modules/audio_coding/test/Channel.cc - src - Git at Google

 /*
  *  Copyright (c) 2012 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 "modules/audio_coding/test/Channel.h"

 #include <iostream>

 #include "rtc_base/strings/string_builder.h"
 #include "rtc_base/time_utils.h"

 namespace webrtc {

 int32_t Channel::SendData(AudioFrameType frameType,
                           uint8_t payloadType,
                           uint32_t timeStamp,
                           const uint8_t* payloadData,
                           size_t payloadSize,
                           int64_t absolute_capture_timestamp_ms) {
   RTPHeader rtp_header;
   int32_t status;
   size_t payloadDataSize = payloadSize;

   rtp_header.markerBit = false;
   rtp_header.ssrc = 0;
   rtp_header.sequenceNumber =
       (external_sequence_number_ < 0)
           ? _seqNo++
           : static_cast<uint16_t>(external_sequence_number_);
   rtp_header.payloadType = payloadType;
   rtp_header.timestamp = (external_send_timestamp_ < 0)
                              ? timeStamp
                              : static_cast<uint32_t>(external_send_timestamp_);

   if (frameType == AudioFrameType::kEmptyFrame) {
     // When frame is empty, we should not transmit it. The frame size of the
     // next non-empty frame will be based on the previous frame size.
     _useLastFrameSize = _lastFrameSizeSample > 0;
     return 0;
   }

   memcpy(_payloadData, payloadData, payloadDataSize);
   if (_isStereo) {
     if (_leftChannel) {
       _rtp_header = rtp_header;
       _leftChannel = false;
     } else {
       rtp_header = _rtp_header;
       _leftChannel = true;
     }
   }

   _channelCritSect.Lock();
   if (_saveBitStream) {
     // fwrite(payloadData, sizeof(uint8_t), payloadSize, _bitStreamFile);
   }

   if (!_isStereo) {
     CalcStatistics(rtp_header, payloadSize);
   }
   _useLastFrameSize = false;
   _lastInTimestamp = timeStamp;
   _totalBytes += payloadDataSize;
   _channelCritSect.Unlock();

   if (_useFECTestWithPacketLoss) {
     _packetLoss += 1;
     if (_packetLoss == 3) {
       _packetLoss = 0;
       return 0;
     }
   }

   if (num_packets_to_drop_ > 0) {
     num_packets_to_drop_--;
     return 0;
   }

   status =
       _receiverACM->IncomingPacket(_payloadData, payloadDataSize, rtp_header);

   return status;
 }

 // TODO(turajs): rewite this method.
 void Channel::CalcStatistics(const RTPHeader& rtp_header, size_t payloadSize) {
   int n;
   if ((rtp_header.payloadType != _lastPayloadType) &&
       (_lastPayloadType != -1)) {
     // payload-type is changed.
     // we have to terminate the calculations on the previous payload type
     // we ignore the last packet in that payload type just to make things
     // easier.
     for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
       if (_lastPayloadType == _payloadStats[n].payloadType) {
         _payloadStats[n].newPacket = true;
         break;
       }
     }
   }
   _lastPayloadType = rtp_header.payloadType;

   bool newPayload = true;
   ACMTestPayloadStats* currentPayloadStr = NULL;
   for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
     if (rtp_header.payloadType == _payloadStats[n].payloadType) {
       newPayload = false;
       currentPayloadStr = &_payloadStats[n];
       break;
     }
   }

   if (!newPayload) {
     if (!currentPayloadStr->newPacket) {
       if (!_useLastFrameSize) {
         _lastFrameSizeSample =
             (uint32_t)((uint32_t)rtp_header.timestamp -
                        (uint32_t)currentPayloadStr->lastTimestamp);
       }
       RTC_DCHECK_GT(_lastFrameSizeSample, 0);
       int k = 0;
       for (; k < MAX_NUM_FRAMESIZES; ++k) {
         if ((currentPayloadStr->frameSizeStats[k].frameSizeSample ==
              _lastFrameSizeSample) ||
             (currentPayloadStr->frameSizeStats[k].frameSizeSample == 0)) {
           break;
         }
       }
       if (k == MAX_NUM_FRAMESIZES) {
         // New frame size found but no space to count statistics on it. Skip it.
         printf("No memory to store statistics for payload %d : frame size %d\n",
                _lastPayloadType, _lastFrameSizeSample);
         return;
       }
       ACMTestFrameSizeStats* currentFrameSizeStats =
           &(currentPayloadStr->frameSizeStats[k]);
       currentFrameSizeStats->frameSizeSample = (int16_t)_lastFrameSizeSample;

       // increment the number of encoded samples.
       currentFrameSizeStats->totalEncodedSamples += _lastFrameSizeSample;
       // increment the number of recveived packets
       currentFrameSizeStats->numPackets++;
       // increment the total number of bytes (this is based on
       // the previous payload we don't know the frame-size of
       // the current payload.
       currentFrameSizeStats->totalPayloadLenByte +=
           currentPayloadStr->lastPayloadLenByte;
       // store the maximum payload-size (this is based on
       // the previous payload we don't know the frame-size of
       // the current payload.
       if (currentFrameSizeStats->maxPayloadLen <
           currentPayloadStr->lastPayloadLenByte) {
         currentFrameSizeStats->maxPayloadLen =
             currentPayloadStr->lastPayloadLenByte;
       }
       // store the current values for the next time
       currentPayloadStr->lastTimestamp = rtp_header.timestamp;
       currentPayloadStr->lastPayloadLenByte = payloadSize;
     } else {
       currentPayloadStr->newPacket = false;
       currentPayloadStr->lastPayloadLenByte = payloadSize;
       currentPayloadStr->lastTimestamp = rtp_header.timestamp;
       currentPayloadStr->payloadType = rtp_header.payloadType;
       memset(currentPayloadStr->frameSizeStats, 0,
              MAX_NUM_FRAMESIZES * sizeof(ACMTestFrameSizeStats));
     }
   } else {
     n = 0;
     while (_payloadStats[n].payloadType != -1) {
       n++;
     }
     // first packet
     _payloadStats[n].newPacket = false;
     _payloadStats[n].lastPayloadLenByte = payloadSize;
     _payloadStats[n].lastTimestamp = rtp_header.timestamp;
     _payloadStats[n].payloadType = rtp_header.payloadType;
     memset(_payloadStats[n].frameSizeStats, 0,
            MAX_NUM_FRAMESIZES * sizeof(ACMTestFrameSizeStats));
   }
 }

 Channel::Channel(int16_t chID)
     : _receiverACM(NULL),
       _seqNo(0),
       _bitStreamFile(NULL),
       _saveBitStream(false),
       _lastPayloadType(-1),
       _isStereo(false),
       _leftChannel(true),
       _lastInTimestamp(0),
       _useLastFrameSize(false),
       _lastFrameSizeSample(0),
       _packetLoss(0),
       _useFECTestWithPacketLoss(false),
       _beginTime(rtc::TimeMillis()),
       _totalBytes(0),
       external_send_timestamp_(-1),
       external_sequence_number_(-1),
       num_packets_to_drop_(0) {
   int n;
   int k;
   for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
     _payloadStats[n].payloadType = -1;
     _payloadStats[n].newPacket = true;
     for (k = 0; k < MAX_NUM_FRAMESIZES; k++) {
       _payloadStats[n].frameSizeStats[k].frameSizeSample = 0;
       _payloadStats[n].frameSizeStats[k].maxPayloadLen = 0;
       _payloadStats[n].frameSizeStats[k].numPackets = 0;
       _payloadStats[n].frameSizeStats[k].totalPayloadLenByte = 0;
       _payloadStats[n].frameSizeStats[k].totalEncodedSamples = 0;
     }
   }
   if (chID >= 0) {
     _saveBitStream = true;
     rtc::StringBuilder ss;
     ss.AppendFormat("bitStream_%d.dat", chID);
     _bitStreamFile = fopen(ss.str().c_str(), "wb");
   } else {
     _saveBitStream = false;
   }
 }

 Channel::~Channel() {}

 void Channel::RegisterReceiverACM(AudioCodingModule* acm) {
   _receiverACM = acm;
   return;
 }

 void Channel::ResetStats() {
   int n;
   int k;
   _channelCritSect.Lock();
   _lastPayloadType = -1;
   for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
     _payloadStats[n].payloadType = -1;
     _payloadStats[n].newPacket = true;
     for (k = 0; k < MAX_NUM_FRAMESIZES; k++) {
       _payloadStats[n].frameSizeStats[k].frameSizeSample = 0;
       _payloadStats[n].frameSizeStats[k].maxPayloadLen = 0;
       _payloadStats[n].frameSizeStats[k].numPackets = 0;
       _payloadStats[n].frameSizeStats[k].totalPayloadLenByte = 0;
       _payloadStats[n].frameSizeStats[k].totalEncodedSamples = 0;
     }
   }
   _beginTime = rtc::TimeMillis();
   _totalBytes = 0;
   _channelCritSect.Unlock();
 }

 uint32_t Channel::LastInTimestamp() {
   uint32_t timestamp;
   _channelCritSect.Lock();
   timestamp = _lastInTimestamp;
   _channelCritSect.Unlock();
   return timestamp;
 }

 double Channel::BitRate() {
   double rate;
   uint64_t currTime = rtc::TimeMillis();
   _channelCritSect.Lock();
   rate = ((double)_totalBytes * 8.0) / (double)(currTime - _beginTime);
   _channelCritSect.Unlock();
   return rate;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2012 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 "modules/audio_coding/test/Channel.h"

	#include <iostream>

	#include "rtc_base/strings/string_builder.h"
	#include "rtc_base/time_utils.h"

	namespace webrtc {

	int32_t Channel::SendData(AudioFrameType frameType,
	uint8_t payloadType,
	uint32_t timeStamp,
	const uint8_t* payloadData,
	size_t payloadSize,
	int64_t absolute_capture_timestamp_ms) {
	RTPHeader rtp_header;
	int32_t status;
	size_t payloadDataSize = payloadSize;

	rtp_header.markerBit = false;
	rtp_header.ssrc = 0;
	rtp_header.sequenceNumber =
	(external_sequence_number_ < 0)
	? _seqNo++
	: static_cast<uint16_t>(external_sequence_number_);
	rtp_header.payloadType = payloadType;
	rtp_header.timestamp = (external_send_timestamp_ < 0)
	? timeStamp
	: static_cast<uint32_t>(external_send_timestamp_);

	if (frameType == AudioFrameType::kEmptyFrame) {
	// When frame is empty, we should not transmit it. The frame size of the
	// next non-empty frame will be based on the previous frame size.
	_useLastFrameSize = _lastFrameSizeSample > 0;
	return 0;
	}

	memcpy(_payloadData, payloadData, payloadDataSize);
	if (_isStereo) {
	if (_leftChannel) {
	_rtp_header = rtp_header;
	_leftChannel = false;
	} else {
	rtp_header = _rtp_header;
	_leftChannel = true;
	}
	}

	_channelCritSect.Lock();
	if (_saveBitStream) {
	// fwrite(payloadData, sizeof(uint8_t), payloadSize, _bitStreamFile);
	}

	if (!_isStereo) {
	CalcStatistics(rtp_header, payloadSize);
	}
	_useLastFrameSize = false;
	_lastInTimestamp = timeStamp;
	_totalBytes += payloadDataSize;
	_channelCritSect.Unlock();

	if (_useFECTestWithPacketLoss) {
	_packetLoss += 1;
	if (_packetLoss == 3) {
	_packetLoss = 0;
	return 0;
	}
	}

	if (num_packets_to_drop_ > 0) {
	num_packets_to_drop_--;
	return 0;
	}

	status =
	_receiverACM->IncomingPacket(_payloadData, payloadDataSize, rtp_header);

	return status;
	}

	// TODO(turajs): rewite this method.
	void Channel::CalcStatistics(const RTPHeader& rtp_header, size_t payloadSize) {
	int n;
	if ((rtp_header.payloadType != _lastPayloadType) &&
	(_lastPayloadType != -1)) {
	// payload-type is changed.
	// we have to terminate the calculations on the previous payload type
	// we ignore the last packet in that payload type just to make things
	// easier.
	for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
	if (_lastPayloadType == _payloadStats[n].payloadType) {
	_payloadStats[n].newPacket = true;
	break;
	}
	}
	}
	_lastPayloadType = rtp_header.payloadType;

	bool newPayload = true;
	ACMTestPayloadStats* currentPayloadStr = NULL;
	for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
	if (rtp_header.payloadType == _payloadStats[n].payloadType) {
	newPayload = false;
	currentPayloadStr = &_payloadStats[n];
	break;
	}
	}

	if (!newPayload) {
	if (!currentPayloadStr->newPacket) {
	if (!_useLastFrameSize) {
	_lastFrameSizeSample =
	(uint32_t)((uint32_t)rtp_header.timestamp -
	(uint32_t)currentPayloadStr->lastTimestamp);
	}
	RTC_DCHECK_GT(_lastFrameSizeSample, 0);
	int k = 0;
	for (; k < MAX_NUM_FRAMESIZES; ++k) {
	if ((currentPayloadStr->frameSizeStats[k].frameSizeSample ==
	_lastFrameSizeSample) \|\|
	(currentPayloadStr->frameSizeStats[k].frameSizeSample == 0)) {
	break;
	}
	}
	if (k == MAX_NUM_FRAMESIZES) {
	// New frame size found but no space to count statistics on it. Skip it.
	printf("No memory to store statistics for payload %d : frame size %d\n",
	_lastPayloadType, _lastFrameSizeSample);
	return;
	}
	ACMTestFrameSizeStats* currentFrameSizeStats =
	&(currentPayloadStr->frameSizeStats[k]);
	currentFrameSizeStats->frameSizeSample = (int16_t)_lastFrameSizeSample;

	// increment the number of encoded samples.
	currentFrameSizeStats->totalEncodedSamples += _lastFrameSizeSample;
	// increment the number of recveived packets
	currentFrameSizeStats->numPackets++;
	// increment the total number of bytes (this is based on
	// the previous payload we don't know the frame-size of
	// the current payload.
	currentFrameSizeStats->totalPayloadLenByte +=
	currentPayloadStr->lastPayloadLenByte;
	// store the maximum payload-size (this is based on
	// the previous payload we don't know the frame-size of
	// the current payload.
	if (currentFrameSizeStats->maxPayloadLen <
	currentPayloadStr->lastPayloadLenByte) {
	currentFrameSizeStats->maxPayloadLen =
	currentPayloadStr->lastPayloadLenByte;
	}
	// store the current values for the next time
	currentPayloadStr->lastTimestamp = rtp_header.timestamp;
	currentPayloadStr->lastPayloadLenByte = payloadSize;
	} else {
	currentPayloadStr->newPacket = false;
	currentPayloadStr->lastPayloadLenByte = payloadSize;
	currentPayloadStr->lastTimestamp = rtp_header.timestamp;
	currentPayloadStr->payloadType = rtp_header.payloadType;
	memset(currentPayloadStr->frameSizeStats, 0,
	MAX_NUM_FRAMESIZES * sizeof(ACMTestFrameSizeStats));
	}
	} else {
	n = 0;
	while (_payloadStats[n].payloadType != -1) {
	n++;
	}
	// first packet
	_payloadStats[n].newPacket = false;
	_payloadStats[n].lastPayloadLenByte = payloadSize;
	_payloadStats[n].lastTimestamp = rtp_header.timestamp;
	_payloadStats[n].payloadType = rtp_header.payloadType;
	memset(_payloadStats[n].frameSizeStats, 0,
	MAX_NUM_FRAMESIZES * sizeof(ACMTestFrameSizeStats));
	}
	}

	Channel::Channel(int16_t chID)
	: _receiverACM(NULL),
	_seqNo(0),
	_bitStreamFile(NULL),
	_saveBitStream(false),
	_lastPayloadType(-1),
	_isStereo(false),
	_leftChannel(true),
	_lastInTimestamp(0),
	_useLastFrameSize(false),
	_lastFrameSizeSample(0),
	_packetLoss(0),
	_useFECTestWithPacketLoss(false),
	_beginTime(rtc::TimeMillis()),
	_totalBytes(0),
	external_send_timestamp_(-1),
	external_sequence_number_(-1),
	num_packets_to_drop_(0) {
	int n;
	int k;
	for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
	_payloadStats[n].payloadType = -1;
	_payloadStats[n].newPacket = true;
	for (k = 0; k < MAX_NUM_FRAMESIZES; k++) {
	_payloadStats[n].frameSizeStats[k].frameSizeSample = 0;
	_payloadStats[n].frameSizeStats[k].maxPayloadLen = 0;
	_payloadStats[n].frameSizeStats[k].numPackets = 0;
	_payloadStats[n].frameSizeStats[k].totalPayloadLenByte = 0;
	_payloadStats[n].frameSizeStats[k].totalEncodedSamples = 0;
	}
	}
	if (chID >= 0) {
	_saveBitStream = true;
	rtc::StringBuilder ss;
	ss.AppendFormat("bitStream_%d.dat", chID);
	_bitStreamFile = fopen(ss.str().c_str(), "wb");
	} else {
	_saveBitStream = false;
	}
	}

	Channel::~Channel() {}

	void Channel::RegisterReceiverACM(AudioCodingModule* acm) {
	_receiverACM = acm;
	return;
	}

	void Channel::ResetStats() {
	int n;
	int k;
	_channelCritSect.Lock();
	_lastPayloadType = -1;
	for (n = 0; n < MAX_NUM_PAYLOADS; n++) {
	_payloadStats[n].payloadType = -1;
	_payloadStats[n].newPacket = true;
	for (k = 0; k < MAX_NUM_FRAMESIZES; k++) {
	_payloadStats[n].frameSizeStats[k].frameSizeSample = 0;
	_payloadStats[n].frameSizeStats[k].maxPayloadLen = 0;
	_payloadStats[n].frameSizeStats[k].numPackets = 0;
	_payloadStats[n].frameSizeStats[k].totalPayloadLenByte = 0;
	_payloadStats[n].frameSizeStats[k].totalEncodedSamples = 0;
	}
	}
	_beginTime = rtc::TimeMillis();
	_totalBytes = 0;
	_channelCritSect.Unlock();
	}

	uint32_t Channel::LastInTimestamp() {
	uint32_t timestamp;
	_channelCritSect.Lock();
	timestamp = _lastInTimestamp;
	_channelCritSect.Unlock();
	return timestamp;
	}

	double Channel::BitRate() {
	double rate;
	uint64_t currTime = rtc::TimeMillis();
	_channelCritSect.Lock();
	rate = ((double)_totalBytes * 8.0) / (double)(currTime - _beginTime);
	_channelCritSect.Unlock();
	return rate;
	}

	} // namespace webrtc