///////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2018 F4HKW //
// for F4EXB / SDRAngel //
// using LeanSDR Framework (C) 2016 F4DAV //
// //
// 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 as version 3 of the License, or //
// //
// 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 V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see . //
///////////////////////////////////////////////////////////////////////////////////
#include "datvdemod.h"
#include
#include
#include
#include
#include "audio/audiooutput.h"
#include "dsp/dspengine.h"
#include "dsp/downchannelizer.h"
#include "dsp/threadedbasebandsamplesink.h"
#include "device/devicesourceapi.h"
const QString DATVDemod::m_channelIdURI = "sdrangel.channel.demoddatv";
const QString DATVDemod::m_channelId = "DATVDemod";
MESSAGE_CLASS_DEFINITION(DATVDemod::MsgConfigureDATVDemod, Message)
MESSAGE_CLASS_DEFINITION(DATVDemod::MsgConfigureChannelizer, Message)
DATVDemod::DATVDemod(DeviceSourceAPI *deviceAPI) :
ChannelSinkAPI(m_channelIdURI),
m_deviceAPI(deviceAPI),
m_objSettingsMutex(QMutex::NonRecursive),
m_objRegisteredDATVScreen(NULL),
m_objVideoStream(NULL),
m_objRegisteredVideoRender(NULL),
m_objRenderThread(NULL),
m_enmModulation(BPSK /*DATV_FM1*/),
m_blnNeedConfigUpdate(false),
m_blnRenderingVideo(false)
{
setObjectName("DATVDemod");
//*************** DATV PARAMETERS ***************
m_blnInitialized=false;
CleanUpDATVFramework(false);
m_objVideoStream = new DATVideostream();
m_objRFFilter = new fftfilt(-256000.0 / 1024000.0, 256000.0 / 1024000.0, rfFilterFftLength);
m_channelizer = new DownChannelizer(this);
m_threadedChannelizer = new ThreadedBasebandSampleSink(m_channelizer, this);
m_deviceAPI->addThreadedSink(m_threadedChannelizer);
m_deviceAPI->addChannelAPI(this);
connect(m_channelizer, SIGNAL(inputSampleRateChanged()), this, SLOT(channelSampleRateChanged()));
}
DATVDemod::~DATVDemod()
{
m_blnInitialized=false;
if(m_objRenderThread!=NULL)
{
if(m_objRenderThread->isRunning())
{
m_objRenderThread->stopRendering();
}
}
//CleanUpDATVFramework(true);
if(m_objRFFilter!=NULL)
{
//delete m_objRFFilter;
}
if(m_objVideoStream!=NULL)
{
//m_objVideoStream->close();
//delete m_objVideoStream;
}
m_deviceAPI->removeChannelAPI(this);
m_deviceAPI->removeThreadedSink(m_threadedChannelizer);
delete m_threadedChannelizer;
delete m_channelizer;
}
bool DATVDemod::SetDATVScreen(DATVScreen *objScreen)
{
m_objRegisteredDATVScreen = objScreen;
}
DATVideostream * DATVDemod::SetVideoRender(DATVideoRender *objScreen)
{
m_objRegisteredVideoRender = objScreen;
m_objRenderThread = new DATVideoRenderThread(m_objRegisteredVideoRender,m_objVideoStream);
return m_objVideoStream;
}
bool DATVDemod::PlayVideo(bool blnStartStop)
{
if(m_objVideoStream==NULL)
{
return false;
}
if(m_objRegisteredVideoRender==NULL)
{
return false;
}
if(m_objRenderThread==NULL)
{
return false;
}
if(m_objRenderThread->isRunning())
{
if(blnStartStop==true)
{
m_objRenderThread->stopRendering();
}
return true;
}
m_objRenderThread->setStreamAndRenderer(m_objRegisteredVideoRender,m_objVideoStream);
m_objVideoStream->MultiThreaded=true;
m_objRenderThread->start();
//m_objVideoStream->MultiThreaded=false;
//m_objRenderThread->run();
return true;
}
void DATVDemod::configure(MessageQueue* objMessageQueue,
int intRFBandwidth,
int intCenterFrequency,
dvb_version enmStandard,
DATVModulation enmModulation,
code_rate enmFEC,
int intSymbolRate,
int intNotchFilters,
bool blnAllowDrift,
bool blnFastLock,
bool blnHDLC,
bool blnHardMetric,
bool blnResample,
bool blnViterbi)
{
Message* msgCmd = MsgConfigureDATVDemod::create(intRFBandwidth,intCenterFrequency,enmStandard, enmModulation, enmFEC, intSymbolRate, intNotchFilters, blnAllowDrift,blnFastLock,blnHDLC,blnHardMetric,blnResample, blnViterbi);
objMessageQueue->push(msgCmd);
}
void DATVDemod::InitDATVParameters(int intMsps,
int intRFBandwidth,
int intCenterFrequency,
dvb_version enmStandard,
DATVModulation enmModulation,
code_rate enmFEC,
int intSampleRate,
int intSymbolRate,
int intNotchFilters,
bool blnAllowDrift,
bool blnFastLock,
bool blnHDLC,
bool blnHardMetric,
bool blnResample,
bool blnViterbi)
{
Real fltLowCut;
Real fltHiCut;
m_blnInitialized=false;
m_objSettingsMutex.lock();
//Recalibrage du filtre passe bande
fltLowCut = -((float)intRFBandwidth / 2.0) / (float)intMsps;
fltHiCut = ((float)intRFBandwidth / 2.0) / (float)intMsps;
m_objRFFilter->create_filter(fltLowCut, fltHiCut);
m_objNCO.setFreq(-(float)intCenterFrequency,(float)intMsps);
//Mise à jour de la config
m_objRunning.intMsps = intMsps;
m_objRunning.intCenterFrequency = intCenterFrequency;
m_objRunning.intRFBandwidth = intRFBandwidth;
m_objRunning.enmStandard = enmStandard;
m_objRunning.enmModulation = enmModulation;
m_objRunning.enmFEC = enmFEC;
m_objRunning.intSampleRate = intSampleRate;
m_objRunning.intSymbolRate = intSymbolRate;
m_objRunning.intNotchFilters = intNotchFilters;
m_objRunning.blnAllowDrift = blnAllowDrift;
m_objRunning.blnFastLock = blnFastLock;
m_objRunning.blnHDLC = blnHDLC;
m_objRunning.blnHardMetric = blnHardMetric;
m_objRunning.blnResample = blnResample;
m_objRunning.blnViterbi = blnViterbi;
qDebug() << "DATVDemod::InitDATVParameters:"
<< " - Msps: " << intMsps
<< " - Sample Rate: " << intSampleRate
<< " - Symbol Rate: " << intSymbolRate
<< " - Modulation: " << enmModulation
<< " - Notch Filters: " << intNotchFilters
<< " - Allow Drift: " << blnAllowDrift
<< " - Fast Lock: " << blnFastLock
<< " - HDLC: " << blnHDLC
<< " - HARD METRIC: " << blnHardMetric
<< " - Resample: " << blnResample
<< " - Viterbi: " << blnViterbi;
m_objSettingsMutex.unlock();
m_blnNeedConfigUpdate=true;
m_blnInitialized=true;
}
void DATVDemod::CleanUpDATVFramework(bool blnRelease)
{
//if(blnRelease==true)
if(false)
{
if(m_objScheduler!=NULL)
{
m_objScheduler->shutdown();
delete m_objScheduler;
}
// INPUT
if(p_rawiq!=NULL) delete p_rawiq;
if(p_rawiq_writer!=NULL) delete p_rawiq_writer;
if(p_preprocessed!=NULL) delete p_preprocessed;
// NOTCH FILTER
if(r_auto_notch!=NULL) delete r_auto_notch;
if(p_autonotched!=NULL) delete p_autonotched;
// FREQUENCY CORRECTION : DEROTATOR
if(p_derot!=NULL) delete p_derot;
if(r_derot!=NULL) delete r_derot;
// CNR ESTIMATION
if(p_cnr!=NULL) delete p_cnr;
if(r_cnr!=NULL) delete r_cnr;
//FILTERING
if(r_resample!=NULL) delete r_resample;
if(p_resampled!=NULL) delete p_resampled;
if(coeffs!=NULL) delete coeffs;
// OUTPUT PREPROCESSED DATA
if(sampler!=NULL) delete sampler;
if(coeffs_sampler!=NULL) delete coeffs_sampler;
if(p_symbols!=NULL) delete p_symbols;
if(p_freq!=NULL) delete p_freq;
if(p_ss!=NULL) delete p_ss;
if(p_mer!=NULL) delete p_mer;
if(p_sampled!=NULL) delete p_sampled;
//DECIMATION
if(p_decimated!=NULL) delete p_decimated;
if(p_decim!=NULL) delete p_decim;
if(r_ppout!=NULL) delete r_ppout;
//GENERIC CONSTELLATION RECEIVER
if(m_objDemodulator!=NULL) delete m_objDemodulator;
//DECONVOLUTION AND SYNCHRONIZATION
if(p_bytes!=NULL) delete p_bytes;
if(r_deconv!=NULL) delete r_deconv;
if(r!=NULL) delete r;
if(p_descrambled!=NULL) delete p_descrambled;
if(p_frames!=NULL) delete p_frames;
if(r_etr192_descrambler!=NULL) delete r_etr192_descrambler;
if(r_sync!=NULL) delete r_sync;
if(p_mpegbytes!=NULL) delete p_mpegbytes;
if(p_lock!=NULL) delete p_lock;
if(p_locktime!=NULL) delete p_locktime;
if(r_sync_mpeg!=NULL) delete r_sync_mpeg;
// DEINTERLEAVING
if(p_rspackets!=NULL) delete p_rspackets;
if(r_deinter!=NULL) delete r_deinter;
if(p_vbitcount!=NULL) delete p_vbitcount;
if(p_verrcount!=NULL) delete p_verrcount;
if(p_rtspackets!=NULL) delete p_rtspackets;
if(r_rsdec!=NULL) delete r_rsdec;
//BER ESTIMATION
if(p_vber!=NULL) delete p_vber;
if(r_vber!=NULL) delete r_vber;
// DERANDOMIZATION
if(p_tspackets!=NULL) delete p_tspackets;
if(r_derand!=NULL) delete r_derand;
//OUTPUT : To remove
if(r_stdout!=NULL) delete r_stdout;
if(r_videoplayer!=NULL) delete r_videoplayer;
//CONSTELLATION
if(r_scope_symbols!=NULL) delete r_scope_symbols;
}
m_objScheduler=NULL;
// INPUT
p_rawiq = NULL;
p_rawiq_writer = NULL;
p_preprocessed = NULL;
// NOTCH FILTER
r_auto_notch = NULL;
p_autonotched = NULL;
// FREQUENCY CORRECTION : DEROTATOR
p_derot = NULL;
r_derot=NULL;
// CNR ESTIMATION
p_cnr = NULL;
r_cnr = NULL;
//FILTERING
r_resample = NULL;
p_resampled = NULL;
coeffs = NULL;
ncoeffs=0;
// OUTPUT PREPROCESSED DATA
sampler = NULL;
coeffs_sampler=NULL;
ncoeffs_sampler=0;
p_symbols = NULL;
p_freq = NULL;
p_ss = NULL;
p_mer = NULL;
p_sampled = NULL;
//DECIMATION
p_decimated = NULL;
p_decim = NULL;
r_ppout = NULL;
//GENERIC CONSTELLATION RECEIVER
m_objDemodulator = NULL;
//DECONVOLUTION AND SYNCHRONIZATION
p_bytes=NULL;
r_deconv=NULL;
r = NULL;
p_descrambled = NULL;
p_frames = NULL;
r_etr192_descrambler = NULL;
r_sync = NULL;
p_mpegbytes = NULL;
p_lock = NULL;
p_locktime = NULL;
r_sync_mpeg = NULL;
// DEINTERLEAVING
p_rspackets = NULL;
r_deinter = NULL;
p_vbitcount = NULL;
p_verrcount = NULL;
p_rtspackets = NULL;
r_rsdec = NULL;
//BER ESTIMATION
p_vber = NULL;
r_vber = NULL;
// DERANDOMIZATION
p_tspackets = NULL;
r_derand = NULL;
//OUTPUT : To remove
r_stdout = NULL;
r_videoplayer = NULL;
//CONSTELLATION
r_scope_symbols = NULL;
}
void DATVDemod::InitDATVFramework()
{
m_blnDVBInitialized=false;
m_lngReadIQ=0;
m_objCfg.standard = m_objRunning.enmStandard;
m_objCfg.fec = m_objRunning.enmFEC;
m_objCfg.Fs = (float) m_objRunning.intSampleRate;
m_objCfg.Fm = (float) m_objRunning.intSymbolRate;
m_objCfg.fastlock = m_objRunning.blnFastLock;
switch(m_objRunning.enmModulation)
{
case BPSK:
m_objCfg.constellation = cstln_lut<256>::BPSK;
break;
case QPSK:
m_objCfg.constellation = cstln_lut<256>::QPSK;
break;
case PSK8:
m_objCfg.constellation = cstln_lut<256>::PSK8;
break;
case APSK16:
m_objCfg.constellation = cstln_lut<256>::APSK16;
break;
case APSK32:
m_objCfg.constellation = cstln_lut<256>::APSK32;
break;
case APSK64E:
m_objCfg.constellation = cstln_lut<256>::APSK64E;
break;
case QAM16:
m_objCfg.constellation = cstln_lut<256>::QAM16;
break;
case QAM64:
m_objCfg.constellation = cstln_lut<256>::QAM64;
break;
case QAM256:
m_objCfg.constellation = cstln_lut<256>::QAM256;
break;
default:
m_objCfg.constellation = cstln_lut<256>::BPSK;
break;
}
m_objCfg.allow_drift = m_objRunning.blnAllowDrift;
m_objCfg.anf = m_objRunning.intNotchFilters;
m_objCfg.hard_metric = m_objRunning.blnHardMetric;
m_objCfg.hdlc = m_objRunning.blnHDLC;
m_objCfg.resample = m_objRunning.blnResample;
m_objCfg.viterbi = m_objRunning.blnViterbi;
// Min buffer size for baseband data
// scopes: 1024
// ss_estimator: 1024
// anf: 4096
// cstln_receiver: reads in chunks of 128+1
BUF_BASEBAND = 4096 * m_objCfg.buf_factor;
// Min buffer size for IQ symbols
// cstln_receiver: writes in chunks of 128/omega symbols (margin 128)
// deconv_sync: reads at least 64+32
// A larger buffer improves performance significantly.
BUF_SYMBOLS = 1024 * m_objCfg.buf_factor;
// Min buffer size for unsynchronized bytes
// deconv_sync: writes 32 bytes
// mpeg_sync: reads up to 204*scan_syncs = 1632 bytes
BUF_BYTES = 2048 * m_objCfg.buf_factor;
// Min buffer size for synchronized (but interleaved) bytes
// mpeg_sync: writes 1 rspacket
// deinterleaver: reads 17*11*12+204 = 2448 bytes
BUF_MPEGBYTES = 2448 * m_objCfg.buf_factor;
// Min buffer size for packets: 1
BUF_PACKETS = m_objCfg.buf_factor;
// Min buffer size for misc measurements: 1
BUF_SLOW = m_objCfg.buf_factor;
m_lngExpectedReadIQ = BUF_BASEBAND;
CleanUpDATVFramework(true);
m_objScheduler = new scheduler();
//***************
p_rawiq = new pipebuf(m_objScheduler, "rawiq", BUF_BASEBAND);
p_rawiq_writer = new pipewriter(*p_rawiq);
p_preprocessed = p_rawiq;
// NOTCH FILTER
if ( m_objCfg.anf )
{
p_autonotched = new pipebuf(m_objScheduler, "autonotched", BUF_BASEBAND);
r_auto_notch = new auto_notch(m_objScheduler, *p_preprocessed, *p_autonotched, m_objCfg.anf, 0);
p_preprocessed = p_autonotched;
}
// FREQUENCY CORRECTION
if ( m_objCfg.Fderot )
{
p_derot = new pipebuf(m_objScheduler, "derotated", BUF_BASEBAND);
r_derot = new rotator(m_objScheduler, *p_preprocessed, *p_derot, -m_objCfg.Fderot/m_objCfg.Fs);
p_preprocessed = p_derot;
}
// CNR ESTIMATION
p_cnr = new pipebuf(m_objScheduler, "cnr", BUF_SLOW);
if ( m_objCfg.cnr )
{
r_cnr = new cnr_fft(m_objScheduler, *p_preprocessed, *p_cnr, m_objCfg.Fm/m_objCfg.Fs);
r_cnr->decimation = decimation(m_objCfg.Fs, 1); // 1 Hz
}
// FILTERING
int decim = 1;
if ( m_objCfg.resample )
{
// Lowpass-filter and decimate.
if ( m_objCfg.decim )
{
decim = m_objCfg.decim;
}
else
{
// Decimate to just above 4 samples per symbol
float target_Fs = m_objCfg.Fm * 4;
decim = m_objCfg.Fs / target_Fs;
if ( decim < 1 )
{
decim = 1;
}
}
float transition = (m_objCfg.Fm/2) * m_objCfg.rolloff;
int order = m_objCfg.resample_rej * m_objCfg.Fs / (22*transition);
order = ((order+1)/2) * 2; // Make even
p_resampled = new pipebuf(m_objScheduler, "resampled", BUF_BASEBAND);
#if 1 // Cut in middle of roll-off region
float Fcut = (m_objCfg.Fm/2) * (1+m_objCfg.rolloff/2) / m_objCfg.Fs;
#else // Cut at beginning of roll-off region
float Fcut = (m_objCfg.Fm/2) / cfg.Fs;
#endif
ncoeffs = filtergen::lowpass(order, Fcut, &coeffs);
filtergen::normalize_dcgain(ncoeffs, coeffs, 1);
r_resample = new fir_filter(m_objScheduler, ncoeffs, coeffs, *p_preprocessed, *p_resampled, decim);
p_preprocessed = p_resampled;
m_objCfg.Fs /= decim;
}
// DECIMATION
// (Unless already done in resampler)
if ( !m_objCfg.resample && m_objCfg.decim>1 )
{
decim = m_objCfg.decim;
p_decimated = new pipebuf(m_objScheduler, "decimated", BUF_BASEBAND);
p_decim = new decimator(m_objScheduler, decim, *p_preprocessed, *p_decimated);
p_preprocessed = p_decimated;
m_objCfg.Fs /= decim;
}
//Resampling FS
// Generic constellation receiver
p_symbols = new pipebuf(m_objScheduler, "PSK soft-symbols", BUF_SYMBOLS);
p_freq = new pipebuf (m_objScheduler, "freq", BUF_SLOW);
p_ss = new pipebuf (m_objScheduler, "SS", BUF_SLOW);
p_mer = new pipebuf (m_objScheduler, "MER", BUF_SLOW);
p_sampled = new pipebuf (m_objScheduler, "PSK symbols", BUF_BASEBAND);
switch ( m_objCfg.sampler )
{
case SAMP_NEAREST:
sampler = new nearest_sampler();
break;
case SAMP_LINEAR:
sampler = new linear_sampler();
break;
case SAMP_RRC:
{
if ( m_objCfg.rrc_steps == 0 )
{
// At least 64 discrete sampling points between symbols
m_objCfg.rrc_steps = max(1, (int)(64*m_objCfg.Fm / m_objCfg.Fs));
}
float Frrc = m_objCfg.Fs * m_objCfg.rrc_steps; // Sample freq of the RRC filter
float transition = (m_objCfg.Fm/2) * m_objCfg.rolloff;
int order = m_objCfg.rrc_rej * Frrc / (22*transition);
ncoeffs_sampler = filtergen::root_raised_cosine(order, m_objCfg.Fm/Frrc, m_objCfg.rolloff, &coeffs_sampler);
sampler = new fir_sampler(ncoeffs_sampler, coeffs_sampler, m_objCfg.rrc_steps);
break;
}
default:
fatal("Interpolator not implemented");
}
m_objDemodulator = new cstln_receiver(m_objScheduler, sampler, *p_preprocessed, *p_symbols, p_freq, p_ss, p_mer, p_sampled);
if ( m_objCfg.standard == DVB_S )
{
if ( m_objCfg.constellation != cstln_lut<256>::QPSK && m_objCfg.constellation != cstln_lut<256>::BPSK )
{
fprintf(stderr, "Warning: non-standard constellation for DVB-S\n");
}
}
if ( m_objCfg.standard == DVB_S2 )
{
// For DVB-S2 testing only.
// Constellation should be determined from PL signalling.
fprintf(stderr, "DVB-S2: Testing symbol sampler only.\n");
}
m_objDemodulator->cstln = make_dvbs2_constellation(m_objCfg.constellation, m_objCfg.fec);
if ( m_objCfg.hard_metric )
{
m_objDemodulator->cstln->harden();
}
m_objDemodulator->set_omega(m_objCfg.Fs/m_objCfg.Fm);
if ( m_objCfg.Ftune )
{
m_objDemodulator->set_freq(m_objCfg.Ftune/m_objCfg.Fs);
}
if ( m_objCfg.allow_drift )
{
m_objDemodulator->set_allow_drift(true);
}
if ( m_objCfg.viterbi )
{
m_objDemodulator->pll_adjustment /= 6;
}
m_objDemodulator->meas_decimation = decimation(m_objCfg.Fs, m_objCfg.Finfo);
// TRACKING FILTERS
if ( r_resample )
{
r_resample->freq_tap = &m_objDemodulator->freq_tap;
r_resample->tap_multiplier = 1.0 / decim;
r_resample->freq_tol = m_objCfg.Fm/(m_objCfg.Fs*decim) * 0.1;
}
if ( r_cnr )
{
r_cnr->freq_tap = &m_objDemodulator->freq_tap;
r_cnr->tap_multiplier = 1.0 / decim;
}
//constellation
m_objRegisteredDATVScreen->resizeDATVScreen(256,256);
r_scope_symbols = new datvconstellation(m_objScheduler, *p_sampled, -128,128, NULL, m_objRegisteredDATVScreen);
r_scope_symbols->decimation = 1;
r_scope_symbols->cstln = &m_objDemodulator->cstln;
// DECONVOLUTION AND SYNCHRONIZATION
p_bytes = new pipebuf(m_objScheduler, "bytes", BUF_BYTES);
r_deconv = NULL;
if ( m_objCfg.viterbi )
{
if ( m_objCfg.fec==FEC23 && (m_objDemodulator->cstln->nsymbols==4 || m_objDemodulator->cstln->nsymbols==64) )
{
m_objCfg.fec = FEC46;
}
//To uncomment -> Linking Problem : undefined symbol: _ZN7leansdr21viterbi_dec_interfaceIhhiiE6updateEPiS2_
r = new viterbi_sync(m_objScheduler, (*p_symbols), (*p_bytes), m_objDemodulator->cstln, m_objCfg.fec);
if ( m_objCfg.fastlock )
{
r->resync_period = 1;
}
}
else
{
r_deconv = make_deconvol_sync_simple(m_objScheduler, (*p_symbols), (*p_bytes), m_objCfg.fec);
r_deconv->fastlock = m_objCfg.fastlock;
}
if ( m_objCfg.hdlc )
{
p_descrambled = new pipebuf(m_objScheduler, "descrambled", BUF_MPEGBYTES);
r_etr192_descrambler = new etr192_descrambler(m_objScheduler, (*p_bytes), *p_descrambled);
p_frames = new pipebuf(m_objScheduler, "frames", BUF_MPEGBYTES);
r_sync = new hdlc_sync(m_objScheduler, *p_descrambled, *p_frames, 2, 278);
if ( m_objCfg.fastlock )
{
r_sync->resync_period = 1;
}
if ( m_objCfg.packetized )
{
r_sync->header16 = true;
}
}
p_mpegbytes = new pipebuf (m_objScheduler, "mpegbytes", BUF_MPEGBYTES);
p_lock = new pipebuf (m_objScheduler, "lock", BUF_SLOW);
p_locktime = new pipebuf (m_objScheduler, "locktime", BUF_PACKETS);
if ( ! m_objCfg.hdlc )
{
r_sync_mpeg = new mpeg_sync(m_objScheduler, *p_bytes, *p_mpegbytes, r_deconv, p_lock, p_locktime);
r_sync_mpeg->fastlock = m_objCfg.fastlock;
}
// DEINTERLEAVING
p_rspackets = new pipebuf< rspacket >(m_objScheduler, "RS-enc packets", BUF_PACKETS);
r_deinter = new deinterleaver(m_objScheduler, *p_mpegbytes, *p_rspackets);
// REED-SOLOMON
p_vbitcount = new pipebuf(m_objScheduler, "Bits processed", BUF_PACKETS);
p_verrcount = new pipebuf(m_objScheduler, "Bits corrected", BUF_PACKETS);
p_rtspackets = new pipebuf(m_objScheduler, "rand TS packets", BUF_PACKETS);
r_rsdec = new rs_decoder (m_objScheduler, *p_rspackets, *p_rtspackets, p_vbitcount, p_verrcount);
// BER ESTIMATION
p_vber = new pipebuf (m_objScheduler, "VBER", BUF_SLOW);
r_vber = new rate_estimator (m_objScheduler, *p_verrcount, *p_vbitcount, *p_vber);
r_vber->sample_size = m_objCfg.Fm/2; // About twice per second, depending on CR
// Require resolution better than 2E-5
if ( r_vber->sample_size < 50000 )
{
r_vber->sample_size = 50000;
}
// DERANDOMIZATION
p_tspackets = new pipebuf(m_objScheduler, "TS packets", BUF_PACKETS);
r_derand = new derandomizer(m_objScheduler, *p_rtspackets, *p_tspackets);
// OUTPUT
r_videoplayer = new datvvideoplayer(m_objScheduler, *p_tspackets,m_objVideoStream);
m_blnDVBInitialized=true;
}
void DATVDemod::feed(const SampleVector::const_iterator& begin, const SampleVector::const_iterator& end, bool firstOfBurst)
{
qint16 * ptrBufferToRelease=NULL;
float fltI;
float fltQ;
cf32 objIQ;
//Complex objC;
fftfilt::cmplx *objRF;
int intRFOut;
#ifdef EXTENDED_DIRECT_SAMPLE
qint16 * ptrBuffer;
qint32 intLen;
//********** Reading direct samples **********
SampleVector::const_iterator it = begin;
intLen = it->intLen;
ptrBuffer = it->ptrBuffer;
ptrBufferToRelease = ptrBuffer;
++it;
for(qint32 intInd=0; intIndreal();
fltQ = it->imag();
#endif
//********** demodulation **********
if((m_blnDVBInitialized==false) || (m_blnNeedConfigUpdate==true))
{
m_blnNeedConfigUpdate=false;
InitDATVFramework();
}
//********** iq stream ****************
if(m_lngReadIQ>p_rawiq_writer->writable())
{
m_objScheduler->step();
m_objRegisteredDATVScreen->renderImage(NULL);
m_lngReadIQ=0;
p_rawiq_writer = new pipewriter(*p_rawiq);
}
if(false)
{
objIQ.re = fltI;
objIQ.im = fltQ;
p_rawiq_writer->write(objIQ);
m_lngReadIQ++;
}
else
{
Complex objC(fltI,fltQ);
objC *= m_objNCO.nextIQ();
intRFOut = m_objRFFilter->runFilt(objC, &objRF); // filter RF before demod
for (int intI = 0 ; intI < intRFOut; intI++)
{
objIQ.re = objRF->real();
objIQ.im = objRF->imag();
p_rawiq_writer->write(objIQ);
objRF ++;
m_lngReadIQ++;
}
}
//********** demodulation **********
}
if(ptrBufferToRelease!=NULL)
{
delete ptrBufferToRelease;
}
//m_objSettingsMutex.unlock();
}
void DATVDemod::start()
{
//m_objTimer.start();
}
void DATVDemod::stop()
{
}
bool DATVDemod::handleMessage(const Message& cmd)
{
qDebug() << "DATVDemod::handleMessage";
if (DownChannelizer::MsgChannelizerNotification::match(cmd))
{
DownChannelizer::MsgChannelizerNotification& objNotif = (DownChannelizer::MsgChannelizerNotification&) cmd;
if(m_objRunning.intMsps!=objNotif.getSampleRate())
{
m_objRunning.intMsps = objNotif.getSampleRate();
m_objRunning.intSampleRate = m_objRunning.intMsps;
printf("Sample Rate: %d\r\n",m_objRunning.intSampleRate );
ApplySettings();
}
qDebug() << "DATVDemod::handleMessage: MsgChannelizerNotification:"
<< " intMsps: " << m_objRunning.intMsps;
return true;
}
else if (MsgConfigureChannelizer::match(cmd))
{
MsgConfigureChannelizer& cfg = (MsgConfigureChannelizer&) cmd;
m_channelizer->configure(m_channelizer->getInputMessageQueue(),
m_channelizer->getInputSampleRate(),
m_objRunning.intCenterFrequency);
qDebug() << "ATVDemod::handleMessage: MsgConfigureChannelizer: sampleRate: " << m_channelizer->getInputSampleRate()
<< " centerFrequency: " << m_objRunning.intCenterFrequency;
return true;
}
else if (MsgConfigureDATVDemod::match(cmd))
{
MsgConfigureDATVDemod& objCfg = (MsgConfigureDATVDemod&) cmd;
if((objCfg.m_objMsgConfig.blnAllowDrift != m_objRunning.blnAllowDrift)
|| (objCfg.m_objMsgConfig.intRFBandwidth != m_objRunning.intRFBandwidth)
|| (objCfg.m_objMsgConfig.intCenterFrequency != m_objRunning.intCenterFrequency)
|| (objCfg.m_objMsgConfig.blnFastLock != m_objRunning.blnFastLock)
|| (objCfg.m_objMsgConfig.blnHardMetric != m_objRunning.blnHardMetric)
|| (objCfg.m_objMsgConfig.blnHDLC != m_objRunning.blnHDLC)
|| (objCfg.m_objMsgConfig.blnResample != m_objRunning.blnResample)
|| (objCfg.m_objMsgConfig.blnViterbi != m_objRunning.blnViterbi)
|| (objCfg.m_objMsgConfig.enmFEC != m_objRunning.enmFEC)
|| (objCfg.m_objMsgConfig.enmModulation != m_objRunning.enmModulation)
|| (objCfg.m_objMsgConfig.enmStandard != m_objRunning.enmStandard)
|| (objCfg.m_objMsgConfig.intNotchFilters != m_objRunning.intNotchFilters)
|| (objCfg.m_objMsgConfig.intSymbolRate != m_objRunning.intSymbolRate))
{
m_objRunning.blnAllowDrift = objCfg.m_objMsgConfig.blnAllowDrift;
m_objRunning.blnFastLock = objCfg.m_objMsgConfig.blnFastLock;
m_objRunning.blnHardMetric = objCfg.m_objMsgConfig.blnHardMetric;
m_objRunning.blnHDLC = objCfg.m_objMsgConfig.blnHDLC;
m_objRunning.blnResample = objCfg.m_objMsgConfig.blnResample;
m_objRunning.blnViterbi = objCfg.m_objMsgConfig.blnViterbi;
m_objRunning.enmFEC = objCfg.m_objMsgConfig.enmFEC;
m_objRunning.enmModulation = objCfg.m_objMsgConfig.enmModulation;
m_objRunning.enmStandard = objCfg.m_objMsgConfig.enmStandard;
m_objRunning.intNotchFilters = objCfg.m_objMsgConfig.intNotchFilters;
m_objRunning.intSymbolRate = objCfg.m_objMsgConfig.intSymbolRate;
m_objRunning.intRFBandwidth = objCfg.m_objMsgConfig.intRFBandwidth;
m_objRunning.intCenterFrequency = objCfg.m_objMsgConfig.intCenterFrequency;
ApplySettings();
}
return true;
}
else
{
return false;
}
}
void DATVDemod::ApplySettings()
{
if(m_objRunning.intMsps==0)
{
return;
}
//m_objSettingsMutex.lock();
InitDATVParameters(m_objRunning.intMsps,
m_objRunning.intRFBandwidth,
m_objRunning.intCenterFrequency,
m_objRunning.enmStandard,
m_objRunning.enmModulation,
m_objRunning.enmFEC,
m_objRunning.intSampleRate,
m_objRunning.intSymbolRate,
m_objRunning.intNotchFilters,
m_objRunning.blnAllowDrift,
m_objRunning.blnFastLock,
m_objRunning.blnHDLC,
m_objRunning.blnHardMetric,
m_objRunning.blnResample,
m_objRunning.blnViterbi);
}
int DATVDemod::GetSampleRate()
{
return m_objRunning.intMsps;
}