zoneminder/src/zm_rtp_source.cpp

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//
// ZoneMinder RTP Source Class Implementation, $Date: 2006-01-17 10:56:30 +0000 (Tue, 17 Jan 2006) $, $Revision: 1829 $
// Copyright (C) 2003-2008 Philip Coombes
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation; either version 2
// of the License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
//
#include "zm_rtp_source.h"
#include "zm_time.h"
#include "zm_rtp_data.h"
#include <arpa/inet.h>
RtpSource::RtpSource( int id, const std::string &localHost, int localPortBase, const std::string &remoteHost, int remotePortBase, U32 ssrc, U16 seq, U32 rtpClock, U32 rtpTime ) :
mId( id ),
mSsrc( ssrc ),
mLocalHost( localHost ),
mRemoteHost( remoteHost ),
mRtpClock( rtpClock ),
mFrame( 65536 ),
mFrameCount( 0 ),
mFrameGood( true ),
mFrameReady( false ),
mFrameProcessed( false )
{
char hostname[256] = "";
gethostname( hostname, sizeof(hostname) );
mCname = stringtf( "zm-%d@%s", mId, hostname );
Debug( 3, "RTP CName = %s", mCname.c_str() );
init( seq );
mMaxSeq = seq - 1;
mProbation = MIN_SEQUENTIAL;
mLocalPortChans[0] = localPortBase;
mLocalPortChans[1] = localPortBase+1;
mRemotePortChans[0] = remotePortBase;
mRemotePortChans[1] = remotePortBase+1;
mRtpFactor = mRtpClock;
mBaseTimeReal = tvNow();
mBaseTimeNtp = tvZero();
mBaseTimeRtp = rtpTime;
mLastSrTimeReal = tvZero();
mLastSrTimeNtp = tvZero();
mLastSrTimeRtp = 0;
}
void RtpSource::init( U16 seq )
{
Debug( 3, "Initialising sequence" );
mBaseSeq = seq;
mMaxSeq = seq;
mBadSeq = RTP_SEQ_MOD + 1; // so seq == mBadSeq is false
mCycles = 0;
mReceivedPackets = 0;
mReceivedPrior = 0;
mExpectedPrior = 0;
// other initialization
mJitter = 0;
mTransit = 0;
}
bool RtpSource::updateSeq( U16 seq )
{
U16 uDelta = seq - mMaxSeq;
// Source is not valid until MIN_SEQUENTIAL packets with
// sequential sequence numbers have been received.
Debug( 5, "Seq: %d", seq );
if ( mProbation)
{
// packet is in sequence
if ( seq == mMaxSeq + 1)
{
Debug( 3, "Sequence in probation %ld, in sequence", mProbation );
mProbation--;
mMaxSeq = seq;
if ( mProbation == 0 )
{
init( seq );
mReceivedPackets++;
return( true );
}
}
else
{
Warning( "Sequence in probation %ld, out of sequence", mProbation );
mProbation = MIN_SEQUENTIAL - 1;
mMaxSeq = seq;
return( false );
}
return( true );
}
else if ( uDelta < MAX_DROPOUT )
{
if ( uDelta == 1 )
{
Debug( 3, "Packet in sequence, gap %d", uDelta );
}
else
{
Warning( "Packet in sequence, gap %d", uDelta );
}
// in order, with permissible gap
if ( seq < mMaxSeq )
{
// Sequence number wrapped - count another 64K cycle.
mCycles += RTP_SEQ_MOD;
}
mMaxSeq = seq;
}
else if ( uDelta <= RTP_SEQ_MOD - MAX_MISORDER )
{
Warning( "Packet out of sequence, gap %d", uDelta );
// the sequence number made a very large jump
if ( seq == mBadSeq )
{
Debug( 3, "Restarting sequence" );
// Two sequential packets -- assume that the other side
// restarted without telling us so just re-sync
// (i.e., pretend this was the first packet).
init( seq );
}
else
{
mBadSeq = (seq + 1) & (RTP_SEQ_MOD-1);
return( false );
}
}
else
{
Warning( "Packet duplicate or reordered, gap %d", uDelta );
// duplicate or reordered packet
return( false );
}
mReceivedPackets++;
return( uDelta==1?true:false );
}
void RtpSource::updateJitter( const RtpDataHeader *header )
{
if ( mRtpFactor > 0 )
{
Debug( 5, "Delta rtp = %.6f", tvDiffSec( mBaseTimeReal ) );
U32 localTimeRtp = mBaseTimeRtp + U32( tvDiffSec( mBaseTimeReal ) * mRtpFactor );
Debug( 5, "Local RTP time = %lx", localTimeRtp );
Debug( 5, "Packet RTP time = %x", ntohl(header->timestampN) );
U32 packetTransit = localTimeRtp - ntohl(header->timestampN);
Debug( 5, "Packet transit RTP time = %lx", packetTransit );
if ( mTransit > 0 )
{
// Jitter
int d = packetTransit - mTransit;
Debug( 5, "Jitter D = %d", d );
if ( d < 0 )
d = -d;
//mJitter += (1./16.) * ((double)d - mJitter);
mJitter += d - ((mJitter + 8) >> 4);
}
mTransit = packetTransit;
}
else
{
mJitter = 0;
}
Debug( 5, "RTP Jitter: %ld", mJitter );
}
void RtpSource::updateRtcpData( U32 ntpTimeSecs, U32 ntpTimeFrac, U32 rtpTime )
{
struct timeval ntpTime = tvMake( ntpTimeSecs, suseconds_t((USEC_PER_SEC*(ntpTimeFrac>>16))/(1<<16)) );
Debug( 5, "ntpTime: %ld.%06ld, rtpTime: %lx", ntpTime.tv_sec, ntpTime.tv_usec, rtpTime );
if ( mBaseTimeNtp.tv_sec == 0 )
{
mBaseTimeReal = tvNow();
mBaseTimeNtp = ntpTime;
mBaseTimeRtp = rtpTime;
}
else if ( !mRtpClock )
{
Debug( 5, "lastSrNtpTime: %ld.%06ld, rtpTime: %lx", mLastSrTimeNtp.tv_sec, mLastSrTimeNtp.tv_usec, rtpTime );
Debug( 5, "ntpTime: %ld.%06ld, rtpTime: %lx", ntpTime.tv_sec, ntpTime.tv_usec, rtpTime );
double diffNtpTime = tvDiffSec( mBaseTimeNtp, ntpTime );
U32 diffRtpTime = rtpTime - mBaseTimeRtp;
//Debug( 5, "Real-diff: %.6f", diffRealTime );
Debug( 5, "NTP-diff: %.6f", diffNtpTime );
Debug( 5, "RTP-diff: %ld", diffRtpTime );
mRtpFactor = (U32)(diffRtpTime / diffNtpTime);
Debug( 5, "RTPfactor: %ld", mRtpFactor );
}
mLastSrTimeNtpSecs = ntpTimeSecs;
mLastSrTimeNtpFrac = ntpTimeFrac;
mLastSrTimeNtp = ntpTime;
mLastSrTimeRtp = rtpTime;
}
void RtpSource::updateRtcpStats()
{
U32 extendedMax = mCycles + mMaxSeq;
mExpectedPackets = extendedMax - mBaseSeq + 1;
Debug( 5, "Expected packets = %ld", mExpectedPackets );
// The number of packets lost is defined to be the number of packets
// expected less the number of packets actually received:
mLostPackets = mExpectedPackets - mReceivedPackets;
Debug( 5, "Lost packets = %ld", mLostPackets );
U32 expectedInterval = mExpectedPackets - mExpectedPrior;
Debug( 5, "Expected interval = %ld", expectedInterval );
mExpectedPrior = mExpectedPackets;
U32 receivedInterval = mReceivedPackets - mReceivedPrior;
Debug( 5, "Received interval = %ld", receivedInterval );
mReceivedPrior = mReceivedPackets;
U32 lostInterval = expectedInterval - receivedInterval;
Debug( 5, "Lost interval = %ld", lostInterval );
if ( expectedInterval == 0 || lostInterval <= 0 )
mLostFraction = 0;
else
mLostFraction = (lostInterval << 8) / expectedInterval;
Debug( 5, "Lost fraction = %d", mLostFraction );
}
bool RtpSource::handlePacket( const unsigned char *packet, size_t packetLen )
{
const RtpDataHeader *rtpHeader;
rtpHeader = (RtpDataHeader *)packet;
if ( updateSeq( ntohs(rtpHeader->seqN) ) )
{
Hexdump( 4, packet+sizeof(RtpDataHeader), 16 );
if ( mFrameGood )
mFrame.Append( packet+sizeof(RtpDataHeader), packetLen-sizeof(RtpDataHeader) );
Hexdump( 4, mFrame.Head(), 16 );
if ( rtpHeader->m )
{
if ( mFrameGood )
{
Debug( 2, "Got new frame %d, %d bytes", mFrameCount, mFrame.Size() );
mFrameProcessed.setValueImmediate( false );
mFrameReady.updateValueSignal( true );
if ( !mFrameProcessed.getValueImmediate() )
{
for ( int count = 0; !mFrameProcessed.getUpdatedValue( 1 ); count++ )
if( count > 1 )
return( false );
}
mFrameCount++;
}
else
{
Warning( "Discarding incomplete frame %d, %d bytes", mFrameCount, mFrame.Size() );
}
mFrame.Empty();
}
}
else
{
if ( mFrame.Size() )
{
Warning( "Discarding partial frame %d, %d bytes", mFrameCount, mFrame.Size() );
}
else
{
Warning( "Discarding frame %d", mFrameCount );
}
mFrameGood = false;
mFrame.Empty();
}
if ( rtpHeader->m )
{
mFrameGood = true;
}
updateJitter( rtpHeader );
return( true );
}
bool RtpSource::getFrame( Buffer &buffer )
{
Debug( 3, "Getting frame" );
if ( !mFrameReady.getValueImmediate() )
{
// Allow for a couple of spurious returns
for ( int count = 0; !mFrameReady.getUpdatedValue( 1 ); count++ )
if ( count > 1 )
return( false );
}
buffer = mFrame;
mFrameReady.setValueImmediate( false );
mFrameProcessed.updateValueSignal( true );
Debug( 3, "Copied %d bytes", buffer.Size() );
return( true );
}