- extra check in castsink prevent null deref

- fix typos
- change bytecounter (size limit) to long instead of int
- fix some string/buffer strangeness in icecast2.cpp
- increase ringbuffer size from 2 to 5 seconds in JackDspSource.cpp
- prevent jack killing us on buffer overflow, we just report and continue 
- new producer/consumer scheme in MultiThreadedConnector.cpp it now runs parallel really
- some compiler warnings fixed
This commit is contained in:
oetelaar.automatisering@gmail.com 2013-04-11 18:52:57 +00:00
parent 8ac1639800
commit 43d89e2796
11 changed files with 242 additions and 139 deletions

View File

@ -1,4 +1,17 @@
next version
o Fix 'Ring Ruffer' reports.
- Increased buffer for jack to 5 seconds
- prevent darkice termination by jack, report no fatal problem when we
have a ringbuffer overflow, can happen during startup
If we can not handle input audio fast enough we just ignore the buffer
and skip it, and just report it.
- new multithreaded connector code, now handles encoders in parallel
and does not spin waiting, cpu load will be very much lower now
Codes uses 2 condition variables to report data availability and
consumer thread availability
- Hopes are that glitching reports will be a thing of the past
- minor compiler warnings fixed
(Fix by Edwin van den Oetelaar)
o Issue #56: Wrong icecast2 password isn't properly reported, fixed.
thanks to Filipe Roque <flip.roque@gmail.com>
o Issue #57: BufferedSink makes streams invalid, fixed.

View File

@ -290,7 +290,11 @@ class CastSink : public Sink, public virtual Reporter
inline virtual bool
isOpen ( void ) const throw ()
{
Sink *s = getSink();
if (s)
return getSink()->isOpen();
else
return false;
}
/**

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@ -252,7 +252,7 @@ Connector :: open ( void ) throw ( Exception )
/*------------------------------------------------------------------------------
* Transfer some data from the source to the sink
*----------------------------------------------------------------------------*/
unsigned int
unsigned long
Connector :: transfer ( unsigned long bytes,
unsigned int bufSize,
unsigned int sec,
@ -271,7 +271,7 @@ Connector :: transfer ( unsigned long bytes,
unsigned char * buf = new unsigned char[bufSize];
reportEvent( 6, "Connector :: tranfer, bytes", bytes);
reportEvent( 6, "Connector :: transfer, bytes", bytes);
for ( b = 0; !bytes || b < bytes; ) {
unsigned int d = 0;

View File

@ -228,7 +228,7 @@ class Connector : public virtual Referable, public virtual Reporter
* @return the number of bytes read from the Source.
* @exception Exception
*/
virtual unsigned int
virtual unsigned long
transfer ( unsigned long bytes,
unsigned int bufSize,
unsigned int sec,

View File

@ -70,12 +70,6 @@
static const char fileid[] = "$Id$";
/*------------------------------------------------------------------------------
* Size of string conversion buffer
*----------------------------------------------------------------------------*/
#define STRBUF_SIZE 32
/*------------------------------------------------------------------------------
* Expected positive response from server begins like this.
*----------------------------------------------------------------------------*/
@ -125,7 +119,8 @@ IceCast2 :: sendLogin ( void ) throw ( Exception )
Sink * sink = getSink();
Source * source = getSocket();
const char * str;
char resp[STRBUF_SIZE];
const int buflen = 1024; // some small buffer size
char resp[buflen]; // a little buffer
unsigned int len;
unsigned int lenExpected;
@ -178,7 +173,7 @@ IceCast2 :: sendLogin ( void ) throw ( Exception )
sink->write( str, strlen(str));
{
// send source:<password> encoded as base64
char * source = "source:";
const char * source = "source:";
const char * pwd = getPassword();
char * tmp = new char[Util::strLen(source) +
Util::strLen(pwd) + 1];
@ -197,10 +192,7 @@ IceCast2 :: sendLogin ( void ) throw ( Exception )
// send the ice- headers
str = "\nice-bitrate: ";
sink->write( str, strlen( str));
if ( log10(getBitRate()) >= (STRBUF_SIZE-2) ) {
throw Exception( __FILE__, __LINE__,
"bitrate does not fit string buffer", getBitRate());
}
sprintf( resp, "%d", getBitRate());
sink->write( resp, strlen( resp));
@ -243,10 +235,10 @@ IceCast2 :: sendLogin ( void ) throw ( Exception )
// read the response, expected response begins with responseOK
lenExpected = Util::strLen( responseOK);
if ( (len = source->read( resp, STRBUF_SIZE-1)) < lenExpected ) {
return false;
if ( (len = source->read( resp, buflen )) < lenExpected ) {
return false; // short read, no need to continue
}
resp[lenExpected] = 0;
resp[lenExpected] = '\x00'; // end string, truncate to expected length
reportEvent(5,resp);
@ -261,13 +253,16 @@ IceCast2 :: sendLogin ( void ) throw ( Exception )
}
if ( !Util::strEq( resp, responseOK) ) {
return false;
// some unexpected response from server
throw Exception( __FILE__, __LINE__,
"Icecast2 - Unexpected response from server");
}
// suck anything that the other side has to say
while ( source->canRead( 0, 0) &&
(len = source->read( resp, STRBUF_SIZE-1)) );
(len = source->read( resp, buflen )));
// all is well, we are connected
return true;
}

View File

@ -259,9 +259,11 @@ JackDspSource :: open ( void ) throw ( Exception )
// Create a ring buffer for each channel
rb_size = 2
* jack_get_sample_rate(client)
* sizeof (jack_default_audio_sample_t);
/* will take about 1 MB buffer for each channel */
rb_size = 5 /* number of seconds */
* jack_get_sample_rate(client) /* eg 48000 */
* sizeof (jack_default_audio_sample_t); /* eg 4 bytes */
for (c=0; c < getChannel(); c++) {
rb[c] = jack_ringbuffer_create(rb_size);
if (!rb[c]) {
@ -459,11 +461,22 @@ JackDspSource :: process_callback( jack_nframes_t nframes, void *arg )
/* copy data to ringbuffer; one per channel */
for (c=0; c < self->getChannel(); c++) {
char *buf = (char*)jack_port_get_buffer(self->ports[c], nframes);
size_t len = jack_ringbuffer_write(self->rb[c], buf, to_write);
if (len < to_write) {
Reporter::reportEvent( 1, "failed to write to ring ruffer");
return 1;
/* check space */
size_t len;
if (jack_ringbuffer_write_space(self->rb[c]) < to_write) {
/* buffer is overflowing, skip the incoming data */
jack_ringbuffer_write_advance(self->rb[c], to_write);
/* prevent blocking the ring buffer by updating internal pointers
* jack will now not terminate on xruns
*/
Reporter::reportEvent( 1, "ring buffer full, skipping data");
/* We do not return error to jack callback handler and keep going */
} else {
/* buffer has space, put data into ringbuffer */
len = jack_ringbuffer_write(self->rb[c], (char *) jack_port_get_buffer(
self->ports[c], nframes), to_write);
if (len != to_write)
Reporter::reportEvent( 1, "failed to write to ring buffer (can not happen)");
}
}

View File

@ -68,9 +68,10 @@ void
MultiThreadedConnector :: init ( bool reconnect ) throw ( Exception )
{
this->reconnect = reconnect;
pthread_mutex_init( &mutexProduce, 0);
pthread_cond_init( &condProduce, 0);
pthread_mutex_init( &mutex_start, 0);
pthread_cond_init( &cond_start, 0);
pthread_mutex_init( &mutex_done, 0);
pthread_cond_init( &cond_done, 0);
threads = 0;
}
@ -86,8 +87,10 @@ MultiThreadedConnector :: strip ( void ) throw ( Exception )
threads = 0;
}
pthread_cond_destroy( &condProduce);
pthread_mutex_destroy( &mutexProduce);
pthread_cond_destroy( &cond_start);
pthread_mutex_destroy( &mutex_start);
pthread_cond_destroy( &cond_done);
pthread_mutex_destroy( &mutex_done);
}
@ -100,8 +103,10 @@ MultiThreadedConnector :: MultiThreadedConnector (
: Connector( connector)
{
reconnect = connector.reconnect;
mutexProduce = connector.mutexProduce;
condProduce = connector.condProduce;
mutex_start = connector.mutex_start;
cond_start = connector.cond_start;
mutex_done = connector.mutex_done;
cond_done = connector.cond_done;
if ( threads ) {
delete[] threads;
@ -112,7 +117,6 @@ MultiThreadedConnector :: MultiThreadedConnector (
}
}
/*------------------------------------------------------------------------------
* Assignment operator
*----------------------------------------------------------------------------*/
@ -124,8 +128,10 @@ MultiThreadedConnector :: operator= ( const MultiThreadedConnector & connector )
Connector::operator=( connector);
reconnect = connector.reconnect;
mutexProduce = connector.mutexProduce;
condProduce = connector.condProduce;
mutex_start = connector.mutex_start;
cond_start = connector.cond_start;
mutex_done = connector.mutex_done;
cond_done = connector.cond_done;
if ( threads ) {
delete[] threads;
@ -139,7 +145,6 @@ MultiThreadedConnector :: operator= ( const MultiThreadedConnector & connector )
return *this;
}
/*------------------------------------------------------------------------------
* Open the source and all the sinks if needed
* Create the sink threads
@ -173,7 +178,7 @@ MultiThreadedConnector :: open ( void ) throw ( Exception )
threadData->connector = this;
threadData->ixSink = i;
threadData->accepting = true;
threadData->isDone = true;
threadData->isDone = 1; // 1==STOP, activate thread in transfer()
if ( pthread_create( &(threadData->thread),
&threadAttr,
ThreadData::threadFunction,
@ -187,10 +192,10 @@ MultiThreadedConnector :: open ( void ) throw ( Exception )
unsigned int j;
// signal to stop for all running threads
pthread_mutex_lock( &mutexProduce);
pthread_mutex_lock( &mutex_start);
running = false;
pthread_cond_broadcast( &condProduce);
pthread_mutex_unlock( &mutexProduce);
pthread_cond_broadcast( &cond_start);
pthread_mutex_unlock( &mutex_start);
for ( j = 0; j < i; ++j ) {
pthread_join( threads[j].thread, 0);
@ -209,14 +214,14 @@ MultiThreadedConnector :: open ( void ) throw ( Exception )
/*------------------------------------------------------------------------------
* Transfer some data from the source to the sink
*----------------------------------------------------------------------------*/
unsigned int
unsigned long
MultiThreadedConnector :: transfer ( unsigned long bytes,
unsigned int bufSize,
unsigned int sec,
unsigned int usec )
throw ( Exception )
{
unsigned int b;
unsigned long byteCounter; // when we reach byteCounter thread will end
if ( numSinks == 0 ) {
return 0;
@ -229,39 +234,64 @@ MultiThreadedConnector :: transfer ( unsigned long bytes,
dataBuffer = new unsigned char[bufSize];
dataSize = 0;
reportEvent( 6, "MultiThreadedConnector :: tranfer, bytes", bytes);
/* if bytes==0 transfer until end of program,
* if bytes>0 transfer upto number of bytes
*/
reportEvent( 6, "MultiThreadedConnector::transfer count:", bytes);
byteCounter = 0; // init, no data bytes sent yet
while (running && (bytes == 0 || byteCounter < bytes)) {
for ( b = 0; !bytes || b < bytes; ) {
if (source->canRead(sec, usec)) {
unsigned int i;
pthread_mutex_lock( &mutexProduce);
dataSize = source->read(dataBuffer, bufSize);
b += dataSize;
byteCounter += dataSize;
// check for EOF
if (dataSize == 0) {
reportEvent(3, "MultiThreadedConnector :: transfer, EOF");
pthread_mutex_unlock( &mutexProduce);
break;
}
pthread_mutex_lock(&mutex_start);
for (i = 0; i < numSinks; ++i) {
threads[i].isDone = false;
if (threads[i].accepting)
threads[i].isDone = 0; // consumers => RUN
}
// tell sink threads that there is some data available
pthread_cond_broadcast( &condProduce);
pthread_cond_broadcast(&cond_start); // kick the waiting consumers to look again
pthread_mutex_unlock(&mutex_start); // UNLOCK, release the consumers' cond variable
// wait for all sink threads to get done with this data
while ( true ) {
for ( i = 0; i < numSinks && threads[i].isDone; ++i );
if ( i == numSinks ) {
// we do not spin here, we just wait for an event from the consumers
pthread_mutex_lock(&mutex_done);
while ( 1 ) {
int rc = 0;
// wait for condition : releases mutex so other thread can change condition
rc = pthread_cond_wait(&cond_done, &mutex_done);
// mutex is locked again
if (rc != 0) {
reportEvent(1, "MultiThreadedConnector pthread_cond_wait() fail");
break;
}
pthread_cond_wait( &condProduce, &mutexProduce);
int acceptor_count=0;
int stopped_count=0;
for (i = 0; i < numSinks; ++i) {
if (threads[i].accepting) {
acceptor_count++; // number of accepting threads
if (threads[i].isDone == 1)
stopped_count++; // number of accepting threads which have STOP
}
pthread_mutex_unlock( &mutexProduce);
}
// break when all accepting threads are done
if (acceptor_count == stopped_count) {
break;
}
// at least one thread has not set the STOP flag yet
}
pthread_mutex_unlock(&mutex_done);
// at this point all consumers are done with the block
} else {
reportEvent(3,"MultiThreadedConnector :: transfer, can't read");
break;
@ -269,7 +299,7 @@ MultiThreadedConnector :: transfer ( unsigned long bytes,
}
delete[] dataBuffer;
return b;
return byteCounter;
}
@ -283,41 +313,54 @@ MultiThreadedConnector :: sinkThread( int ixSink )
ThreadData * threadData = &threads[ixSink];
Sink * sink = sinks[ixSink].get( );
while ( running ) {
while ( running )
{
// wait for some data to become available
pthread_mutex_lock( &mutexProduce);
while ( running && threadData->isDone ) {
pthread_cond_wait( &condProduce, &mutexProduce);
}
if ( !running ) {
pthread_mutex_unlock( &mutexProduce);
break;
// producer sets isDone==0 when consumer can continue
// producer sets isDone==2 or running==0 to request termination
pthread_mutex_lock( &mutex_start ); // LOCK
int rc=0;
while ( (rc==0) && running && (threadData->isDone==1) )
{
// wait for condition, releases lock
rc = pthread_cond_wait( &cond_start, &mutex_start );
// we hold the lock again
}
pthread_mutex_unlock( &mutex_start ); // UNLOCK
if ( threadData->cut) {
// something wrong or signal to quit detected
// break out of this loop, will end the thread
if ( running==false || threadData->isDone==2 || rc != 0 )
break;
if ( threadData->cut )
{
sink->cut( );
threadData->cut = false;
}
if ( threadData->accepting ) {
if ( sink->canWrite( 0, 0) ) {
try {
if ( threadData->accepting )
{
if ( sink->canWrite( 0, 0 ) )
{
try
{
sink->write( dataBuffer, dataSize );
} catch ( Exception & e ) {
} catch ( Exception & e )
{
// something wrong. don't accept more data, try to
// reopen the sink next time around
threadData->accepting = false;
}
} else {
}
else
{
reportEvent( 4,
"MultiThreadedConnector :: sinkThread can't write ",
ixSink );
// don't care if we can't write
}
}
threadData->isDone = true;
pthread_cond_broadcast( &condProduce);
pthread_mutex_unlock( &mutexProduce);
if ( !threadData->accepting ) {
if ( reconnect ) {
@ -334,14 +377,45 @@ MultiThreadedConnector :: sinkThread( int ixSink )
} catch ( Exception & e ) {
// don't care, just try and try again
}
} else {
// if !reconnect, just stop the connector
running = false;
}
else {
// if !reconnect, just stop the connector
// running = false; /* kill the whole application */
// tell that we used the databuffer, do not wait for us anymore
pthread_mutex_lock( &mutex_done );
threadData->isDone = 1; // 1==STOP
pthread_mutex_unlock( &mutex_done );
reportEvent( 4,
"MultiThreadedConnector :: sinkThread no reconnect? ",
ixSink );
try
{
threadData->accepting = false;
sink->close( );
} catch ( Exception & e )
{
// don't care, just try and try again
reportEvent( 9,
"MultiThreadedConnector :: sinkThread do not care2 ",
ixSink );
}
}
}
pthread_mutex_lock( &mutex_done );
threadData->isDone = 1; // producer will check this flag
pthread_cond_signal( &cond_done ); // signal producer
pthread_mutex_unlock( &mutex_done );
} /* is running */
/* just make sure nobody will be waiting for us when we terminate */
pthread_mutex_lock( &mutex_done );
threadData->isDone = 1; // STOP
pthread_cond_signal( &cond_done ); // signal producer
pthread_mutex_unlock( &mutex_done );
}
/*------------------------------------------------------------------------------
* Signal to each sink to cut what they've done so far, and start anew.
@ -369,16 +443,15 @@ MultiThreadedConnector :: close ( void ) throw ( Exception )
unsigned int i;
// signal to stop for all threads
pthread_mutex_lock( &mutexProduce);
pthread_mutex_lock( &mutex_start );
running = false;
pthread_cond_broadcast( &condProduce);
pthread_mutex_unlock( &mutexProduce);
pthread_cond_broadcast( &cond_start );
pthread_mutex_unlock( &mutex_start );
// wait for all the threads to finish
for ( i = 0; i < numSinks; ++i ) {
pthread_join( threads[i].thread, 0);
}
pthread_attr_destroy( &threadAttr);
Connector::close();
}

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@ -105,7 +105,7 @@ class MultiThreadedConnector : public virtual Connector
* Marks if the thread has processed the last batch
* of data.
*/
bool isDone;
int isDone;
/**
* A flag to show that the sink should be made to cut in the
@ -123,7 +123,7 @@ class MultiThreadedConnector : public virtual Connector
this->ixSink = 0;
this->thread = 0;
this->accepting = false;
this->isDone = false;
this->isDone = 1; // 0==RUN 1=STOP 2=TERMINATE
this->cut = false;
}
@ -138,15 +138,19 @@ class MultiThreadedConnector : public virtual Connector
threadFunction( void * param );
};
/**
* The mutex of this object.
/* mutex and cond variable for signaling new data
* the consumers wait for this
*/
pthread_mutex_t mutexProduce;
pthread_mutex_t mutex_start;
pthread_cond_t cond_start; // producer sets this
/**
* The conditional variable for presenting new data.
/* mutex and cond variable for signaling that a single thread has
* finished working on a block of data
* the producer waits for this, then checks if everyone is done
* and maybe waits again until everyone has finished on the data
*/
pthread_cond_t condProduce;
pthread_mutex_t mutex_done;
pthread_cond_t cond_done; // consumer sets this
/**
* The thread attributes.
@ -159,7 +163,7 @@ class MultiThreadedConnector : public virtual Connector
ThreadData * threads;
/**
* Signal if we're running or not, so the threads no if to stop.
* Signal if we're running or not running
*/
bool running;
@ -314,7 +318,7 @@ class MultiThreadedConnector : public virtual Connector
* @return the number of bytes read from the Source.
* @exception Exception
*/
virtual unsigned int
virtual unsigned long
transfer ( unsigned long bytes,
unsigned int bufSize,
unsigned int sec,

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@ -226,7 +226,7 @@ aflibConverter::resample( /* number of output samples returned */
int
aflibConverter::err_ret(char *s)
aflibConverter::err_ret(const char *s)
{
aflib_debug("resample: %s \n\n",s); /* Display error message */
return -1;

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@ -110,7 +110,7 @@ private:
operator=(const aflibConverter& op);
int
err_ret(char *s);
err_ret(const char *s);
void
deleteMemory();

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@ -97,7 +97,8 @@ void output_message(::aflibDebug::Level level, const char *msg) {
default:
break; // avoid compile warning
}
system(buff);
int r = system(buff);
if (r<0) fprintf(stderr, "aflibDebug, system() failed\n");
}
/*