,
	// (unsigned long long)position);
	// ALOGD("convertTimeToPosition: framesDelta = %llu, mFramesPerBurst = %d",
	// (long long) framesDelta, mFramesPerBurst);
	return position;
	}

	void IsochronousClockModel::dump() const {
	ALOGD("mMarkerFramePosition = %lld", (long long) mMarkerFramePosition);
	ALOGD("mMarkerNanoTime = %lld", (long long) mMarkerNanoTime);
	ALOGD("mSampleRate = %6d", mSampleRate);
	ALOGD("mFramesPerBurst = %6d", mFramesPerBurst);
	ALOGD("mMaxLatenessInNanos = %6d", mMaxLatenessInNanos);
	ALOGD("mState = %6d", mState);
	}