template < typename IN_PORT_TYPE, typename OUT_PORT_TYPE > int randomizer_base::_forecastAndProcess( bool &eos, typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams ,
typename std::vector< gr_ostream< OUT_PORT_TYPE > > &ostreams )
{
typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList;
typedef typename std::vector< gr_ostream< OUT_PORT_TYPE > > _OStreamList;
typename _OStreamList::iterator ostream;
typename _IStreamList::iterator istream = istreams.begin();
int nout = 0;
bool dataReady = false;
if ( !eos ) {
uint64_t max_items_avail = 0;
for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) {
LOG_TRACE( randomizer_base, "GET MAX ITEMS: STREAM:"<< idx << " NITEMS/SCALARS:" <<
istream->nitems() << "/" << istream->_data.size() );
max_items_avail = std::max( istream->nitems(), max_items_avail );
}
if ( max_items_avail == 0 ) {
LOG_TRACE( randomizer_base, "DATA CHECK - MAX ITEMS NOUTPUT/MAX_ITEMS:" << noutput_items << "/" << max_items_avail);
return -1;
}
//
// calc number of output elements based on input items available
//
noutput_items = 0;
if ( !gr_sptr->fixed_rate() ) {
noutput_items = round_down((int32_t) (max_items_avail * gr_sptr->relative_rate()), gr_sptr->output_multiple());
LOG_TRACE( randomizer_base, " VARIABLE FORECAST NOUTPUT == " << noutput_items );
} else {
istream = istreams.begin();
for ( int i=0; istream != istreams.end(); i++, istream++ ) {
int t_noutput_items = gr_sptr->fixed_rate_ninput_to_noutput( istream->nitems() );
if ( gr_sptr->output_multiple_set() ) {
t_noutput_items = round_up(t_noutput_items, gr_sptr->output_multiple());
}
if ( t_noutput_items > 0 ) {
if ( noutput_items == 0 ) {
noutput_items = t_noutput_items;
}
if ( t_noutput_items <= noutput_items ) {
noutput_items = t_noutput_items;
}
}
}
LOG_TRACE( randomizer_base, " FIXED FORECAST NOUTPUT/output_multiple == " <<
noutput_items << "/" << gr_sptr->output_multiple());
}
//
// ask the block how much input they need to produce noutput_items...
// if enough data is available to process then set the dataReady flag
//
int32_t outMultiple = gr_sptr->output_multiple();
while ( !dataReady && noutput_items >= outMultiple ) {
//
// ask the block how much input they need to produce noutput_items...
//
gr_sptr->forecast(noutput_items, _ninput_items_required);
LOG_TRACE( randomizer_base, "--> FORECAST IN/OUT " << _ninput_items_required[0] << "/" << noutput_items );
istream = istreams.begin();
uint32_t dr_cnt=0;
for ( int idx=0 ; noutput_items > 0 && istream != istreams.end(); idx++, istream++ ) {
// check if buffer has enough elements
_input_ready[idx] = false;
if ( istream->nitems() >= (uint64_t)_ninput_items_required[idx] ) {
_input_ready[idx] = true;
dr_cnt++;
}
LOG_TRACE( randomizer_base, "ISTREAM DATACHECK NELMS/NITEMS/REQ/READY:" << istream->nelems() <<
"/" << istream->nitems() << "/" << _ninput_items_required[idx] << "/" << _input_ready[idx]);
}
if ( dr_cnt < istreams.size() ) {
if ( outMultiple > 1 ) {
noutput_items -= outMultiple;
} else {
noutput_items /= 2;
}
} else {
dataReady = true;
}
LOG_TRACE( randomizer_base, " TRIM FORECAST NOUTPUT/READY " << noutput_items << "/" << dataReady );
}
// check if data is ready...
if ( !dataReady ) {
LOG_TRACE( randomizer_base, "DATA CHECK - NOT ENOUGH DATA AVAIL/REQ:" << _istreams[0].nitems() <<
"/" << _ninput_items_required[0] );
return -1;
}
// reset looping variables
int ritems = 0;
int nitems = 0;
// reset caching vectors
_output_items.clear();
_input_items.clear();
_ninput_items.clear();
istream = istreams.begin();
for ( int idx=0 ; istream != istreams.end(); idx++, istream++ ) {
// check if the stream is ready
if ( !_input_ready[idx] ) {
continue;
}
// get number of items remaining
try {
ritems = gr_sptr->nitems_read( idx );
} catch(...){
// something bad has happened, we are missing an input stream
LOG_ERROR( randomizer_base, "MISSING INPUT STREAM FOR GR BLOCK, STREAM ID:" << istream->streamID );
return -2;
}
nitems = istream->nitems() - ritems;
LOG_TRACE( randomizer_base, " ISTREAM: IDX:" << idx << " ITEMS AVAIL/READ/REQ " << nitems << "/"
<< ritems << "/" << _ninput_items_required[idx] );
if ( nitems >= _ninput_items_required[idx] && nitems > 0 ) {
//remove eos checks ...if ( nitems < _ninput_items_required[idx] ) nitems=0;
_ninput_items.push_back( nitems );
_input_items.push_back( (const void *) (istream->read_pointer(ritems)) );
}
}
//
// setup output buffer vector based on noutput..
//
ostream = ostreams.begin();
for( ; ostream != ostreams.end(); ostream++ ) {
ostream->resize(noutput_items);
_output_items.push_back((void*)(ostream->write_pointer()) );
}
nout=0;
if ( _input_items.size() != 0 && serviceThread->threadRunning() ) {
LOG_TRACE( randomizer_base, " CALLING WORK.....N_OUT:" << noutput_items << " N_IN:" << nitems
<< " ISTREAMS:" << _input_items.size() << " OSTREAMS:" << _output_items.size());
nout = gr_sptr->general_work( noutput_items, _ninput_items, _input_items, _output_items);
LOG_TRACE( randomizer_base, "RETURN WORK ..... N_OUT:" << nout);
}
// check for stop condition from work method
if ( nout < gr_block::WORK_DONE ) {
LOG_WARN( randomizer_base, "WORK RETURNED STOP CONDITION..." << nout );
nout=0;
eos = true;
}
}
if (nout != 0 or eos ) {
noutput_items = nout;
LOG_TRACE( randomizer_base, " WORK RETURNED: NOUT : " << nout << " EOS:" << eos);
ostream = ostreams.begin();
typename IN_PORT_TYPE::dataTransfer *pkt=NULL;
for ( int idx=0 ; ostream != ostreams.end(); idx++, ostream++ ) {
pkt=NULL;
int inputIdx = idx;
if ( (size_t)(inputIdx) >= istreams.size() ) {
for ( inputIdx= istreams.size()-1; inputIdx > -1; inputIdx--) {
if ( istreams[inputIdx].pkt != NULL ) {
pkt = istreams[inputIdx].pkt;
break;
}
}
} else {
pkt = istreams[inputIdx].pkt;
}
LOG_TRACE( randomizer_base, "PUSHING DATA ITEMS/STREAM_ID " << ostream->nitems() << "/" << ostream->streamID );
if ( _maintainTimeStamp ) {
// set time stamp for output samples based on input time stamp
if ( ostream->nelems() == 0 ) {
#ifdef TEST_TIME_STAMP
LOG_DEBUG( randomizer_base, "SEED - TS SRI: xdelta:" << std::setprecision(12) << ostream->sri.xdelta );
LOG_DEBUG( randomizer_base, "OSTREAM WRITE: maint:" << _maintainTimeStamp );
LOG_DEBUG( randomizer_base, " mode:" << ostream->tstamp.tcmode );
LOG_DEBUG( randomizer_base, " status:" << ostream->tstamp.tcstatus );
LOG_DEBUG( randomizer_base, " offset:" << ostream->tstamp.toff );
LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << ostream->tstamp.twsec );
LOG_DEBUG( randomizer_base, "SEED - TS frac:" << std::setprecision(12) << ostream->tstamp.tfsec );
#endif
ostream->setTimeStamp( pkt->T, _maintainTimeStamp );
}
// write out samples, and set next time stamp based on xdelta and noutput_items
ostream->write ( noutput_items, eos );
} else {
// use incoming packet's time stamp to forward
if ( pkt ) {
#ifdef TEST_TIME_STAMP
LOG_DEBUG( randomizer_base, "OSTREAM SRI: items/xdelta:" << noutput_items << "/" << std::setprecision(12) << ostream->sri.xdelta );
LOG_DEBUG( randomizer_base, "PKT - TS maint:" << _maintainTimeStamp );
LOG_DEBUG( randomizer_base, " mode:" << pkt->T.tcmode );
LOG_DEBUG( randomizer_base, " status:" << pkt->T.tcstatus );
LOG_DEBUG( randomizer_base, " offset:" << pkt->T.toff );
LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << pkt->T.twsec );
LOG_DEBUG( randomizer_base, "PKT - TS frac:" << std::setprecision(12) << pkt->T.tfsec );
#endif
ostream->write( noutput_items, eos, pkt->T );
} else {
#ifdef TEST_TIME_STAMP
LOG_DEBUG( randomizer_base, "OSTREAM SRI: items/xdelta:" << noutput_items << "/" << std::setprecision(12) << ostream->sri.xdelta );
LOG_DEBUG( randomizer_base, "OSTREAM TOD maint:" << _maintainTimeStamp );
LOG_DEBUG( randomizer_base, " mode:" << ostream->tstamp.tcmode );
LOG_DEBUG( randomizer_base, " status:" << ostream->tstamp.tcstatus );
LOG_DEBUG( randomizer_base, " offset:" << ostream->tstamp.toff );
LOG_DEBUG( randomizer_base, " whole:" << std::setprecision(10) << ostream->tstamp.twsec );
LOG_DEBUG( randomizer_base, "OSTREAM TOD frac:" << std::setprecision(12) << ostream->tstamp.tfsec );
#endif
// use time of day as time stamp
ostream->write( noutput_items, eos, _maintainTimeStamp );
}
}
} // for ostreams
}
return nout;
}
template < typename IN_PORT_TYPE > int file_descriptor_sink_i_base::_forecastAndProcess( bool &eos, typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams )
{
typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList;
typename _IStreamList::iterator istream = istreams.begin();
int nout = 0;
bool dataReady = false;
if ( !eos ) {
uint64_t max_items_avail = 0;
for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) {
LOG_TRACE( file_descriptor_sink_i_base, "GET MAX ITEMS: STREAM:" << idx << " NITEMS/SCALARS:"
<< istream->nitems() << "/" << istream->_data.size() );
max_items_avail = std::max( istream->nitems(), max_items_avail );
}
//
// calc number of output items to produce
//
noutput_items = (int) (max_items_avail * gr_sptr->relative_rate ());
noutput_items = round_down (noutput_items, gr_sptr->output_multiple ());
if ( noutput_items <= 0 ) {
LOG_TRACE( file_descriptor_sink_i_base, "DATA CHECK - MAX ITEMS NOUTPUT/MAX_ITEMS:" << noutput_items << "/" << max_items_avail);
return -1;
}
if ( gr_sptr->fixed_rate() ) {
istream = istreams.begin();
for ( int i=0; istream != istreams.end(); i++, istream++ ) {
int t_noutput_items = gr_sptr->fixed_rate_ninput_to_noutput( istream->nitems() );
if ( gr_sptr->output_multiple_set() ) {
t_noutput_items = round_up(t_noutput_items, gr_sptr->output_multiple());
}
if ( t_noutput_items > 0 ) {
if ( noutput_items == 0 ) {
noutput_items = t_noutput_items;
}
if ( t_noutput_items <= noutput_items ) {
noutput_items = t_noutput_items;
}
}
}
LOG_TRACE( file_descriptor_sink_i_base, " FIXED FORECAST NOUTPUT/output_multiple == "
<< noutput_items << "/" << gr_sptr->output_multiple());
}
//
// ask the block how much input they need to produce noutput_items...
// if enough data is available to process then set the dataReady flag
//
int32_t outMultiple = gr_sptr->output_multiple();
while ( !dataReady && noutput_items >= outMultiple ) {
//
// ask the block how much input they need to produce noutput_items...
//
gr_sptr->forecast(noutput_items, _ninput_items_required);
LOG_TRACE( file_descriptor_sink_i_base, "--> FORECAST IN/OUT " << _ninput_items_required[0] << "/" << noutput_items );
istream = istreams.begin();
uint32_t dr_cnt=0;
for ( int idx=0 ; noutput_items > 0 && istream != istreams.end(); idx++, istream++ ) {
// check if buffer has enough elements
_input_ready[idx] = false;
if ( istream->nitems() >= (uint64_t)_ninput_items_required[idx] ) {
_input_ready[idx] = true;
dr_cnt++;
}
LOG_TRACE( file_descriptor_sink_i_base, "ISTREAM DATACHECK NELMS/NITEMS/REQ/READY:" <<
istream->nelems() << "/" << istream->nitems() << "/" <<
_ninput_items_required[idx] << "/" << _input_ready[idx]);
}
if ( dr_cnt < istreams.size() ) {
if ( outMultiple > 1 ) {
noutput_items -= outMultiple;
} else {
noutput_items /= 2;
}
} else {
dataReady = true;
}
LOG_TRACE( file_descriptor_sink_i_base, " TRIM FORECAST NOUTPUT/READY " << noutput_items << "/" << dataReady );
}
// check if data is ready...
if ( !dataReady ) {
LOG_TRACE( file_descriptor_sink_i_base, "DATA CHECK - NOT ENOUGH DATA AVAIL/REQ:"
<< _istreams[0].nitems() << "/" << _ninput_items_required[0] );
return -1;
}
// reset looping variables
int ritems = 0;
int nitems = 0;
// reset caching vectors
_output_items.clear();
_input_items.clear();
_ninput_items.clear();
istream = istreams.begin();
for ( int idx=0 ; istream != istreams.end(); idx++, istream++ ) {
// check if the stream is ready
if ( !_input_ready[idx] ) continue;
// get number of items remaining
try {
ritems = gr_sptr->nitems_read( idx );
} catch(...){
// something bad has happened, we are missing an input stream
LOG_ERROR( file_descriptor_sink_i_base, "MISSING INPUT STREAM FOR GR BLOCK, STREAM ID:" << istream->streamID );
return -2;
}
nitems = istream->nitems() - ritems;
LOG_TRACE( file_descriptor_sink_i_base, " ISTREAM: IDX:" << idx << " ITEMS AVAIL/READ/REQ " << nitems << "/"
<< ritems << "/" << _ninput_items_required[idx] );
if ( nitems >= _ninput_items_required[idx] && nitems > 0 ) {
//remove eos checks ...if ( nitems < _ninput_items_required[idx] ) nitems=0;
_ninput_items.push_back( nitems );
_input_items.push_back( (const void *) (istream->read_pointer(ritems)) );
}
}
nout=0;
if ( _input_items.size() != 0 && serviceThread->threadRunning() ) {
LOG_TRACE( file_descriptor_sink_i_base, " CALLING WORK.....N_OUT:" << noutput_items <<
" N_IN:" << nitems << " ISTREAMS:" << _input_items.size() <<
" OSTREAMS:" << _output_items.size());
nout = gr_sptr->general_work( noutput_items, _ninput_items, _input_items, _output_items);
// sink/analyzer patterns do not return items, so consume_each is not called in Gnu Radio BLOCK
if ( nout == 0 ) {
gr_sptr->consume_each(nitems);
}
LOG_TRACE( file_descriptor_sink_i_base, "RETURN WORK ..... N_OUT:" << nout);
}
// check for stop condition from work method
if ( nout < gr_block::WORK_DONE ) {
LOG_WARN( file_descriptor_sink_i_base, "WORK RETURNED STOP CONDITION..." << nout );
nout=0;
eos = true;
}
}
return nout;
}
template < typename IN_PORT_TYPE, typename OUT_PORT_TYPE > int randomizer_base::_transformerServiceFunction( typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams ,
typename std::vector< gr_ostream< OUT_PORT_TYPE > > &ostreams )
{
typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList;
typedef typename std::vector< gr_ostream< OUT_PORT_TYPE > > _OStreamList;
boost::mutex::scoped_lock lock(serviceThreadLock);
if ( validGRBlock() == false ) {
// create our processing block, and setup property notifiers
createBlock();
LOG_DEBUG( randomizer_base, " FINISHED BUILDING GNU RADIO BLOCK");
}
//process any Stream ID changes this could affect number of io streams
processStreamIdChanges();
if ( !validGRBlock() || istreams.size() == 0 || ostreams.size() == 0 ) {
LOG_WARN( randomizer_base, "NO STREAMS ATTACHED TO BLOCK..." );
return NOOP;
}
_input_ready.resize( istreams.size() );
_ninput_items_required.resize( istreams.size() );
_ninput_items.resize( istreams.size() );
_input_items.resize( istreams.size() );
_output_items.resize( ostreams.size() );
//
// RESOLVE: need to look at forecast strategy,
// 1) see how many read items are necessary for N number of outputs
// 2) read input data and see how much output we can produce
//
//
// Grab available data from input streams
//
typename _OStreamList::iterator ostream;
typename _IStreamList::iterator istream = istreams.begin();
int nitems=0;
for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) {
// note this a blocking read that can cause deadlocks
nitems = istream->read();
if ( istream->overrun() ) {
LOG_WARN( randomizer_base, " NOT KEEPING UP WITH STREAM ID:" << istream->streamID );
}
if ( istream->sriChanged() ) {
// RESOLVE - need to look at how SRI changes can affect Gnu Radio BLOCK state
LOG_DEBUG( randomizer_base, "SRI CHANGED, STREAMD IDX/ID: "
<< idx << "/" << istream->pkt->streamID );
setOutputStreamSRI( idx, istream->pkt->SRI );
}
}
LOG_TRACE( randomizer_base, "READ NITEMS: " << nitems );
if ( nitems <= 0 && !_istreams[0].eos() ) {
return NOOP;
}
bool eos = false;
int nout = 0;
bool workDone = false;
while ( nout > -1 && serviceThread->threadRunning() ) {
eos = false;
nout = _forecastAndProcess( eos, istreams, ostreams );
if ( nout > -1 ) {
workDone = true;
// we chunked on data so move read pointer..
istream = istreams.begin();
for ( ; istream != istreams.end(); istream++ ) {
int idx=std::distance( istreams.begin(), istream );
// if we processed data for this stream
if ( _input_ready[idx] ) {
size_t nitems = 0;
try {
nitems = gr_sptr->nitems_read( idx );
} catch(...){}
if ( nitems > istream->nitems() ) {
LOG_WARN( randomizer_base, "WORK CONSUMED MORE DATA THAN AVAILABLE, READ/AVAILABLE "
<< nitems << "/" << istream->nitems() );
nitems = istream->nitems();
}
istream->consume( nitems );
LOG_TRACE( randomizer_base, " CONSUME READ DATA ITEMS/REMAIN " << nitems << "/" << istream->nitems());
}
}
gr_sptr->reset_read_index();
}
// check for not enough data return
if ( nout == -1 ) {
// check for end of stream
istream = istreams.begin();
for ( ; istream != istreams.end() ; istream++) {
if ( istream->eos() ) {
eos=true;
}
}
if ( eos ) {
LOG_TRACE( randomizer_base, "EOS SEEN, SENDING DOWNSTREAM " );
_forecastAndProcess( eos, istreams, ostreams);
}
}
}
if ( eos ) {
istream = istreams.begin();
for ( ; istream != istreams.end() ; istream++ ) {
int idx=std::distance( istreams.begin(), istream );
LOG_DEBUG( randomizer_base, " CLOSING INPUT STREAM IDX:" << idx );
istream->close();
}
// close remaining output streams
ostream = ostreams.begin();
for ( ; eos && ostream != ostreams.end(); ostream++ ) {
int idx=std::distance( ostreams.begin(), ostream );
LOG_DEBUG( randomizer_base, " CLOSING OUTPUT STREAM IDX:" << idx );
ostream->close();
}
}
//
// set the read pointers of the GNU Radio Block to start at the beginning of the
// supplied buffers
//
gr_sptr->reset_read_index();
LOG_TRACE( randomizer_base, " END OF TRANSFORM SERVICE FUNCTION....." << noutput_items );
if ( nout == -1 && eos == false && !workDone ) {
return NOOP;
} else {
return NORMAL;
}
}
template < typename IN_PORT_TYPE > int vector_sink_s_base::_analyzerServiceFunction( typename std::vector< gr_istream< IN_PORT_TYPE > > &istreams ) {
typedef typename std::vector< gr_istream< IN_PORT_TYPE > > _IStreamList;
boost::mutex::scoped_lock lock(serviceThreadLock);
if ( validGRBlock() == false ) {
// create our processing block
createBlock();
LOG_DEBUG( vector_sink_s_base, " FINISHED BUILDING GNU RADIO BLOCK");
}
// process any Stream ID changes this could affect number of io streams
processStreamIdChanges();
if ( !validGRBlock() || istreams.size() == 0 ) {
LOG_WARN(vector_sink_s_base, "NO STREAMS ATTACHED TO BLOCK..." );
return NOOP;
}
// resize data vectors for passing data to GR_BLOCK object
_input_ready.resize( istreams.size() );
_ninput_items_required.resize( istreams.size());
_ninput_items.resize( istreams.size());
_input_items.resize(istreams.size());
_output_items.resize(0);
//
// RESOLVE: need to look at forecast strategy,
// 1) see how many read items are necessary for N number of outputs
// 2) read input data and see how much output we can produce
//
//
// Grab available data from input streams
//
typename _IStreamList::iterator istream = istreams.begin();
int nitems=0;
for ( int idx=0 ; istream != istreams.end() && serviceThread->threadRunning() ; idx++, istream++ ) {
// note this a blocking read that can cause deadlocks
nitems = istream->read();
if ( istream->overrun() ) {
LOG_WARN( vector_sink_s_base, " NOT KEEPING UP WITH STREAM ID:" << istream->streamID );
}
// RESOLVE issue when SRI changes that could affect the GNU Radio BLOCK
if ( istream->sriChanged() ) {
LOG_DEBUG( vector_sink_s_base, "SRI CHANGED, STREAMD IDX/ID: "
<< idx << "/" << istream->pkt->streamID );
}
}
LOG_TRACE( vector_sink_s_base, "READ NITEMS: " << nitems );
if ( nitems <= 0 && !_istreams[0].eos() ) return NOOP;
bool exitServiceFunction = false;
bool eos = false;
int nout = 0;
while ( nout > -1 && !exitServiceFunction && serviceThread->threadRunning() ) {
eos = false;
nout = _forecastAndProcess( eos, istreams );
if ( nout > -1 ) {
// we chunked on data so move read pointer..
istream = istreams.begin();
for ( ; istream != istreams.end(); istream++ ) {
int idx=std::distance( istreams.begin(), istream );
// if we processed data for this stream
if ( _input_ready[idx] ) {
size_t nitems = 0;
try {
nitems = gr_sptr->nitems_read( idx );
}
catch(...){}
if ( nitems > istream->nitems() ) {
LOG_WARN( vector_sink_s_base, "WORK CONSUMED MORE DATA THAN AVAILABLE, READ/AVAILABLE " << nitems << "/" << istream->nitems() );
nitems = istream->nitems();
}
istream->consume( nitems );
LOG_TRACE( vector_sink_s_base, " CONSUME READ DATA ITEMS/REMAIN " << nitems << "/" << istream->nitems());
}
}
gr_sptr->reset_read_index();
}
// check for not enough data return
if ( nout == -1 ) {
// check for end of stream
istream = istreams.begin();
for ( ; istream != istreams.end() ; istream++) if ( istream->eos() ) eos=true;
if ( eos ) {
LOG_TRACE( vector_sink_s_base, " DATA NOT READY, EOS:" << eos );
_forecastAndProcess( eos, istreams );
}
exitServiceFunction = true;
}
}
if ( eos ) {
istream = istreams.begin();
for ( ; istream != istreams.end() ; istream++) {
int idx=std::distance( istreams.begin(), istream );
LOG_TRACE( vector_sink_s_base, " CLOSING INPUT STREAM IDX:" << idx );
istream->close();
}
}
//
// set the read pointers of the GNU Radio Block to start at the beginning of the
// supplied buffers
//
gr_sptr->reset_read_index();
LOG_TRACE( vector_sink_s_base, " END OF ANALYZER SERVICE FUNCTION....." << noutput_items );
if ( nout == -1 && eos == false )
return NOOP;
else
return NORMAL;
}
