WSJT-X/Detector/Detector.cpp
Bill Somerville 542ffe8311
Improve audio device handling and error recovery
where possible  audio devices that  disappear are not  forgotten until
the user selects another device, this should allow temporarily missing
devices or forgetting  to switch on devices before  starting WSJT-X to
be  handled more  cleanly. If  all else  fails, visiting  the Settings
dialog and  clicking OK should  get things  going again. Note  that we
still  do not  have  a  reliable way  of  detecting  failed audio  out
devices, in that  case selecting another device and  then returning to
the original should work.

Enumerating  audio devices  is expensive  and on  Linux may  take many
seconds per  device. To avoid  lengthy blocking behaviour until  it is
absolutely necessary,  audio devices are  not enumerated until  one of
the "Settings->Audio" device drop-down lists is opened. Elsewhere when
devices  must be  discovered  the  enumeration stops  as  soon as  the
configured device is  discovered. A status bar message  is posted when
audio devices are being enumerated as a reminder that the UI may block
while this is happening.

The message box warning about  unaccounted-for input audio samples now
only triggers when  >5 seconds of audio appears to  be missing or over
provided. Hopefully this will make the warning less annoying for those
that are  using audio sources  with high and/or variable  latencies. A
status  bar message  is still  posted for  any amount  of audio  input
samples  unaccounted for  >1/5 second,  this message  appearing a  lot
should be considered as notification that  there is a problem with the
audio sub-system, system load is  too high, or time synchronization is
stepping the PC clock rather  than adjusting the frequency to maintain
monotonic clock ticks.
2020-09-20 18:20:16 +01:00

126 lines
4.5 KiB
C++

#include "Detector.hpp"
#include <QDateTime>
#include <QtAlgorithms>
#include <QDebug>
#include <math.h>
#include "commons.h"
#include "moc_Detector.cpp"
extern "C" {
void fil4_(qint16*, qint32*, qint16*, qint32*);
}
extern dec_data_t dec_data;
Detector::Detector (unsigned frameRate, double periodLengthInSeconds,
unsigned downSampleFactor, QObject * parent)
: AudioDevice (parent)
, m_frameRate (frameRate)
, m_period (periodLengthInSeconds)
, m_downSampleFactor (downSampleFactor)
, m_samplesPerFFT {max_buffer_size}
, m_buffer ((downSampleFactor > 1) ?
new short [max_buffer_size * downSampleFactor] : nullptr)
, m_bufferPos (0)
{
(void)m_frameRate; // quell compiler warning
clear ();
}
void Detector::setBlockSize (unsigned n)
{
m_samplesPerFFT = n;
}
bool Detector::reset ()
{
clear ();
// don't call base class reset because it calls seek(0) which causes
// a warning
return isOpen ();
}
void Detector::clear ()
{
// set index to roughly where we are in time (1ms resolution)
// qint64 now (QDateTime::currentMSecsSinceEpoch ());
// unsigned msInPeriod ((now % 86400000LL) % (m_period * 1000));
// dec_data.params.kin = qMin ((msInPeriod * m_frameRate) / 1000, static_cast<unsigned> (sizeof (dec_data.d2) / sizeof (dec_data.d2[0])));
dec_data.params.kin = 0;
m_bufferPos = 0;
// fill buffer with zeros (G4WJS commented out because it might cause decoder hangs)
// qFill (dec_data.d2, dec_data.d2 + sizeof (dec_data.d2) / sizeof (dec_data.d2[0]), 0);
}
qint64 Detector::writeData (char const * data, qint64 maxSize)
{
static unsigned mstr0=999999;
qint64 ms0 = QDateTime::currentMSecsSinceEpoch() % 86400000;
unsigned mstr = ms0 % int(1000.0*m_period); // ms into the nominal Tx start time
if(mstr < mstr0) { //When mstr has wrapped around to 0, restart the buffer
dec_data.params.kin = 0;
m_bufferPos = 0;
}
mstr0=mstr;
// no torn frames
Q_ASSERT (!(maxSize % static_cast<qint64> (bytesPerFrame ())));
// these are in terms of input frames (not down sampled)
size_t framesAcceptable ((sizeof (dec_data.d2) /
sizeof (dec_data.d2[0]) - dec_data.params.kin) * m_downSampleFactor);
size_t framesAccepted (qMin (static_cast<size_t> (maxSize /
bytesPerFrame ()), framesAcceptable));
if (framesAccepted < static_cast<size_t> (maxSize / bytesPerFrame ())) {
qDebug () << "dropped " << maxSize / bytesPerFrame () - framesAccepted
<< " frames of data on the floor!"
<< dec_data.params.kin << mstr;
}
for (unsigned remaining = framesAccepted; remaining; ) {
size_t numFramesProcessed (qMin (m_samplesPerFFT *
m_downSampleFactor - m_bufferPos, remaining));
if(m_downSampleFactor > 1) {
store (&data[(framesAccepted - remaining) * bytesPerFrame ()],
numFramesProcessed, &m_buffer[m_bufferPos]);
m_bufferPos += numFramesProcessed;
if(m_bufferPos==m_samplesPerFFT*m_downSampleFactor) {
qint32 framesToProcess (m_samplesPerFFT * m_downSampleFactor);
qint32 framesAfterDownSample (m_samplesPerFFT);
if(m_downSampleFactor > 1 && dec_data.params.kin>=0 &&
dec_data.params.kin < (NTMAX*12000 - framesAfterDownSample)) {
fil4_(&m_buffer[0], &framesToProcess, &dec_data.d2[dec_data.params.kin],
&framesAfterDownSample);
dec_data.params.kin += framesAfterDownSample;
} else {
// qDebug() << "framesToProcess = " << framesToProcess;
// qDebug() << "dec_data.params.kin = " << dec_data.params.kin;
// qDebug() << "secondInPeriod = " << secondInPeriod();
// qDebug() << "framesAfterDownSample" << framesAfterDownSample;
}
Q_EMIT framesWritten (dec_data.params.kin);
m_bufferPos = 0;
}
} else {
store (&data[(framesAccepted - remaining) * bytesPerFrame ()],
numFramesProcessed, &dec_data.d2[dec_data.params.kin]);
m_bufferPos += numFramesProcessed;
dec_data.params.kin += numFramesProcessed;
if (m_bufferPos == static_cast<unsigned> (m_samplesPerFFT)) {
Q_EMIT framesWritten (dec_data.params.kin);
m_bufferPos = 0;
}
}
remaining -= numFramesProcessed;
}
// we drop any data past the end of the buffer on the floor until
// the next period starts
return maxSize;
}