Exemplo n.º 1
0
  /** Execute the algorithm.
   */
  void SaveIsawPeaks::exec()
  {
    // Section header
    std::string header = "2   SEQN    H    K    L     COL      ROW     CHAN        L2   2_THETA        AZ         WL         D      IPK          INTI    SIGI  RFLG";

    std::string filename = getPropertyValue("Filename");
    PeaksWorkspace_sptr ws = getProperty("InputWorkspace");
    std::vector<Peak> peaks = ws->getPeaks();

    // We must sort the peaks first by run, then bank #, and save the list of workspace indices of it
    typedef std::map<int, std::vector<size_t> > bankMap_t;
    typedef std::map<int, bankMap_t> runMap_t;
    std::set<int> uniqueBanks;
    runMap_t runMap;

    for (size_t i=0; i < peaks.size(); ++i)
    {
      Peak & p = peaks[i];
      int run = p.getRunNumber();
      int bank = 0;
      std::string bankName = p.getBankName();
      if (bankName.size() <= 4)
      {
        g_log.information() << "Could not interpret bank number of peak " << i << "(" << bankName << ")\n";
        continue;
      }
      // Take out the "bank" part of the bank name and convert to an int
      bankName = bankName.substr(4, bankName.size()-4);
      Strings::convert(bankName, bank);

      // Save in the map
      runMap[run][bank].push_back(i);
      // Track unique bank numbers
      uniqueBanks.insert(bank);
    }

    Instrument_const_sptr inst = ws->getInstrument();
    if (!inst) throw std::runtime_error("No instrument in PeaksWorkspace. Cannot save peaks file.");

    double l1; V3D beamline; double beamline_norm; V3D samplePos;
    inst->getInstrumentParameters(l1, beamline, beamline_norm, samplePos);

    std::ofstream out;
    bool append = getProperty("AppendFile");
    if (append)
    {
      out.open( filename.c_str(), std::ios::app);
    }
    else
    {
      out.open( filename.c_str());


    out << "Version: 2.0  Facility: SNS " ;
    out <<  " Instrument: " <<  inst->getName() <<  "  Date: " ;

    //TODO: The experiment date might be more useful than the instrument date.
    // For now, this allows the proper instrument to be loaded back after saving.
    Kernel::DateAndTime expDate = inst->getValidFromDate() + 1.0;
    out <<  expDate.to_ISO8601_string() << std::endl;

    out << "6         L1    T0_SHIFT" <<  std::endl;
    out << "7 "<< std::setw( 10 )  ;
    out <<   std::setprecision( 4 ) <<  std::fixed <<  ( l1*100 ) ;
    out << std::setw( 12 ) <<  std::setprecision( 3 ) <<  std::fixed  ;
    // Time offset of 0.00 for now
    out << "0.000" <<  std::endl;


    // ============================== Save .detcal info =========================================
    if (true)
    {
      out <<  "4 DETNUM  NROWS  NCOLS   WIDTH   HEIGHT   DEPTH   DETD   CenterX   CenterY   CenterZ    BaseX    BaseY    BaseZ      UpX      UpY      UpZ"
          <<  std::endl;
      // Here would save each detector...
      std::set<int>::iterator it;
      for (it = uniqueBanks.begin(); it != uniqueBanks.end(); it++)
      {
        // Build up the bank name
        int bank = *it;
        std::ostringstream mess;
        mess << "bank" << bank;
        std::string bankName = mess.str();
        // Retrieve it
        RectangularDetector_const_sptr det = boost::dynamic_pointer_cast<const RectangularDetector>(inst->getComponentByName(bankName));
        if (det)
        {
          // Center of the detector
          V3D center = det->getPos();
          // Distance to center of detector
          double detd = (center - inst->getSample()->getPos()).norm();

          // Base unit vector (along the horizontal, X axis)
          V3D base = det->getAtXY(det->xpixels()-1,0)->getPos() - det->getAtXY(0,0)->getPos();
          base.normalize();
          // Up unit vector (along the vertical, Y axis)
          V3D up = det->getAtXY(0,det->ypixels()-1)->getPos() - det->getAtXY(0,0)->getPos();
          up.normalize();

          // Write the line
          out << "5 "
           << std::setw(6) << std::right << bank << " "
           << std::setw(6) << std::right << det->xpixels() << " "
           << std::setw(6) << std::right << det->ypixels() << " "
           << std::setw(7) << std::right << std::fixed << std::setprecision(4) << 100.0*det->xsize() << " "
           << std::setw(7) << std::right << std::fixed << std::setprecision(4) << 100.0*det->ysize() << " "
           << "  0.2000 "
           << std::setw(6) << std::right << std::fixed << std::setprecision(2) << 100.0*detd << " "
           << std::setw(9) << std::right << std::fixed << std::setprecision(4) << 100.0*center.X() << " "
           << std::setw(9) << std::right << std::fixed << std::setprecision(4) << 100.0*center.Y() << " "
           << std::setw(9) << std::right << std::fixed << std::setprecision(4) << 100.0*center.Z() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << base.X() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << base.Y() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << base.Z() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << up.X() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << up.Y() << " "
           << std::setw(8) << std::right << std::fixed << std::setprecision(5) << up.Z() << " "
           << std::endl;

        }
      }
    }
    }


    // ============================== Save all Peaks =========================================
    // Sequence number
    int seqNum = 1;

    // Go in order of run numbers
    runMap_t::iterator runMap_it;
    for (runMap_it = runMap.begin(); runMap_it != runMap.end(); runMap_it++)
    {
      // Start of a new run
      int run = runMap_it->first;
      bankMap_t & bankMap = runMap_it->second;

      bankMap_t::iterator bankMap_it;
      for (bankMap_it = bankMap.begin(); bankMap_it != bankMap.end(); bankMap_it++)
      {
        // Start of a new bank.
        int bank = bankMap_it->first;
        std::vector<size_t> & ids = bankMap_it->second;

        if (ids.size() > 0)
        {
          // Write the bank header
          out << "0 NRUN DETNUM    CHI      PHI    OMEGA   MONCNT" << std::endl;
          out <<  "1" <<  std::setw( 5 ) <<  run <<  std::setw( 7 ) <<
              std::right <<  bank;

          // Determine goniometer angles by calculating from the goniometer matrix of a peak in the list
          Goniometer gon(peaks[ids[0]].getGoniometerMatrix());
          std::vector<double> angles = gon.getEulerAngles("yzy");

          double phi = angles[2];
          double chi = angles[1];
          double omega = angles[0];

          out  <<  std::setw( 7 ) <<  std::fixed <<  std::setprecision( 2 )  <<  chi << " ";
          out  <<  std::setw( 7 ) <<  std::fixed <<  std::setprecision( 2 )  <<  phi << " ";
          out  <<  std::setw( 7 ) <<  std::fixed <<  std::setprecision( 2 )  <<  omega << " ";
          out  <<  std::setw( 7 ) <<  (int)( 0 ) <<  std::endl;

          out << header << std::endl;

          // Go through each peak at this run / bank
          for (size_t i=0; i < ids.size(); i++)
          {
            size_t wi = ids[i];
            Peak & p = peaks[wi];

            // Sequence (run) number
            out <<  "3" <<  std::setw( 7 ) << seqNum;

            // HKL is flipped by -1 due to different q convention in ISAW vs mantid.
            out <<  std::setw( 5 ) << Utils::round(-p.getH())
                <<  std::setw( 5 ) << Utils::round(-p.getK())
                <<  std::setw( 5 ) << Utils::round(-p.getL());

            // Row/column
            out <<  std::setw( 8 ) <<  std::fixed << std::setprecision( 2 )
              << static_cast<double>(p.getCol()) << " ";

            out << std::setw( 8 ) << std::fixed << std::setprecision( 2 )
              << static_cast<double>(p.getRow()) << " ";

            out << std::setw( 8 ) << std::fixed << std::setprecision( 0 )
              << p.getTOF() << " ";


            out << std::setw( 9 ) << std::fixed << std::setprecision( 3 )
              << (p.getL2()*100.0) << " ";

            // This is the scattered beam direction
            V3D dir = p.getDetPos() - inst->getSample()->getPos();
            double scattering, azimuth;

            // Two-theta = polar angle = scattering angle = between +Z vector and the scattered beam
            scattering = dir.angle( V3D(0.0, 0.0, 1.0) );

            // "Azimuthal" angle: project the beam onto the XY plane, and measure the angle between that and the +X axis (right-handed)
            azimuth = atan2( dir.Y(), dir.X() );

            out << std::setw( 9 ) << std::fixed << std::setprecision( 5 )
              << scattering << " "; //two-theta scattering

            out << std::setw( 9 ) << std::fixed << std::setprecision( 5 )
              << azimuth << " ";

            out << std::setw( 10 ) << std::fixed << std::setprecision( 6 )
              << p.getWavelength() << " ";

            out << std::setw( 9 ) << std::fixed << std::setprecision( 4 )
              << p.getDSpacing() << " ";

            out << std::setw( 8 ) << std::fixed << int(p.getBinCount()) << std::setw( 10 ) << " "
              << std::fixed << std::setprecision( 2 ) << p.getIntensity() << " ";

            out << std::setw( 7 ) << std::fixed << std::setprecision( 2 )
              << p.getSigmaIntensity() << " ";

            int thisReflag = 310;
            out << std::setw( 5 ) << thisReflag;

            out << std::endl;

            // Count the sequence
            seqNum++;
          }
        }
      }
    }

    out.flush();
    out.close();

//    //REMOVE:
//    std::string line;
//    std::ifstream myfile (filename.c_str());
//    if (myfile.is_open())
//    {
//      while ( myfile.good() )
//      {
//        getline (myfile,line);
//        std::cout << line << std::endl;
//      }
//      myfile.close();
//    }


  }
Exemplo n.º 2
0
/**
* Set the run start and end
* @param start :: The run start
* @param end :: The run end
*/
void Run::setStartAndEndTime(const Kernel::DateAndTime & start, const Kernel::DateAndTime & end)
{
    this->addProperty<std::string>("start_time", start.to_ISO8601_string(), true);
    this->addProperty<std::string>("end_time", end.to_ISO8601_string(), true);
}