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floatValue = su::convertStringToType<float>(m_rtcKeywords["RTCTTCAMTINT"]);
fits_write_key(fptr, TFLOAT, "RTCTTCAMTINT", &floatValue, "TipTilt Camera integration time", &FitStatus);
// if(m_pGetRtcStatus){ intValue = su::convertStringToType<int>(m_pGetRtcStatus("TTLOOPENABLED"));}
intValue = su::convertStringToType<int>(m_rtcKeywords["TTLOOPENABLED"]);
fits_write_key(fptr, TLOGICAL,"RTCTTLOOPENABLED", &intValue, "Flag indicating fast tip/tilt loop status", &FitStatus);
// fits_write_key(fptr, TLOGICAL,"RTCTTHISTORYENABLED", &intValue, "Number of images save", &FitStatus);
// fits_write_key(fptr, TSTRING, "TTTIMEHISTORYFILE", (char *)"", "Time History Filename", &FitStatus);
// fits_write_key(fptr, TINT, "TTTIMEHISTLEN", &intValue, "Number of history lines if history is enabled", &FitStatus);
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTDMMAXPOWER"]);
fits_write_key(fptr, TFLOAT, "TTDMMAXPOWER", &floatValue, "Max Power allowed to DM", &FitStatus);
fits_write_key(fptr, TSTRING, "TTBIASFILE", su::get_char_star(m_rtcKeywords["TTBIASFILE"]), "Bias File", &FitStatus);
fits_write_key(fptr, TSTRING, "TTDMFLATFILE", su::get_char_star(m_rtcKeywords["TTDMFLATFILE"]), "Flat File", &FitStatus);
if(m_pGetRtcStatus){m_rtcKeywords["TTSENSORTEMP"] = m_pGetRtcStatus("TTSENSORTEMP");}
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTSENSORTEMP"]);
fits_write_key(fptr, TFLOAT, "TTSENSORTEMP", &floatValue, "sensor temperature in degree C", &FitStatus);
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTCENTROIDGAINX"]);
fits_write_key(fptr, TFLOAT, "TTCENTROIDGAINX", &floatValue, "TipTilt gain on centroid X", &FitStatus);
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTCENTROIDGAINY"]);
fits_write_key(fptr, TFLOAT, "TTCENTROIDGAINY", &floatValue, "TipTilt gain on centroid Y", &FitStatus);
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTCENTROIDORIGX"]);
fits_write_key(fptr, TFLOAT, "TTCENTROIDORIGX", &floatValue, "X Origin position in [-1,1] coordinates", &FitStatus);
floatValue = su::convertStringToType<float>(m_rtcKeywords["TTCENTROIDORIGY"]);
fits_write_key(fptr, TFLOAT, "TTCENTROIDORIGY", &floatValue, "Y Origin position in [-1,1] coordinates", &FitStatus);
intValue = su::convertStringToType<int>(m_rtcKeywords["TDMMODESNUM"]);
fits_write_key(fptr, TINT, "TTDMMODESNUM", &intValue, "number of modes in zonal influence matrix", &FitStatus);
fits_write_key(fptr, TSTRING, "TTPIXELGAINFILE", su::get_char_star(m_rtcKeywords["TTPIXELGAINFILE"]), "Gain factor for each pixel in which the centroid is calculated", &FitStatus);
intValue = su::convertStringToType<int>(m_rtcKeywords["RTCTTPIXELENABLED"]);
fits_write_key(fptr, TLOGICAL,"RTCTTPIXELENABLED", &intValue, "Enable saving frames on memory", &FitStatus);
intValue = su::convertStringToType<int>(m_rtcKeywords["RTCTTPIXELDCIMATION"]);
fits_write_key(fptr, TINT, "RTCTTPIXELDECIMATION", &intValue, "Frame saving decimation factor", &FitStatus);
intValue = su::convertStringToType<int>(m_rtcKeywords["RTCTTDIAGENABLED"]);
fits_write_key(fptr, TLOGICAL,"RTCTTDIAGENABLED", &intValue, "Diagnostic enabled", &FitStatus);
intValue = su::convertStringToType<int>(m_rtcKeywords["RTCTTDIAGDECIMATION"]);
fits_write_key(fptr, TINT, "RTCTTDIAGDECIMATION", &intValue, "TipTilt diagnostic decimation factor", &FitStatus);
fits_write_record(fptr, " ------------------------------------------------------------------------", &FitStatus);
int WCSAXES = 2;
fits_write_key(fptr, TINT, "WCSAXES ", &WCSAXES, "Dimensionality of WCS: 2 for image, 3 for spectrum", &FitStatus);
if(WCSAXES == 2)
fits_write_key(fptr, TSTRING, "CTYPE1 ", (char *)"RA---TAN", "Pixel coordinate system", &FitStatus);
fits_write_key(fptr, TSTRING, "CTYPE2 ", (char *)"DEC--TAN", "Pixel coordinate system", &FitStatus);
fits_write_key(fptr, TSTRING, "RADESYS ", (char *)"ICRS", "reference system", &FitStatus);
fits_write_key(fptr, TSTRING, "CUNIT1 ", (char *)"deg", "Unit of coordinate transformation", &FitStatus);
fits_write_key(fptr, TSTRING, "CUNIT2 ", (char *)"deg", "Unit of coordinate transformation", &FitStatus);
floatValue2 = 0.0000040277777777777;
fits_write_key(fptr, TFLOAT, "CDELT1 ", &floatValue2,"Increment along axis 1 as [CUNIT1]/pxl", &FitStatus);
fits_write_key(fptr, TFLOAT, "CDELT2 ", &floatValue2,"Increment along axis 2 as [CUNIT2]/pxl", &FitStatus);
float ra_tel_deg = tenv.achieved_ra/suc::DEGREE, ra_point_offset = 0.f, ra_guide_offset = 0.f, ra_shark = 0.f;
float dec_tel_deg = tenv.achieved_dec/suc::DEGREE, dec_point_offset = 0.f, dec_guide_offset = 0.f, dec_shark = 0.f;
floatValue = ra_tel_deg + ra_point_offset + ra_guide_offset + ra_shark;
fits_write_key(fptr, TFLOAT, "CRVAL1 ", &floatValue, "RA at CRPIX1 in units CUNIT1", &FitStatus);
floatValue = dec_tel_deg + dec_point_offset + dec_guide_offset + dec_shark;
fits_write_key(fptr, TFLOAT, "CRVAL2 ", &floatValue, "DEC at CRPIX2 in units CUNIT2", &FitStatus);
floatValue = 58.1f + 885.f - xmin;
fits_write_key(fptr, TFLOAT, "CRPIX1 ", &floatValue, "Value of X Ref. pixel", &FitStatus);
floatValue = 51.5f + 1020.f - ymin;
fits_write_key(fptr, TFLOAT, "CRPIX2 ", &floatValue, "Value of Y Ref. pixel", &FitStatus);
double sign = (m_bTest01 ? 1. : -1.);
floatValue = std::cos((ih.derotator.position1 - gDrotRef + sign*tenv.parallactic_angle)*suc::DEGREE);
fits_write_key(fptr, TFLOAT, "PC1_1 ", &floatValue, "Scale in [CUNIT1]/pixel", &FitStatus);
int flip = -1;
floatValue *= flip;
fits_write_key(fptr, TFLOAT, "PC2_2 ", &floatValue, "Scale in [CUNIT2]/pixel", &FitStatus);
floatValue = std::sin((ih.derotator.position1 - gDrotRef + sign*tenv.parallactic_angle)*suc::DEGREE);
fits_write_key(fptr, TFLOAT, "PC1_2 ", &floatValue, "Rotation and skew", &FitStatus);
fits_write_key(fptr, TFLOAT, "PC2_1 ", &floatValue, "Rotation and skew", &FitStatus);
{
fits_write_key(fptr, TSTRING, "CTYPE1 ", (char *)"WAVE", "Pixel coordinate system", &FitStatus);
fits_write_key(fptr, TSTRING, "CTYPE2 ", strValue, "Pixel coordinate system", &FitStatus);
fits_write_key(fptr, TSTRING, "CTYPE3 ", strValue, "Pixel coordinate system", &FitStatus);
fits_write_key(fptr, TSTRING, "CUNIT1 ", strValue, "Unit of coordinate transformation", &FitStatus);
fits_write_key(fptr, TSTRING, "CUNIT2 ", strValue, "Unit of coordinate transformation", &FitStatus);
fits_write_key(fptr, TSTRING, "CUNIT3 ", strValue, "Unit of coordinate transformation", &FitStatus);
fits_write_key(fptr, TFLOAT, "CRVAL1 ", &floatValue, "Wavelength at CRPIX1", &FitStatus);
fits_write_key(fptr, TFLOAT, "CRVAL2 ", &floatValue, "RA at CRPIX1 in units CUNIT1", &FitStatus);
fits_write_key(fptr, TFLOAT, "CRVAL3 ", &floatValue, "DEC at CRPIX2 in units CUNIT2", &FitStatus);
fits_write_key(fptr, TFLOAT, "CD1_1 ", &floatValue, "Increment for CTYPE1", &FitStatus);
fits_write_key(fptr, TFLOAT, "CD2_2 ", &floatValue, "Increment for CTYPE2", &FitStatus);
fits_write_key(fptr, TFLOAT, "CD3_3 ", &floatValue, "Increment for CTYPE3", &FitStatus);
fits_write_key(fptr, TINT, "DISPAXIS ", &intValue, "Dispersion axis (1=rows; 2=columns)", &FitStatus);
fits_write_key(fptr, TSTRING, "DISPUNIT ", strValue, "Units for coordinate along DISPAXIS", &FitStatus);
fits_write_key(fptr, TSTRING, "DISPWC ", strValue, "Approximate central dispersion coordinate on detector [DISPAXIS]", &FitStatus);
fits_write_key(fptr, TSTRING, "DISPDW ", strValue, "Approximate central dispersion per pixel on the detector", &FitStatus);
}
// TODO : Table 15 Enclosure, environment, and weather specific keywords
fits_write_record(fptr, " ------------------------------------------------------------------------", &FitStatus);
fits_write_key(fptr, TFLOAT, "DOMEPAN ", &floatValue, "Dome position angle [degrees E of N]", &FitStatus);
fits_write_key(fptr, TFLOAT, "DOMTEM ", &floatValue, "Dome temperature [degrees C]", &FitStatus);
fits_write_key(fptr, TFLOAT, "DOMHUM ", &floatValue, "Dome relative humidity [%]", &FitStatus);
fits_write_key(fptr, TFLOAT, "DOMDEWPT ", &floatValue, "Dome dew point [degrees C]", &FitStatus);
fits_write_record(fptr, " ------------------------------------------------------------------------", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVTEM ", &tenv.smt_temp, "Outside temperature, C, at MJD-OBS", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVPRE ", &tenv.smt_pressure, "Atmospheric pressure [mbar]", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVWIN ", &tenv.smt_wind_speed, "Outside wind speed (m/s) at MJD-OBS", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVDIR ", &tenv.smt_wind_dir, "(degrees) Direction of wind: E from N", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVHUM ", &tenv.smt_humidity, "Outside relative humidity % at MJD-OBS", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVDEWPT ", &tenv.smt_dewpoint, "Outside dew point (degrees C) at MJD-OBS", &FitStatus);
fits_write_key(fptr, TFLOAT, "ENVTAU ", &tenv.smt_tau, "Opacity at 225 GHz, from SMT", &FitStatus);
fits_write_key(fptr, TSTRING, "WEATHER ", su::get_char_star(operator_comment), "Comment by telescope operator or observer", &FitStatus);
fits_write_key(fptr, TFLOAT, "SEEING ", &tenv.dimm_seeing, "Seeing estimate from S-H WFS", &FitStatus);
fits_write_key(fptr, TFLOAT, "SEEWAV ", &floatValue, "Wavelength for seeing estimate", &FitStatus);
fits_write_key(fptr, TFLOAT, "SEECAL ", &floatValue, "Seeing: S-H to seeing calibration curve", &FitStatus);
U8_LLOG("");
return FitStatus;
}
void SeqDataMgr::getTelescopeEnv(STelescopeEnv & env)
{
// DIMMFWHM DIMM seeing, [arcsecs] DIMMSeeing (DIMMSeeingZenith, DIMMSeeingElevation)
// DIMMFLUX DIMM mean centroid flux DIMMMeanFlux
// LBTWLINK Weather Station Link State LBTWeatherAlive (LBTWeatherAliveFront)
// LBTPRES Ambient Pressure [hPa] LBTPressure
// LBTTEMP Ambient Temperature [deg C] LBTTemp
// LBTHUM LBT Relative Humidity [percent] LBTHumidity
// LBTDWPT LBT Dew Point [deg C] LBTDewPoint
static Nice::Date lastCall;
Nice::Date currentCall = Nice::Date::now();
if(currentCall - lastCall < Nice::Time::seconds(5))return;
lbto::result res;
lbto::DDstruct ddt;
lbto::SeqDD dd;
ddt.DDname = "DIMMSeeing";
dd.push_back(ddt);
ddt.DDname = "DIMMMeanFlux";
dd.push_back(ddt);
ddt.DDname = "LBTWeatherAlive";
dd.push_back(ddt);
ddt.DDname = "LBTPressure";
dd.push_back(ddt);
ddt.DDname = "LBTTemp";
dd.push_back(ddt);
ddt.DDname = "LBTHumidity";
dd.push_back(ddt);
ddt.DDname = "LBTDewPoint";
dd.push_back(ddt);
ddt.DDname = "ELPosition";
dd.push_back(ddt);
ddt.DDname = "AZPosition";
dd.push_back(ddt);
ddt.DDname = "SMTDewPoint";
dd.push_back(ddt);
ddt.DDname = "SMTHumidity";
dd.push_back(ddt);
ddt.DDname = "SMTPressure";
dd.push_back(ddt);
ddt.DDname = "SMTWindSpeed";
dd.push_back(ddt);
ddt.DDname = "SMTWindDir";
dd.push_back(ddt);
ddt.DDname = "SMTTau";
dd.push_back(ddt);
ddt.DDname = "L_AOOffsetX";
dd.push_back(ddt);
ddt.DDname = "L_AOOffsetY";
dd.push_back(ddt);
ddt.DDname = "L_AOOffsetZ";
dd.push_back(ddt);
ddt.DDname = "L_DECOffset";
dd.push_back(ddt);
ddt.DDname = "L_RAOffset";
dd.push_back(ddt);
ddt.DDname = "L_TargetRA";
dd.push_back(ddt);
ddt.DDname = "L_TargetDEC";
dd.push_back(ddt);
ddt.DDname = "L_AchievedRA";
dd.push_back(ddt);
ddt.DDname = "L_AchievedDEC";
dd.push_back(ddt);
ddt.DDname = "ParAngle";
dd.push_back(ddt);
ddt.DDname = "L_AchievedALT";
dd.push_back(ddt);
ddt.DDname = "L_AchievedAZ";
dd.push_back(ddt);
bool get_parameters = true;
int retry_counter = 0;
while(get_parameters)
{
get_parameters = false;
try
{
res = m_iif->iifGetParameter(dd);
}
catch(Basda::ServiceIsBusyException)
{
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{
W_LLOG("Busy : retrying " << retry_counter);
}
retry_counter++;
get_parameters = true;
usleep(50000);
continue;
}
catch(const std::exception& e)
{
W_LLOG(e.what());
return;
}
catch(...)
{
std::string what = boost::current_exception_diagnostic_information();
std::string toErase = "std::exception::what :";
size_t pos = what.find(toErase);
if(pos != std::string::npos)what.erase(pos, toErase.length());
what.erase(std::remove(what.begin(), what.end(), '\n'), what.end());
std::stringstream log_msg;
log_msg << "Error trying getting DD parmateres : " << what;
W_LLOG(log_msg.str());
return;
}
}
if(res.rescode == EXIT_SUCCESS)
{
double temp;
// std::vector<std::string>::const_iterator it;
// int counter = 0;
// for(it = res.resmsg.begin(); it < res.resmsg.end(); it++)
// {
// counter++;
// U9_LLOG(counter << " ~ " << *it);
// }
env.dimm_seeing = atof(res.resmsg[1].c_str());
env.dimm_mean_flux = atof(res.resmsg[2].c_str());
env.lbt_weather_alive = (bool)atoi(res.resmsg[3].c_str());
env.lbt_pressure = atof(res.resmsg[4].c_str());
env.lbt_temp = atof(res.resmsg[5].c_str());
env.lbt_humidity = atof(res.resmsg[6].c_str());
env.lbt_dewpoint = atof(res.resmsg[7].c_str());
env.mcs_elevation = atof(res.resmsg[8].c_str())/3600;
env.mcs_azimuth = atof(res.resmsg[9].c_str())/3600;
env.smt_dewpoint = atof(res.resmsg[11].c_str());
env.smt_humidity = atof(res.resmsg[12].c_str());
env.smt_pressure = atof(res.resmsg[13].c_str());
env.smt_wind_speed = atof(res.resmsg[14].c_str());
env.smt_wind_dir = atof(res.resmsg[15].c_str());
env.smt_tau = atof(res.resmsg[16].c_str());
env.ao_offsetx = atof(res.resmsg[17].c_str());
env.ao_offsety = atof(res.resmsg[18].c_str());
env.ao_offsetz = atof(res.resmsg[19].c_str());
env.target_decoffset = atof(res.resmsg[20].c_str());
env.target_raoffset = atof(res.resmsg[21].c_str());
env.target_ra = atof(res.resmsg[22].c_str());
env.target_dec = atof(res.resmsg[23].c_str());
env.achieved_ra = atof(res.resmsg[24].c_str());
env.achieved_dec = atof(res.resmsg[25].c_str());
env.parallactic_angle = atof(res.resmsg[26].c_str());
env.achieved_alt = atof(res.resmsg[27].c_str());
env.achieved_az = atof(res.resmsg[28].c_str());
// env.weather_comment = atof(res.resmsg[28].c_str());
}
else
{
for(unsigned int i = 0; i < res.resmsg.size(); i++)
{
U9_LLOG(res.resmsg[i]);
}
}
}
void SeqDataMgr::GetReadoutRegion(int & xmin, int & xmax, int & ymin, int & ymax)
{
xmin = xmax = ymin = ymax = 0;
std::map<std::string, indi::IElement>::const_iterator itRegion;
const std::map<std::string, indi::IElement> & elements = sashaReadoutRegion.getElements();
itRegion = elements.find("x1");
Davide Ricci
committed
{
if(!su::getValue<int>(itRegion->second.get(), xmin)){ W_LLOG("Could not get readout region XMIN value");}
Davide Ricci
committed
}
else { W_LLOG("Could not find readout region XMIN value");}
itRegion = elements.find("x2");
if(itRegion != elements.end())
{
if(!su::getValue<int>(itRegion->second.get(), xmax)){ W_LLOG("Could not get readout region XMAX value");}
}
else { W_LLOG("Could not find readout region XMAX value");}
itRegion = elements.find("y1");
if(itRegion != elements.end())
{
if(!su::getValue<int>(itRegion->second.get(), ymin)){ W_LLOG("Could not get readout region YMIN value");}
}
else { W_LLOG("Could not find readout region YMIN value");}
itRegion = elements.find("y2");
if(itRegion != elements.end())
{
if(!su::getValue<int>(itRegion->second.get(), ymax)){ W_LLOG("Could not get readout region YMAX value");}
}
else { W_LLOG("Could not find readout region YMAX value");}
}
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int SeqDataMgr::sashaEnableSave(const std::map<std::string, std::string> & _dSashaSetup)
{
// To be Implemented
U6_LLOG(__FUNCTION__ << " ~ DEPRECATED");
Ice::Int status = EXIT_SUCCESS;
#ifdef UNDEFINED
IProperty sashaSave(IProperty::Switch), recvProp;
std::map<std::string, std::string>::const_iterator itFind;
itFind = _dSashaSetup.find("SAVE");
// m_ptrIc->connect();
// NOTE while alive, indiserver does not close the connection to the client.
// U1_LLOG("Command sasha to save to file");
U1_LLOG("Command sasha to save to file");
sashaSave.setDevice("sasha_save");
sashaSave.setName("enable_save");
sashaSave.setPerm(IProperty::ReadWrite);
sashaSave.setState(IProperty::Busy);
sashaSave.add(IElement("value"));
// Switch properties can have value On or Off
sashaSave["value"].setSwitchState(IElement::Off);
U1_LLOG(sashaSave.getType());
if((su::str_tolower(itFind->second) == "true") || (itFind->second == "1"))
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{
sashaSave["value"].setSwitchState(IElement::On);
}
}
//
m_ptrIc2->send_new_property_wait2(sashaSave, recvProp);
#endif
// status = m_ptrIc->close();
U8_LLOG(__FUNCTION__);
return status;
}
int SeqDataMgr::sashaGetFitsFile(const std::map<std::string, std::string> & _dSashaSetup, const std::string & _instMode, std::string & _outFilename)
{
U6_LLOG(__FUNCTION__ << " ~ DEPRECATED");
int status = EXIT_FAILURE;
#ifdef UNDEFINED
std::string strObjname = "test";
Ice::CommunicatorPtr dataMgrIC;
// std::ostringstream streamRsync;
// std::ostringstream streamFileNum;
// std::ostringstream streamFileName;
std::ofstream fout;
// --Ice.Config=$INSROOT/etc/data_mgr/data_mgr-ice.cfg
// char* argvDataMgr[] = { "SequencerI::sashaGetFITSFile",
// "--Ice.Config=/opt/tan/etc/data_mgr/data_mgr-ice.cfg" };
// int argcDataMgr = 2;
// CFITSIO related
//
// Saving file to disk
// filename format is SHARKNIR.YYYY-MM-DDThh:mm:ss.ssssssZ.<_instMode>.fits
// this is passed to data manager for future use in mearging headers
// and saved in output parameter
//
// get date of file creation by INDI in ISO8601 format
dateISO8601 = recvProp.getTimeStamp().getFormattedIso8601Str();
filenameSASHA = "SHARKNIR." + dateISO8601 + "." + _instMode + ".SASHA.fits";
filenameSHINS = "SHARKNIR." + dateISO8601 + "." + _instMode + ".fits";
/* what follows is most likely old code to be erased
at this moment dataMgr will take care of ingesting file to
LBT archive mount point
// setting filenameSASHA as filename of acquired FITS file to data_mgr for its reference
// NOTE: may not be necessary
dataMgrIC = Ice::initialize(argcDataMgr, argvDataMgr);
Ice::ObjectPrx base = dataMgrIC->stringToProxy("dataManagerAdapter:default -p 10501");
sd::fitsFilePrx archiver = sd::fitsFilePrx::checkedCast(base);
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throw("Invalid Proxy");
// setting name of SASHA produced FITS in data manager component
status = archiver->setCurrentFilenameSASHA(filenameSASHA);
U4_LLOG(archiver->getCurrentFilenameSASHA());
// creating fits file with no data and with complete+populated header.
status = archiver->createEmptyAndPopulateHeader(filnameSHINS, bitpix, naxis, vecNaxes);
status = archiver->mergeHeadersAndCopyData(filenameSHINS, filenameSASHA);
*/
}
}
}
}
}
if(dataMgrIC)dataMgrIC->destroy();
// creating standard vectors with keywords values and comments for SHINS part of header.
// These vectors will be passed to data manager which will merge them to SASHA header
// by creating in place a FITS header and merging it to SASHA header, without creating
// a second file on disk
// create header only fits file to fill with SHINS values for keywords
// try
// {
// dataMgrIC = Ice::initialize(argcDataMgr, argvDataMgr);
// Ice::ObjectPrx base = dataMgrIC->stringToProxy("dataManagerAdapter:default -p 10501");
// sd::fitsFilePrx archiver = sd::fitsFilePrx::checkedCast(base);
// throw("Invalid Proxy");
// status = archiver->saveSASHABLOB(toBitsBlob, counter);
// status = archiver->setCurrentFilenameSASHA(_outFilenameSASHA);
// }
// catch(const Ice::Exception& ex)
// catch(const char* msg)
// if(dataMgrIC)dataMgrIC->destroy();
// timeOut = su::convertStringToType<long>(itDit->second)*
// su::convertStringToType<float>(itNDit->second)*std::pow(10,6); // time out have to be in micro seconds
// U1_LLOG("time out = " << timeOut*2 << " micro seconds");
// IndiProperty sashaSaveFileNum(IndiProperty::Text);
// IndiProperty sharknirUTCDate(IndiProperty::Number);
// the method shouhld check on remote INDI property for info on exposure status
// alredy done by sashaExpose, but to control twice is better
// _outFilenameSASHA = "No Filename Retrieved";
// boost::thread fits_notify_thread(inotifierInstance.start, _remotePathToWatch,
// boost::ref(_outFilenameSASHA),
// timeOut*6); // create and start thread
// fits_notify_thread.join(); // Wait for thread to finish
// check on _outFilenameSASHA
// fits_notify_thread should have timeout parameter for INotifier::start
itFind = _dSashaSetup.find("OBJECTNAME");
if(!(itFind == _dSashaSetup.end()))strObjname = itFind->second;
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// sashaSaveFileNum = init_indi_property("sasha_save", "largest_filenum", IndiProperty::Text, std::vector<std::string>(1, "value"));
// vecElemNames.push_back("JD");
// vecElemNames.push_back("UTC");
// vecElemNames.push_back("UTCDate");
// vecElemNames.push_back("LT");
// vecElemNames.push_back("LST");
// vecElemNames.push_back("MoonAz");
// vecElemNames.push_back("MoonAlt");
// vecElemNames.push_back("MoonElong");
// vecElemNames.push_back("MoonLit");
// vecElemNames.push_back("SunAz");
// vecElemNames.push_back("SunAlt");
// sharknirUTCDate = init_indi_property("sharknir_time", "Now",
// IndiProperty::Number,
// vecElemNames);
// // NOTE while alive, indiserver does not close the connection to the client.
// U1_LLOG("Asking INDI for file number ...");
// m_ptrIc2->send_get_property_wait(sashaSaveFileNum, recvProp);
// streamFileNum << std::setfill('0') << std::setw(6)
// << recvProp["value"].getValue() << std::setfill(' ');
// recvProp.clear();
// U1_LLOG("Asking INDI for UTC date ... ");
// m_ptrIc2->send_get_property_wait(sharknirUTCDate, recvProp);
// strUTCDate = recvProp["UTCDate"].getValue().substr(2,recvProp["UTCDate"].getValue().size()-2);
// U1_LLOG("Got " << recvProp["UTCDate"].getValue());
// U1_LLOG("Extracted " << strUTCDate);
// streamRsync << "rsync -avzh " << su::get_LLOGin() << "@sashaws::fits/" << strUTCDate
// << "/sa_" << strUTCDate << "_" << streamFileNum.str()
// << ".fits " << dataDir
// << "SHARKNIR_" << strObjname << "_" << recvProp["UTCDate"].getValue()
// << "_" << streamFileNum.str() << ".fits";
// streamFileName << "SHARKNIR_" << strObjname << "_" << recvProp["UTCDate"].getValue()
// << "_" << streamFileNum.str() << ".fits";
// status = std::system(streamRsync.str().c_str());
}
#endif
U8_LLOG("");
return status;
}
// Patch to get rid of the timeout problem of sasha driver. NREAD is sent whenever NDIT changes and no other parameters are sent
int SeqDataMgr::sashaEndSetup(std::map<std::string, std::string> & _dTimeoutSetup, bool ndit_changed)
{
U6_LLOG(__FUNCTION__);
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if(ndit_changed && _dTimeoutSetup.empty())
{
IProperty & prop = m_sashaProps.find("NREADS")->second;
const std::map<std::string, indi::IElement> elements = prop.getElements();
if(elements.find("value") != elements.end())
{
_dTimeoutSetup["NREADS"] = prop["value"].getValue();
}
else
{
std::stringstream log_msg;
log_msg << "Error : IProperty \"" << prop.getDevice() << "." << prop.getName() << "\" from INDI Server has changed";
E_LLOG(log_msg.str());
throw(std::runtime_error(log_msg.str()));
}
}
std::map<std::string, std::string>::iterator itSetup;
int num_properties = _dTimeoutSetup.size();
int counter = 0, sent_properties = 0;
try
{
for(itSetup = _dTimeoutSetup.begin(); itSetup != _dTimeoutSetup.end(); itSetup++)
{
if(m_getFitsAbortFlag)break;
counter++;
IProperty & prop = m_sashaProps.find(itSetup->first)->second;
const std::map<std::string, indi::IElement> elements = prop.getElements();
bool bPropError = false, bSetProperty = false;
if(elements.find("value") != elements.end())
{
if(m_bForcePropertySet || itSetup->second != prop["value"].getValue())
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{
prop["value"].setValue<int>(su::convertStringToType<int>(itSetup->second));
bSetProperty = true;
}
}
else
bPropError = true;
if(bPropError)
{
std::stringstream log_msg;
log_msg << "Error : IProperty \"" << prop.getDevice() << "." << prop.getName() << "\" from INDI Server has changed";
E_LLOG(log_msg.str());
throw(std::runtime_error(log_msg.str()));
}
else if(bSetProperty || (sent_properties == 0 && counter == num_properties))
{
m_sashaPropsSet[itSetup->first] = false;
SendNewProperty(prop);
sent_properties++;
}
}
bool wait_result = false;
wait_result = WaitSetMessages(60000000);
if(!wait_result)status = EXIT_FAILURE;
}
catch(...)
{
E_LLOG(__FUNCTION__);
U8_LLOG("");
throw;
}
U8_LLOG("");
return status;
}
int SeqDataMgr::sashaSetup(const std::map<std::string, std::string> & _dSashaExpose)
{
U6_LLOG(__FUNCTION__);
int status = EXIT_SUCCESS;
m_exposeMutex.lock();
for(itSashaSetup = m_sashaSetup.begin(); itSashaSetup != m_sashaSetup.end(); itSashaSetup++)
{
if(itSashaSetup->first == suc::instrument_mode)
itSashaSetup->second = "UNDEF";
itSashaSetup->second.clear();
}
std::map<std::string, std::string>::const_iterator itSetup;
for(itSetup = _dSashaExpose.begin(); itSetup != _dSashaExpose.end(); itSetup++)
{
U9_LLOG("Keyword : " << itSetup->first << "; Value : " << itSetup->second);
{
std::stringstream log_msg;
log_msg << "Keyword not allowed in sashaExpose : " << itSetup->first;
E_LLOG(log_msg.str());
throw(std::invalid_argument(log_msg.str()));
}
bool bForceTimeoutRefresh = false;
bool ndit_changed = false;
checkContinuousFlag();
std::map<std::string, std::string> incomingSetup = _dSashaExpose;
std::map<std::string, std::string> timeoutSetup;
timeoutSetup = su::extract_setup(m_timeoutSetup, incomingSetup);
for(itSetup = incomingSetup.begin(); itSetup != incomingSetup.end(); itSetup++)
{
if(m_getFitsAbortFlag)break;
if(itSetup->first == "DIT" || itSetup->first == "InstrumentMode")
{
}
else
{
// U9_LLOG("setup : " << itSetup->first << ":" << itSetup->second);
IProperty & prop = m_sashaProps.find(itSetup->first)->second;
const std::map<std::string, indi::IElement> elements = prop.getElements();
bool bPropError = false, bSetProperty = false;
if(itSetup->first == "SAVE")
{
bool bSave = true;
su::get_bool_from_setup(_dSashaExpose, "SAVE", bSave);
std::map<std::string, indi::IElement>::const_iterator itEl;
if(elements.find("value") != elements.end())
{
indi::IElement::SwitchStateType switch_state = (bSave ? IElement::On : IElement::Off);
if(m_bForcePropertySet || prop["value"].getSwitchState() != switch_state)
{
prop["value"].setSwitchState(switch_state);
// U9_LLOG("Setting : " << "value" << " to " << bSave);
bSetProperty = true;
}
}
else
bPropError = true;
}
else if(itSetup->first == "OBJECTNAME")
{
if(elements.find("value") != elements.end())
{
std::string current_name = prop["value"].getValue();
if(m_bForcePropertySet || current_name != itSetup->second)
{
prop["value"].setValue(itSetup->second);
bSetProperty = true;
else
bPropError = true;
}
// else if(itSetup->first == "NCOADDS")
// {
// if(elements.find("num_coadds") != elements.end())
// prop["num_coadds"].setValue<int>(su::convertStringToType<int>(itSetup->second));
// else
// bPropError = true;
// }
else if(itSetup->first == "READOUT")
{
if(elements.find("value") != elements.end())
if(m_bForcePropertySet || prop["value"].getValue() != itSetup->second)
{
prop["value"].setValue(itSetup->second);
bSetProperty = true;
}
}
else
bPropError = true;
}
else
{
if(elements.find("value") != elements.end())
{
// int value = su::convertStringToType<int>(prop["value"].getValue());
if(m_bForcePropertySet || itSetup->second != prop["value"].getValue())
if(itSetup->first == "NDIT")ndit_changed = true;
prop["value"].setValue<int>(su::convertStringToType<int>(itSetup->second));
bSetProperty = true;
}
}
else
bPropError = true;
}
if(bPropError)
{
std::stringstream log_msg;
log_msg << "Error : IProperty \"" << prop.getDevice() << "." << prop.getName() << "\" from INDI Server has changed";
E_LLOG(log_msg.str());
throw(std::runtime_error(log_msg.str()));
}
else if(bSetProperty)
{
m_sashaPropsSet[itSetup->first] = false;
SendNewProperty(prop);
}
}
}
updateInstrumentHeader();
if(!bObjectNamesSet)
{
const std::map<std::string, indi::IElement> elements = sashaObjName.getElements();
if(elements.find("value") != elements.end())
{
m_sashaPropsSet["OBJECTNAME"] = false;
sashaObjName["value"].setValue(m_TcsPreset.object_name);
SendNewProperty(sashaObjName);
}
}
bool wait_result = false;
wait_result = WaitSetMessages(60000000);
if(!wait_result)status = EXIT_FAILURE;
int status2 = sashaEndSetup(timeoutSetup, ndit_changed);
if(status == EXIT_FAILURE || status2 == EXIT_FAILURE)status = EXIT_FAILURE;
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}
catch(...)
{
m_exposeMutex.unlock();
U8_LLOG("");
throw;
}
m_exposeMutex.unlock();
U8_LLOG(__FUNCTION__ << " exiting");
return status;
}
int SeqDataMgr::sashaSetFrequency(const std::map<std::string, std::string> & _dSashaExpose)
{
U6_LLOG(__FUNCTION__);
int status = EXIT_SUCCESS;
m_exposeMutex.lock();
try
{
std::map<std::string, std::string>::const_iterator itSetup;
itSetup = _dSashaExpose.find("FREQUENCY");
if(itSetup != _dSashaExpose.end())
{
IProperty & prop = m_sashaProps.find(itSetup->first)->second;
const std::map<std::string, indi::IElement> elements = prop.getElements();
if(elements.find("value") != elements.end())
{
if(m_bForcePropertySet || prop["value"].getValue() != itSetup->second)
{
prop["value"].setValue(itSetup->second);
m_sashaPropsSet[itSetup->first] = false;
SendNewProperty(prop);
//camera reinitializes and readout region is reset
m_sashaPropsSet["READOUT"] = false;
WaitSetMessages(60000000);
}
}
else
{
U9_LLOG("Error: frequency property from INDI server has changed");
}
}
}
catch(...)
{
m_exposeMutex.unlock();
U8_LLOG("");
throw;
}
m_exposeMutex.unlock();
U8_LLOG(__FUNCTION__ << " exiting");
return status;
}
int SeqDataMgr::checkContinuousFlag()
{
int status = EXIT_SUCCESS;
if(!(sashaExposeProp["value"].getSwitchState() == IElement::Off))
{
m_sashaPropsSet["STOP"] = false;
sashaStop["value"].setSwitchState(IElement::On);
SendNewProperty(sashaStop);
m_sashaPropsSet["EXPOSE"] = false;
U6_LLOG(__FUNCTION__ << " ~ Clearing Expose Property");
WaitSetMessages(10000000);
m_sashaPropsSet["EXPOSE"] = false;
WaitSetMessages(10000000);
}
// if(!(sashaEnableCont["value"].getSwitchState() == IElement::Off))
// enable_cont property is resetted every time because is sometimes found misaligned with the one on the indi server
{
m_sashaPropsSet["CONTINUOUS"] = false;
sashaEnableCont["value"].setSwitchState(IElement::Off);
SendNewProperty(sashaEnableCont);
WaitSetMessages(10000000);
}
return status;
}
int SeqDataMgr::sashaExpose2(std::vector<std::string> & out_files)
{
U6_LLOG(__FUNCTION__);
int status = EXIT_SUCCESS;
m_exposeMutex.lock();
Davide Ricci
committed
m_getFitsAbortFlag = 0;
checkContinuousFlag();
m_last_generated_files.clear();
if(m_bSaveOnlyExposedFiles && !m_getFitsAbortFlag)
{
sashaBlob.setBLOBEnable(IProperty::Also);
SendNewProperty(sashaBlob);
}
bool wait_result = false;
wait_result = WaitSetMessages(60000000);
if(!m_getFitsAbortFlag)
{
m_sashaPropsSet["EXPOSE"] = false;
sashaExposeProp["value"].setSwitchState(IElement::On);
SendNewProperty(sashaExposeProp);
m_ExpectedBlobs = su::convertStringToType<int>(sashaNumSeqs["value"].getValue());
m_bInstrumentSetupUpdated = false;
updateInstrumentHeader();
wait_result = WaitSetMessages(30000000);
}
if(!m_getFitsAbortFlag)
{
wait_result = WaitStartAcquireOff(ExtimateTiming() + 20000);
m_bBlobArrived = false;
}
if(m_bSaveOnlyExposedFiles)
{
if(m_ExpectedBlobs > 0)WaitBLOB(20000);
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sashaBlob.setBLOBEnable(IProperty::Never);
SendNewProperty(sashaBlob);
}
if(!wait_result)status = EXIT_FAILURE;
if(m_getFitsAbortFlag)
{
throw(std::runtime_error("Error acquisition aborted by user"));
}
}
catch(...)
{
m_exposeMutex.unlock();
if(m_getFitsAbortFlag)m_getFitsAbortFlag--;
U8_LLOG("");
throw;
}
if(m_getFitsAbortFlag)m_getFitsAbortFlag--;
m_exposeMutex.unlock();
out_files = m_last_generated_files;
m_last_generated_file = "";
m_last_generated_files.clear();
U8_LLOG(__FUNCTION__ << " exiting");
return status;
}
void SeqDataMgr::abortExposure()
{
m_getFitsAbortFlag = 1;
SendNewProperty(sashaStop);
}
bool SeqDataMgr::WaitSetMessages(int timeout)
{
bool wait_sets = true;
int waited_time = 0;
int sleep_time = 1000;
std::stringstream log_msg;
while(wait_sets)
{
usleep(sleep_time);
waited_time += sleep_time;
sleep_time = 49000*(waited_time == 1000) + 50000*(waited_time > 1000);
std::map<std::string, bool>::iterator itSet;
for(itSet = m_sashaPropsSet.begin(); itSet != m_sashaPropsSet.end(); itSet++)
{
if(!itSet->second)break;
}
wait_sets = itSet != m_sashaPropsSet.end();
if(waited_time >= timeout)
{
log_msg << __FUNCTION__ << " ~ Timed Out waiting for : ";
for(itSet = m_sashaPropsSet.begin(); itSet != m_sashaPropsSet.end(); itSet++)
{
if(!itSet->second)
log_msg << itSet->first << " ~ ";
}
if(m_bReceivedEof)
{
E_LLOG("Received EOF");
U8_LLOG("");
throw(std::runtime_error("Indi Server signaled EoF"));
}
if(m_getFitsAbortFlag)break;
}
if(waited_time > 1000)
{
U6_LLOG(__FUNCTION__);
if(!log_msg.str().empty()){E_LLOG(log_msg.str());};
U8_LLOG(__FUNCTION__ << " ~ Exiting; waited " << waited_time/1000.f << "ms");
}
return !wait_sets;
}
bool SeqDataMgr::WaitStartAcquireOff(unsigned int timeout)
{
U6_LLOG(__FUNCTION__);
bool wait_result = true;
unsigned int waited_time = 0;
while(wait_result)
{
usleep(200000);
waited_time += 200;
wait_result = !(sashaExposeProp["value"].getSwitchState() == IElement::Off);
if(waited_time >= timeout)
{
E_LLOG(__FUNCTION__ << " ~ Timed Out");
break;
}
if((waited_time % 300000) == 0)
{
U9_LLOG(__FUNCTION__ << " ~ Waiting " << waited_time/1000.f << "/" << timeout/1000.f << "s");
}
if(m_getFitsAbortFlag)break;
if(m_bReceivedEof)
{
E_LLOG("Received EOF");
U8_LLOG("");
throw(std::runtime_error("Indi Server signaled EoF"));
}
}
U8_LLOG(__FUNCTION__ << " ~ Exiting; waited " << waited_time << "ms");
return !wait_result;
}
bool SeqDataMgr::WaitBLOB(unsigned int timeout)
{
U6_LLOG(__FUNCTION__);
bool wait_result = true;
unsigned int waited_time = 0;
while(wait_result)
{
usleep(200000);
waited_time += 200;
wait_result = !(m_bBlobArrived == true);
if(wait_result && waited_time >= timeout)
{
E_LLOG(__FUNCTION__ << " ~ Timed Out");
break;
}
if((waited_time % 300000) == 0)
{
U9_LLOG(__FUNCTION__ << " ~ Waiting " << waited_time/1000.f << "/" << timeout/1000.f << "s");
}
if(m_getFitsAbortFlag)break;
if(m_bReceivedEof)
{
E_LLOG("Received EOF");
U8_LLOG("");
throw(std::runtime_error("Indi Server signaled EoF"));
}
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}
U8_LLOG(__FUNCTION__ << " ~ Exiting; waited " << waited_time << "ms");
return !wait_result;
}
// I_LOG("Asking for temperature to sensor");
// IProperty sharknirTemp(IProperty::Text), recvProp;
// sharknirTemp.setDevice("sharknir_temp");
// sharknirTemp.setName("sensor");
// sharknirTemp.add(IElement("enable_alarm"));
// sharknirTemp.add(IElement("enable_collection"));
// sharknirTemp.add(IElement("identifie"));
// sharknirTemp.add(IElement("is_connected"));
// sharknirTemp.add(IElement("max_value"));
// sharknirTemp.add(IElement("min_value"));
// sharknirTemp.add(IElement("notify_email_file"));
// sharknirTemp.add(IElement("notify_email_list"));
// sharknirTemp.add(IElement("tag"));
// sharknirTemp.add(IElement("units"));
// sharknirTemp.add(IElement("value"));
// heater
/*
IProperty sharknirTempHeater(IndiProperty::Text);
sharknirTempHeater.setDevice("sharknir_sensors");
sharknirTempHeater.setName("Heater");
sharknirTempHeater.setPerm(IndiProperty::ReadOnly);
sharknirTempHeater.setState(IndiProperty::Busy);
sharknirTempHeater.add(IndiElement("command"));
sharknirTempHeater.add(IndiElement("enable_collection"));
sharknirTempHeater.add(IndiElement("hardware_num"));
sharknirTempHeater.add(IndiElement("identifier"));
sharknirTempHeater.add(IndiElement("max_power"));