webrtc/system_wrappers/source/timestamp_extrapolator.cc - src - Git at Google

 /*
  *  Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "webrtc/system_wrappers/include/timestamp_extrapolator.h"

 #include <algorithm>

 namespace webrtc {

 TimestampExtrapolator::TimestampExtrapolator(int64_t start_ms)
     : _rwLock(RWLockWrapper::CreateRWLock()),
       _startMs(0),
       _firstTimestamp(0),
       _wrapArounds(0),
       _prevUnwrappedTimestamp(-1),
       _prevWrapTimestamp(-1),
       _lambda(1),
       _firstAfterReset(true),
       _packetCount(0),
       _startUpFilterDelayInPackets(2),
       _detectorAccumulatorPos(0),
       _detectorAccumulatorNeg(0),
       _alarmThreshold(60e3),
       _accDrift(6600),  // in timestamp ticks, i.e. 15 ms
       _accMaxError(7000),
       _pP11(1e10) {
     Reset(start_ms);
 }

 TimestampExtrapolator::~TimestampExtrapolator()
 {
     delete _rwLock;
 }

 void TimestampExtrapolator::Reset(int64_t start_ms)
 {
     WriteLockScoped wl(*_rwLock);
     _startMs = start_ms;
     _prevMs = _startMs;
     _firstTimestamp = 0;
     _w[0] = 90.0;
     _w[1] = 0;
     _pP[0][0] = 1;
     _pP[1][1] = _pP11;
     _pP[0][1] = _pP[1][0] = 0;
     _firstAfterReset = true;
     _prevUnwrappedTimestamp = -1;
     _prevWrapTimestamp = -1;
     _wrapArounds = 0;
     _packetCount = 0;
     _detectorAccumulatorPos = 0;
     _detectorAccumulatorNeg = 0;
 }

 void
 TimestampExtrapolator::Update(int64_t tMs, uint32_t ts90khz)
 {

     _rwLock->AcquireLockExclusive();
     if (tMs - _prevMs > 10e3)
     {
         // Ten seconds without a complete frame.
         // Reset the extrapolator
         _rwLock->ReleaseLockExclusive();
         Reset(tMs);
         _rwLock->AcquireLockExclusive();
     }
     else
     {
         _prevMs = tMs;
     }

     // Remove offset to prevent badly scaled matrices
     tMs -= _startMs;

     CheckForWrapArounds(ts90khz);

     int64_t unwrapped_ts90khz = static_cast<int64_t>(ts90khz) +
         _wrapArounds * ((static_cast<int64_t>(1) << 32) - 1);

     if (_prevUnwrappedTimestamp >= 0 &&
         unwrapped_ts90khz < _prevUnwrappedTimestamp)
     {
         // Drop reordered frames.
         _rwLock->ReleaseLockExclusive();
         return;
     }

     if (_firstAfterReset)
     {
         // Make an initial guess of the offset,
         // should be almost correct since tMs - _startMs
         // should about zero at this time.
         _w[1] = -_w[0] * tMs;
         _firstTimestamp = unwrapped_ts90khz;
         _firstAfterReset = false;
     }

     double residual =
         (static_cast<double>(unwrapped_ts90khz) - _firstTimestamp) -
         static_cast<double>(tMs) * _w[0] - _w[1];
     if (DelayChangeDetection(residual) &&
         _packetCount >= _startUpFilterDelayInPackets)
     {
         // A sudden change of average network delay has been detected.
         // Force the filter to adjust its offset parameter by changing
         // the offset uncertainty. Don't do this during startup.
         _pP[1][1] = _pP11;
     }
     //T = [t(k) 1]';
     //that = T'*w;
     //K = P*T/(lambda + T'*P*T);
     double K[2];
     K[0] = _pP[0][0] * tMs + _pP[0][1];
     K[1] = _pP[1][0] * tMs + _pP[1][1];
     double TPT = _lambda + tMs * K[0] + K[1];
     K[0] /= TPT;
     K[1] /= TPT;
     //w = w + K*(ts(k) - that);
     _w[0] = _w[0] + K[0] * residual;
     _w[1] = _w[1] + K[1] * residual;
     //P = 1/lambda*(P - K*T'*P);
     double p00 = 1 / _lambda *
         (_pP[0][0] - (K[0] * tMs * _pP[0][0] + K[0] * _pP[1][0]));
     double p01 = 1 / _lambda *
         (_pP[0][1] - (K[0] * tMs * _pP[0][1] + K[0] * _pP[1][1]));
     _pP[1][0] = 1 / _lambda *
         (_pP[1][0] - (K[1] * tMs * _pP[0][0] + K[1] * _pP[1][0]));
     _pP[1][1] = 1 / _lambda *
         (_pP[1][1] - (K[1] * tMs * _pP[0][1] + K[1] * _pP[1][1]));
     _pP[0][0] = p00;
     _pP[0][1] = p01;
     _prevUnwrappedTimestamp = unwrapped_ts90khz;
     if (_packetCount < _startUpFilterDelayInPackets)
     {
         _packetCount++;
     }
     _rwLock->ReleaseLockExclusive();
 }

 int64_t
 TimestampExtrapolator::ExtrapolateLocalTime(uint32_t timestamp90khz)
 {
     ReadLockScoped rl(*_rwLock);
     int64_t localTimeMs = 0;
     CheckForWrapArounds(timestamp90khz);
     double unwrapped_ts90khz = static_cast<double>(timestamp90khz) +
         _wrapArounds * ((static_cast<int64_t>(1) << 32) - 1);
     if (_packetCount == 0)
     {
         localTimeMs = -1;
     }
     else if (_packetCount < _startUpFilterDelayInPackets)
     {
         localTimeMs = _prevMs + static_cast<int64_t>(
             static_cast<double>(unwrapped_ts90khz - _prevUnwrappedTimestamp) /
             90.0 + 0.5);
     }
     else
     {
         if (_w[0] < 1e-3)
         {
             localTimeMs = _startMs;
         }
         else
         {
             double timestampDiff = unwrapped_ts90khz -
                 static_cast<double>(_firstTimestamp);
             localTimeMs = static_cast<int64_t>(
                 static_cast<double>(_startMs) + (timestampDiff - _w[1]) /
                 _w[0] + 0.5);
         }
     }
     return localTimeMs;
 }

 // Investigates if the timestamp clock has overflowed since the last timestamp and
 // keeps track of the number of wrap arounds since reset.
 void
 TimestampExtrapolator::CheckForWrapArounds(uint32_t ts90khz)
 {
     if (_prevWrapTimestamp == -1)
     {
         _prevWrapTimestamp = ts90khz;
         return;
     }
     if (ts90khz < _prevWrapTimestamp)
     {
         // This difference will probably be less than -2^31 if we have had a wrap around
         // (e.g. timestamp = 1, _previousTimestamp = 2^32 - 1). Since it is casted to a Word32,
         // it should be positive.
         if (static_cast<int32_t>(ts90khz - _prevWrapTimestamp) > 0)
         {
             // Forward wrap around
             _wrapArounds++;
         }
     }
     // This difference will probably be less than -2^31 if we have had a backward wrap around.
     // Since it is casted to a Word32, it should be positive.
     else if (static_cast<int32_t>(_prevWrapTimestamp - ts90khz) > 0)
     {
         // Backward wrap around
         _wrapArounds--;
     }
     _prevWrapTimestamp = ts90khz;
 }

 bool
 TimestampExtrapolator::DelayChangeDetection(double error)
 {
     // CUSUM detection of sudden delay changes
     error = (error > 0) ? std::min(error, _accMaxError) :
                           std::max(error, -_accMaxError);
     _detectorAccumulatorPos =
         std::max(_detectorAccumulatorPos + error - _accDrift, (double)0);
     _detectorAccumulatorNeg =
         std::min(_detectorAccumulatorNeg + error + _accDrift, (double)0);
     if (_detectorAccumulatorPos > _alarmThreshold || _detectorAccumulatorNeg < -_alarmThreshold)
     {
         // Alarm
         _detectorAccumulatorPos = _detectorAccumulatorNeg = 0;
         return true;
     }
     return false;
 }

 }
	/*
	* Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "webrtc/system_wrappers/include/timestamp_extrapolator.h"

	#include <algorithm>

	namespace webrtc {

	TimestampExtrapolator::TimestampExtrapolator(int64_t start_ms)
	: _rwLock(RWLockWrapper::CreateRWLock()),
	_startMs(0),
	_firstTimestamp(0),
	_wrapArounds(0),
	_prevUnwrappedTimestamp(-1),
	_prevWrapTimestamp(-1),
	_lambda(1),
	_firstAfterReset(true),
	_packetCount(0),
	_startUpFilterDelayInPackets(2),
	_detectorAccumulatorPos(0),
	_detectorAccumulatorNeg(0),
	_alarmThreshold(60e3),
	_accDrift(6600), // in timestamp ticks, i.e. 15 ms
	_accMaxError(7000),
	_pP11(1e10) {
	Reset(start_ms);
	}

	TimestampExtrapolator::~TimestampExtrapolator()
	{
	delete _rwLock;
	}

	void TimestampExtrapolator::Reset(int64_t start_ms)
	{
	WriteLockScoped wl(*_rwLock);
	_startMs = start_ms;
	_prevMs = _startMs;
	_firstTimestamp = 0;
	_w[0] = 90.0;
	_w[1] = 0;
	_pP[0][0] = 1;
	_pP[1][1] = _pP11;
	_pP[0][1] = _pP[1][0] = 0;
	_firstAfterReset = true;
	_prevUnwrappedTimestamp = -1;
	_prevWrapTimestamp = -1;
	_wrapArounds = 0;
	_packetCount = 0;
	_detectorAccumulatorPos = 0;
	_detectorAccumulatorNeg = 0;
	}

	void
	TimestampExtrapolator::Update(int64_t tMs, uint32_t ts90khz)
	{

	_rwLock->AcquireLockExclusive();
	if (tMs - _prevMs > 10e3)
	{
	// Ten seconds without a complete frame.
	// Reset the extrapolator
	_rwLock->ReleaseLockExclusive();
	Reset(tMs);
	_rwLock->AcquireLockExclusive();
	}
	else
	{
	_prevMs = tMs;
	}

	// Remove offset to prevent badly scaled matrices
	tMs -= _startMs;

	CheckForWrapArounds(ts90khz);

	int64_t unwrapped_ts90khz = static_cast<int64_t>(ts90khz) +
	_wrapArounds * ((static_cast<int64_t>(1) << 32) - 1);

	if (_prevUnwrappedTimestamp >= 0 &&
	unwrapped_ts90khz < _prevUnwrappedTimestamp)
	{
	// Drop reordered frames.
	_rwLock->ReleaseLockExclusive();
	return;
	}

	if (_firstAfterReset)
	{
	// Make an initial guess of the offset,
	// should be almost correct since tMs - _startMs
	// should about zero at this time.
	_w[1] = -_w[0] * tMs;
	_firstTimestamp = unwrapped_ts90khz;
	_firstAfterReset = false;
	}

	double residual =
	(static_cast<double>(unwrapped_ts90khz) - _firstTimestamp) -
	static_cast<double>(tMs) * _w[0] - _w[1];
	if (DelayChangeDetection(residual) &&
	_packetCount >= _startUpFilterDelayInPackets)
	{
	// A sudden change of average network delay has been detected.
	// Force the filter to adjust its offset parameter by changing
	// the offset uncertainty. Don't do this during startup.
	_pP[1][1] = _pP11;
	}
	//T = [t(k) 1]';
	//that = T'*w;
	//K = PT/(lambda + T'P*T);
	double K[2];
	K[0] = _pP[0][0] * tMs + _pP[0][1];
	K[1] = _pP[1][0] * tMs + _pP[1][1];
	double TPT = _lambda + tMs * K[0] + K[1];
	K[0] /= TPT;
	K[1] /= TPT;
	//w = w + K*(ts(k) - that);
	_w[0] = _w[0] + K[0] * residual;
	_w[1] = _w[1] + K[1] * residual;
	//P = 1/lambda(P - KT'*P);
	double p00 = 1 / _lambda *
	(_pP[0][0] - (K[0] * tMs * _pP[0][0] + K[0] * _pP[1][0]));
	double p01 = 1 / _lambda *
	(_pP[0][1] - (K[0] * tMs * _pP[0][1] + K[0] * _pP[1][1]));
	_pP[1][0] = 1 / _lambda *
	(_pP[1][0] - (K[1] * tMs * _pP[0][0] + K[1] * _pP[1][0]));
	_pP[1][1] = 1 / _lambda *
	(_pP[1][1] - (K[1] * tMs * _pP[0][1] + K[1] * _pP[1][1]));
	_pP[0][0] = p00;
	_pP[0][1] = p01;
	_prevUnwrappedTimestamp = unwrapped_ts90khz;
	if (_packetCount < _startUpFilterDelayInPackets)
	{
	_packetCount++;
	}
	_rwLock->ReleaseLockExclusive();
	}

	int64_t
	TimestampExtrapolator::ExtrapolateLocalTime(uint32_t timestamp90khz)
	{
	ReadLockScoped rl(*_rwLock);
	int64_t localTimeMs = 0;
	CheckForWrapArounds(timestamp90khz);
	double unwrapped_ts90khz = static_cast<double>(timestamp90khz) +
	_wrapArounds * ((static_cast<int64_t>(1) << 32) - 1);
	if (_packetCount == 0)
	{
	localTimeMs = -1;
	}
	else if (_packetCount < _startUpFilterDelayInPackets)
	{
	localTimeMs = _prevMs + static_cast<int64_t>(
	static_cast<double>(unwrapped_ts90khz - _prevUnwrappedTimestamp) /
	90.0 + 0.5);
	}
	else
	{
	if (_w[0] < 1e-3)
	{
	localTimeMs = _startMs;
	}
	else
	{
	double timestampDiff = unwrapped_ts90khz -
	static_cast<double>(_firstTimestamp);
	localTimeMs = static_cast<int64_t>(
	static_cast<double>(_startMs) + (timestampDiff - _w[1]) /
	_w[0] + 0.5);
	}
	}
	return localTimeMs;
	}

	// Investigates if the timestamp clock has overflowed since the last timestamp and
	// keeps track of the number of wrap arounds since reset.
	void
	TimestampExtrapolator::CheckForWrapArounds(uint32_t ts90khz)
	{
	if (_prevWrapTimestamp == -1)
	{
	_prevWrapTimestamp = ts90khz;
	return;
	}
	if (ts90khz < _prevWrapTimestamp)
	{
	// This difference will probably be less than -2^31 if we have had a wrap around
	// (e.g. timestamp = 1, _previousTimestamp = 2^32 - 1). Since it is casted to a Word32,
	// it should be positive.
	if (static_cast<int32_t>(ts90khz - _prevWrapTimestamp) > 0)
	{
	// Forward wrap around
	_wrapArounds++;
	}
	}
	// This difference will probably be less than -2^31 if we have had a backward wrap around.
	// Since it is casted to a Word32, it should be positive.
	else if (static_cast<int32_t>(_prevWrapTimestamp - ts90khz) > 0)
	{
	// Backward wrap around
	_wrapArounds--;
	}
	_prevWrapTimestamp = ts90khz;
	}

	bool
	TimestampExtrapolator::DelayChangeDetection(double error)
	{
	// CUSUM detection of sudden delay changes
	error = (error > 0) ? std::min(error, _accMaxError) :
	std::max(error, -_accMaxError);
	_detectorAccumulatorPos =
	std::max(_detectorAccumulatorPos + error - _accDrift, (double)0);
	_detectorAccumulatorNeg =
	std::min(_detectorAccumulatorNeg + error + _accDrift, (double)0);
	if (_detectorAccumulatorPos > _alarmThreshold \|\| _detectorAccumulatorNeg < -_alarmThreshold)
	{
	// Alarm
	_detectorAccumulatorPos = _detectorAccumulatorNeg = 0;
	return true;
	}
	return false;
	}

	}