LCOV - code coverage report
Current view: top level - msvis/MSVis - VisBufferUtil.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 70 537 13.0 %
Date: 2024-10-10 11:40:37 Functions: 5 26 19.2 %

          Line data    Source code
       1             : //# VisBufferUtil.cc: VisBuffer Utilities
       2             : //# Copyright (C) 1996,1997,2001
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This library is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU Library General Public License as published by
       7             : //# the Free Software Foundation; either version 2 of the License, or (at your
       8             : //# option) any later version.
       9             : //#
      10             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Library General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU Library General Public License
      16             : //# along with this library; if not, write to the Free Software Foundation,
      17             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be adressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : //#
      27             : //# $Id$
      28             : 
      29             : #include <casacore/casa/aips.h>
      30             : 
      31             : #include <casacore/casa/Utilities/Assert.h>
      32             : #include <casacore/casa/Exceptions/Error.h>
      33             : #include <casacore/casa/Arrays/ArrayMath.h>
      34             : #include <casacore/casa/Arrays/MatrixMath.h>
      35             : #include <casacore/casa/Arrays/Array.h>
      36             : #include <casacore/casa/Arrays/Vector.h>
      37             : #include <casacore/casa/Arrays/Matrix.h>
      38             : #include <casacore/casa/Arrays/Cube.h>
      39             : #include <casacore/casa/Utilities/Sort.h>
      40             : #include <casacore/casa/OS/Timer.h>
      41             : #include <casacore/casa/OS/Path.h>
      42             : #include <casacore/measures/Measures/UVWMachine.h>
      43             : #include <casacore/measures/Measures/MeasTable.h>
      44             : #include <casacore/ms/MSSel/MSSelectionTools.h>
      45             : #include <casacore/ms/MeasurementSets/MSPointingColumns.h>
      46             : #include <msvis/MSVis/VisBufferUtil.h>
      47             : #include <msvis/MSVis/StokesVector.h>
      48             : #include <msvis/MSVis/ViImplementation2.h>
      49             : #include <msvis/MSVis/VisibilityIterator.h>
      50             : #include <msvis/MSVis/VisibilityIterator2.h>
      51             : #include <msvis/MSVis/VisBuffer.h>
      52             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      53             : #include <iostream>
      54             : #include <fstream>
      55             : #include <iomanip>
      56             : 
      57             : #ifdef _OPENMP
      58             : #include <omp.h>
      59             : #endif
      60             : using namespace std;
      61             : 
      62             : using namespace casacore;
      63             : namespace casa { //# NAMESPACE CASA - BEGIN
      64             : 
      65             : // <summary>
      66             : // </summary>
      67             : 
      68             : // <reviewed reviewer="" date="" tests="tMEGI" demos="">
      69             : 
      70             : // <prerequisite>
      71             : // </prerequisite>
      72             : //
      73             : // <etymology>
      74             : // </etymology>
      75             : //
      76             : // <synopsis>
      77             : // </synopsis>
      78             : //
      79             : // <example>
      80             : // <srcblock>
      81             : // </srcblock>
      82             : // </example>
      83             : //
      84             : // <motivation>
      85             : // </motivation>
      86             : //
      87             : // <todo asof="">
      88             : // </todo>
      89             : 
      90             : 
      91           0 :   VisBufferUtil::VisBufferUtil(): oldMSId_p(-1), oldPCMSId_p(-1), timeAntIndex_p(0), cachedPointingDir_p(0), cachedPhaseCenter_p(0){};
      92             : 
      93             : 
      94             : // Construct from a VisBuffer (sets frame info)
      95           0 :   VisBufferUtil::VisBufferUtil(const VisBuffer& vb): oldMSId_p(-1), oldPCMSId_p(-1), timeAntIndex_p(0), cachedPointingDir_p(0), cachedPhaseCenter_p(0) {
      96             : 
      97             :   // The nominal epoch
      98           0 :   MEpoch ep=vb.msColumns().timeMeas()(0);
      99             : 
     100             :   // The nominal position
     101           0 :   String observatory;
     102           0 :   MPosition pos;
     103           0 :   if (vb.msColumns().observation().nrow() > 0) {
     104           0 :     observatory = vb.msColumns().observation().telescopeName()
     105           0 :       (vb.msColumns().observationId()(0));
     106             :   }
     107           0 :   if (observatory.length() == 0 ||
     108           0 :       !MeasTable::Observatory(pos,observatory)) {
     109             :     // unknown observatory, use first antenna
     110           0 :     pos=vb.msColumns().antenna().positionMeas()(0);
     111             :   }
     112             : 
     113             :   // The nominal direction
     114           0 :   MDirection dir=vb.phaseCenter();
     115             : 
     116             :   // The nominal MeasFrame
     117           0 :   mframe_=MeasFrame(ep, pos, dir);
     118             : 
     119           0 : }
     120             : 
     121             : // Construct from a VisBuffer (sets frame info)
     122           3 :   VisBufferUtil::VisBufferUtil(const vi::VisBuffer2& vb): oldMSId_p(-1), oldPCMSId_p(-1),  timeAntIndex_p(0), cachedPointingDir_p(0), cachedPhaseCenter_p(0) {
     123           3 :         if(!vb.isAttached())
     124           0 :                 ThrowCc("Programmer Error: used a detached Visbuffer when it should not have been so");
     125           3 :         MSColumns msc(vb.ms());
     126             :   // The nominal epoch
     127           3 :   MEpoch ep=msc.timeMeas()(0);
     128             : 
     129             :   // The nominal position
     130           3 :   String observatory;
     131           3 :   MPosition pos;
     132           3 :   if (msc.observation().nrow() > 0) {
     133           3 :     observatory = msc.observation().telescopeName()
     134           3 :       (msc.observationId()(0));
     135             :   }
     136           6 :   if (observatory.length() == 0 ||
     137           3 :       !MeasTable::Observatory(pos,observatory)) {
     138             :     // unknown observatory, use first antenna
     139           0 :     pos=msc.antenna().positionMeas()(0);
     140             :   }
     141             : 
     142             :   // The nominal direction
     143           3 :   MDirection dir=vb.phaseCenter();
     144             : 
     145             :   // The nominal MeasFrame
     146           3 :   mframe_=MeasFrame(ep, pos, dir);
     147             : 
     148           3 : }
     149           0 : VisBufferUtil::VisBufferUtil(const vi::VisibilityIterator2& iter): oldMSId_p(-1) {
     150             : 
     151           0 :         MSColumns msc(iter.ms());
     152             :   // The nominal epoch
     153           0 :   MEpoch ep=msc.timeMeas()(0);
     154             : 
     155             :   // The nominal position
     156           0 :   String observatory;
     157           0 :   MPosition pos;
     158           0 :   if (msc.observation().nrow() > 0) {
     159           0 :     observatory = msc.observation().telescopeName()
     160           0 :       (msc.observationId()(0));
     161             :   }
     162           0 :   if (observatory.length() == 0 ||
     163           0 :       !MeasTable::Observatory(pos,observatory)) {
     164             :     // unknown observatory, use first antenna
     165           0 :     pos=msc.antenna().positionMeas()(0);
     166             :   }
     167             : 
     168             :   // The nominal direction
     169             :   //MDirection dir=iter.phaseCenter();
     170           0 :   MDirection dir=msc.field().phaseDirMeasCol()(0)(IPosition(1,0));
     171             :   // The nominal MeasFrame
     172           0 :   mframe_=MeasFrame(ep, pos, dir);
     173             : 
     174           0 : }
     175           0 : VisBufferUtil::VisBufferUtil(const MeasFrame& mframe): oldMSId_p(-1) {
     176           0 :         mframe_=mframe;
     177             : 
     178           0 : }
     179           0 : Bool VisBufferUtil::rotateUVW(const vi::VisBuffer2&vb, const MDirection& desiredDir,
     180             :                                 Matrix<Double>& uvw, Vector<Double>& dphase){
     181             : 
     182           0 :     Bool retval=true;
     183           0 :     mframe_.resetEpoch(vb.time()(0));
     184           0 :     UVWMachine uvwMachine(desiredDir, vb.phaseCenter(), mframe_,
     185           0 :                         false, false);
     186           0 :     retval = !uvwMachine.isNOP();
     187           0 :     dphase.resize(vb.nRows());
     188           0 :     dphase.set(0.0);
     189           0 :     if(uvw.nelements() ==0)
     190           0 :       uvw=vb.uvw();
     191           0 :     for (rownr_t row=0; row< vb.nRows(); ++row){
     192           0 :       Vector<Double> eluvw(uvw.column(row));
     193           0 :       uvwMachine.convertUVW(dphase(row), eluvw);
     194           0 :     }
     195             : 
     196           0 :     return retval;
     197           0 :   }
     198             : 
     199             : // Set the visibility buffer for a PSF
     200           0 : void VisBufferUtil::makePSFVisBuffer(VisBuffer& vb) {
     201           0 :   CStokesVector coh(Complex(1.0), Complex(0.0), Complex(0.0), Complex(1.0));
     202           0 :   vb.correctedVisibility()=coh;
     203           0 : }
     204             : 
     205             : 
     206           0 : Bool VisBufferUtil::interpolateFrequency(Cube<Complex>& data,
     207             :                                          Cube<Bool>& flag,
     208             :                                          const VisBuffer& vb,
     209             :                                          const Vector<Float>& outFreqGrid,
     210             :                                          const MS::PredefinedColumns whichCol,
     211             :                                          const MFrequency::Types freqFrame,
     212             :                                          const InterpolateArray1D<Float,Complex>::InterpolationMethod interpMethod){
     213             : 
     214           0 :   Cube<Complex> origdata;
     215             :   // Convert the visibility frequency to the frame requested
     216           0 :   Vector<Double> visFreqD;
     217           0 :   convertFrequency(visFreqD, vb, freqFrame);
     218             :   //convert it to Float
     219           0 :   Vector<Float> visFreq(visFreqD.nelements());
     220           0 :   convertArray(visFreq, visFreqD);
     221             : 
     222             :   //Assign which column is to be regridded to origdata
     223           0 :   if(whichCol==MS::MODEL_DATA){
     224           0 :     origdata.reference(vb.modelVisCube());
     225             :   }
     226           0 :   else if(whichCol==MS::CORRECTED_DATA){
     227           0 :       origdata.reference(vb.correctedVisCube());
     228             :     }
     229           0 :   else if(whichCol==MS::DATA){
     230           0 :       origdata.reference(vb.visCube());
     231             :   }
     232             :   else{
     233           0 :     throw(AipsError("Don't know which column is being regridded"));
     234             :   }
     235           0 :   Cube<Complex> flipdata;
     236           0 :   Cube<Bool> flipflag;
     237             :   //The interpolator interpolates on the 3rd axis only...so need to flip the axes (y,z)
     238           0 :   swapyz(flipflag,vb.flagCube());
     239           0 :   swapyz(flipdata,origdata);
     240             : 
     241             :   //interpolate the data and the flag to the output frequency grid
     242             :   InterpolateArray1D<Float,Complex>::
     243           0 :     interpolate(data,flag, outFreqGrid,visFreq,flipdata,flipflag,interpMethod);
     244           0 :   flipdata.resize();
     245             :   //reflip the data and flag to be in the same order as in Visbuffer output
     246           0 :   swapyz(flipdata,data);
     247           0 :   data.resize();
     248           0 :   data.reference(flipdata);
     249           0 :   flipflag.resize();
     250           0 :   swapyz(flipflag,flag);
     251           0 :   flag.resize();
     252           0 :   flag.reference(flipflag);
     253             : 
     254           0 :   return true;
     255             : 
     256           0 : }
     257           0 :   void VisBufferUtil::getFreqRange(Double& freqMin, Double& freqMax, vi::VisibilityIterator2& vi, MFrequency::Types freqFrame){
     258           0 :     vi.originChunks();
     259           0 :     vi.origin();
     260             : 
     261           0 :     Double freqEnd=0.0;
     262           0 :     Double freqStart=C::dbl_max;
     263           0 :     vi::VisBuffer2* vb=vi.getVisBuffer();
     264           0 :     for (vi.originChunks(); vi.moreChunks();vi.nextChunk())
     265             :         {
     266           0 :           for (vi.origin(); vi.more();vi.next())
     267             :                 {
     268             :                   Double localmax, localmin;
     269           0 :                   IPosition localmaxpos(1,0);
     270           0 :                   IPosition localminpos(1,0);
     271           0 :                   Vector<Double> freqs=vb->getFrequencies(0, freqFrame);
     272           0 :                   if(freqs.nelements() ==0){
     273           0 :                     throw(AipsError("Frequency selection error" ));
     274             :                   }
     275           0 :                   minMax(localmin,localmax,localminpos, localmaxpos, freqs);
     276             :                   //localmax=max(freqs);
     277             :                   //localmin=min(freqs);
     278             :                   //freqEnd=max(freqEnd, localmax);
     279             :                   //freqStart=min(freqStart, localmin);
     280             : 
     281           0 :                   Int nfreq = freqs.nelements();
     282           0 :                   Vector<Int> curspws = vb->spectralWindows();
     283             :                   // as the vb row 0 is used for getFrequencies, the same row 0 is used here
     284           0 :                   Vector<Double> chanWidths = vi.subtableColumns().spectralWindow().chanWidth()(curspws[0]);
     285             :                   // freqs are in channel center freq so add the half the width to the values to return the edge frequencies
     286           0 :                   if (nfreq==1) {
     287           0 :                     freqEnd=max(freqEnd, localmax+fabs(chanWidths[0]/2.0));
     288           0 :                     freqStart=min(freqStart, localmin-fabs(chanWidths[0]/2.0));
     289             :                   }
     290             :                   else {
     291           0 :                     freqEnd=max(freqEnd, localmax+fabs(chanWidths[localmaxpos[0]]/2.0));
     292           0 :                     freqStart=min(freqStart, localmin-fabs(chanWidths[localminpos[0]]/2.0));
     293             :                   }
     294             : 
     295           0 :                 }
     296             :         }
     297           0 :     freqMin=freqStart;
     298           0 :     freqMax=freqEnd;
     299           0 :   }
     300             : 
     301           0 :   Bool VisBufferUtil::getFreqRangeFromRange(casacore::Double& outfreqMin, casacore::Double& outfreqMax,  const casacore::MFrequency::Types inFreqFrame, const casacore::Double infreqMin, const casacore::Double infreqMax, vi::VisibilityIterator2& vi, casacore::MFrequency::Types outFreqFrame){
     302             : 
     303             : 
     304           0 :     if(inFreqFrame==outFreqFrame){
     305           0 :       outfreqMin=infreqMin;
     306           0 :       outfreqMax=infreqMax;
     307           0 :       return True;
     308             :     }
     309             : 
     310             : 
     311           0 :     vi.originChunks();
     312           0 :     vi.origin();
     313             :     try{
     314           0 :       outfreqMin=C::dbl_max;
     315           0 :       outfreqMax=0;
     316           0 :       vi::VisBuffer2* vb=vi.getVisBuffer();
     317           0 :       MSColumns msc(vi.ms());
     318             :       // The nominal epoch
     319           0 :       MEpoch ep=msc.timeMeas()(0);
     320             : 
     321             :       // The nominal position
     322           0 :       String observatory;
     323           0 :       MPosition pos;
     324           0 :       if (msc.observation().nrow() > 0) {
     325           0 :         observatory = msc.observation().telescopeName()
     326           0 :           (msc.observationId()(0));
     327             :       }
     328           0 :       if (observatory.length() == 0 ||
     329           0 :           !MeasTable::Observatory(pos,observatory)) {
     330             :         // unknown observatory, use first antenna
     331           0 :         pos=msc.antenna().positionMeas()(0);
     332             :       }
     333             : 
     334             :       // The nominal direction
     335           0 :       MDirection dir=vb->phaseCenter();
     336           0 :       MeasFrame mFrame(ep, pos, dir);
     337             :       // The conversion engine:
     338             :       MFrequency::Convert toNewFrame(inFreqFrame,
     339           0 :                                      MFrequency::Ref(outFreqFrame, mFrame));
     340             : 
     341           0 :       for (vi.originChunks(); vi.moreChunks();vi.nextChunk())
     342             :         {
     343           0 :           for (vi.origin(); vi.more();vi.next()){
     344             :             //assuming time is fixed in visbuffer
     345           0 :             mFrame.resetEpoch(vb->time()(0)/86400.0);
     346             : 
     347             :             // Reset the direction (ASSUMES phaseCenter is constant in the VisBuffer)
     348           0 :             mFrame.resetDirection(vb->phaseCenter());
     349           0 :             Double temp=toNewFrame(infreqMin).getValue().getValue();
     350           0 :             if(temp < outfreqMin)
     351           0 :               outfreqMin = temp;
     352             : 
     353           0 :             temp=toNewFrame(infreqMax).getValue().getValue();
     354           0 :             if(temp > outfreqMax)
     355           0 :               outfreqMax = temp;
     356             :           }
     357             :         }
     358           0 :     }
     359           0 :     catch(...){
     360             :       //Could not do a conversion
     361           0 :       return False;
     362             : 
     363           0 :     }
     364             :       //cerr << "min " << outfreqMin << " max " << outfreqMax << endl;
     365           0 :       return True;
     366             : 
     367             :   }
     368             : 
     369           0 : void VisBufferUtil::convertFrequency(Vector<Double>& outFreq,
     370             :                                      const VisBuffer& vb,
     371             :                                      const MFrequency::Types freqFrame){
     372           0 :    Int spw=vb.spectralWindow();
     373           0 :    MFrequency::Types obsMFreqType=(MFrequency::Types)(vb.msColumns().spectralWindow().measFreqRef()(spw));
     374             : 
     375             :    // The input frequencies (a reference)
     376           0 :    Vector<Double> inFreq(vb.frequency());
     377             : 
     378             :    // The output frequencies
     379           0 :    outFreq.resize(inFreq.nelements());
     380             : 
     381           0 :    MFrequency::Types newMFreqType=freqFrame;
     382           0 :    if (freqFrame==MFrequency::N_Types)
     383             :      // Opt out of conversion
     384           0 :      newMFreqType=obsMFreqType;
     385             : 
     386             : 
     387             :    // Only convert if the requested frame differs from observed frame
     388           0 :    if(obsMFreqType != newMFreqType){
     389             : 
     390             :      // Setting epoch to the first in this iteration
     391             :      //     MEpoch ep=vb.msColumns().timeMeas()(0);
     392             :      //     MEpoch ep(MVEpoch(vb.time()(0)/86400.0),MEpoch::UTC);
     393             :      //     cout << "Time = " << ep.getValue()  << endl;
     394             : 
     395             :      // Reset the timestamp (ASSUMES TIME is constant in the VisBuffer)
     396           0 :      mframe_.resetEpoch(vb.time()(0)/86400.0);
     397             : 
     398             :      // Reset the direction (ASSUMES phaseCenter is constant in the VisBuffer)
     399           0 :      mframe_.resetDirection(vb.msColumns().field().phaseDirMeasCol()(vb.fieldId())(IPosition(1,0)));
     400             : 
     401             :      //     cout << "Frame = " << mframe_ << endl;
     402             : 
     403             :      // The conversion engine:
     404             :      MFrequency::Convert toNewFrame(obsMFreqType,
     405           0 :                                     MFrequency::Ref(newMFreqType, mframe_));
     406             : 
     407             :      // Do the conversion
     408           0 :      for (uInt k=0; k< inFreq.nelements(); ++k)
     409           0 :        outFreq(k)=toNewFrame(inFreq(k)).getValue().getValue();
     410             : 
     411           0 :    }
     412             :    else{
     413             :      // The requested frame is the same as the observed frame
     414           0 :      outFreq=inFreq;
     415             :    }
     416             : 
     417           0 :  }
     418             : 
     419           0 : void VisBufferUtil::convertFrequency(Vector<Double>& outFreq,
     420             :                                      const vi::VisBuffer2& vb,
     421             :                                      const MFrequency::Types freqFrame){
     422           0 :   Int spw=vb.spectralWindows()(0);
     423           0 :   MFrequency::Types obsMFreqType=(MFrequency::Types)(MSColumns(vb.ms()).spectralWindow().measFreqRef()(spw));
     424             : 
     425             : 
     426             : 
     427             :    // The input frequencies
     428           0 :   Vector<Int> chanNums=vb.getChannelNumbers(0);
     429             : 
     430           0 :   Vector<Double> inFreq(chanNums.nelements());
     431           0 :   Vector<Double> spwfreqs=MSColumns(vb.ms()).spectralWindow().chanFreq().get(spw);
     432           0 :   for (uInt k=0; k < chanNums.nelements(); ++k){
     433             : 
     434           0 :     inFreq[k]=spwfreqs[chanNums[k]];
     435             :   }
     436             : 
     437             :    // The output frequencies
     438           0 :    outFreq.resize(inFreq.nelements());
     439             : 
     440           0 :    MFrequency::Types newMFreqType=freqFrame;
     441           0 :    if (freqFrame==MFrequency::N_Types)
     442             :      // Opt out of conversion
     443           0 :      newMFreqType=obsMFreqType;
     444             : 
     445             : 
     446             :    // Only convert if the requested frame differs from observed frame
     447           0 :    if(obsMFreqType != newMFreqType){
     448             : 
     449             :      // Setting epoch to the first in this iteration
     450             :      //     MEpoch ep=vb.msColumns().timeMeas()(0);
     451             :      //     MEpoch ep(MVEpoch(vb.time()(0)/86400.0),MEpoch::UTC);
     452             :      //     cout << "Time = " << ep.getValue()  << endl;
     453             : 
     454             :      // Reset the timestamp (ASSUMES TIME is constant in the VisBuffer)
     455           0 :      mframe_.resetEpoch(vb.time()(0)/86400.0);
     456             : 
     457             :      // Reset the direction (ASSUMES phaseCenter is constant in the VisBuffer)
     458           0 :      mframe_.resetDirection(vb.phaseCenter());
     459             : 
     460             :      //     cout << "Frame = " << mframe_ << endl;
     461             : 
     462             :      // The conversion engine:
     463             :      MFrequency::Convert toNewFrame(obsMFreqType,
     464           0 :                                     MFrequency::Ref(newMFreqType, mframe_));
     465             : 
     466             :      // Do the conversion
     467           0 :      for (uInt k=0; k< inFreq.nelements(); ++k)
     468           0 :        outFreq(k)=toNewFrame(inFreq(k)).getValue().getValue();
     469             : 
     470           0 :    }
     471             :    else{
     472             :      // The requested frame is the same as the observed frame
     473           0 :      outFreq=inFreq;
     474             :    }
     475             : 
     476             :    //cerr << std::setprecision(9) << " infreq " << inFreq[152] << "   " << outFreq[152] << " vb freq " << vb.getFrequencies(0, freqFrame)[152] << endl;
     477             : 
     478           0 :  }
     479             : 
     480           0 :  void VisBufferUtil::toVelocity(Vector<Double>& outVel,
     481             :                                 const VisBuffer& vb,
     482             :                                 const MFrequency::Types freqFrame,
     483             :                                 const MVFrequency restFreq,
     484             :                                 const MDoppler::Types veldef){
     485             : 
     486             :    // The input frequencies (a reference)
     487           0 :    Vector<Double> inFreq(vb.frequency());
     488             : 
     489             :    // The output velocities
     490           0 :    outVel.resize(inFreq.nelements());
     491             : 
     492             :    // Reset the timestamp (ASSUMES TIME is constant in the VisBuffer)
     493           0 :    mframe_.resetEpoch(vb.time()(0)/86400.0);
     494             : 
     495             :    // Reset the direction (ASSUMES phaseCenter is constant in the VisBuffer)
     496             :    //mframe_.resetDirection(vb.phaseCenter());
     497           0 :    mframe_.resetDirection(vb.msColumns().field().phaseDirMeasCol()(vb.fieldId())(IPosition(1,0)));
     498             : 
     499             :    // The frequency conversion engine:
     500           0 :    Int spw=vb.spectralWindow();
     501           0 :    MFrequency::Types obsMFreqType=(MFrequency::Types)(vb.msColumns().spectralWindow().measFreqRef()(spw));
     502             : 
     503           0 :    MFrequency::Types newMFreqType=freqFrame;
     504           0 :    if (freqFrame==MFrequency::N_Types)
     505             :      // Don't convert frame
     506           0 :      newMFreqType=obsMFreqType;
     507             : 
     508             :    MFrequency::Convert toNewFrame(obsMFreqType,
     509           0 :                                   MFrequency::Ref(newMFreqType, mframe_));
     510             : 
     511             :    // The velocity conversion engine:
     512           0 :    MDoppler::Ref dum1(MDoppler::RELATIVISTIC);
     513           0 :    MDoppler::Ref dum2(veldef);
     514           0 :    MDoppler::Convert dopConv(dum1, dum2);
     515             : 
     516             :    // Cope with unspecified rest freq
     517           0 :    MVFrequency rf=restFreq;
     518           0 :    if (restFreq.getValue()<=0.0)
     519           0 :      rf=toNewFrame(inFreq(vb.nChannel()/2)).getValue();
     520             : 
     521             :    // Do the conversions
     522           0 :    for (uInt k=0; k< inFreq.nelements(); ++k){
     523             :          //cerr <<"old freq " << toNewFrame(inFreq(k)).getValue().get().getValue() << endl;
     524           0 :      MDoppler eh = toNewFrame(inFreq(k)).toDoppler(rf);
     525           0 :      MDoppler eh2 = dopConv(eh);
     526           0 :      outVel(k)=eh2.getValue().get().getValue();
     527           0 :    }
     528             : 
     529           0 :  }
     530             : 
     531           0 :  void VisBufferUtil::toVelocity(Vector<Double>& outVel,
     532             :                                 const vi::VisBuffer2& vb,
     533             :                                 const MFrequency::Types freqFrame,
     534             :                                 const MVFrequency restFreq,
     535             :                                 const MDoppler::Types veldef, const Int row){
     536             : 
     537           0 :                  Vector<Double> inFreq;
     538           0 :                  inFreq=vb.getFrequencies(row, freqFrame);
     539             :                 // cerr << "Freqs " << inFreq << endl;
     540             :                 // The output velocities
     541           0 :                  outVel.resize(inFreq.nelements());
     542             :                  // The velocity conversion engine:
     543           0 :                  MDoppler::Ref dum1(MDoppler::RELATIVISTIC);
     544           0 :                  MDoppler::Ref dum2(veldef);
     545           0 :                  MDoppler::Convert dopConv(dum1, dum2);
     546             : 
     547             :                  // Cope with unspecified rest freq
     548           0 :                  MVFrequency rf=restFreq;
     549           0 :                  if (restFreq.getValue()<=0.0)
     550           0 :                       rf=inFreq(inFreq.nelements()/2);
     551             : 
     552             :                  // Do the conversions
     553           0 :                  for (uInt k=0; k< inFreq.nelements(); ++k){
     554           0 :                          MDoppler eh = MFrequency(Quantity(inFreq(k), "Hz"), freqFrame).toDoppler(rf);
     555           0 :                          MDoppler eh2 = dopConv(eh);
     556           0 :                          outVel(k)=eh2.getValue().get().getValue();
     557           0 :                         }
     558             : 
     559             : 
     560           0 :  }
     561           0 :  void VisBufferUtil::toVelocity(Vector<Double>& outVel,
     562             :                                 const vi::VisBuffer2& vb,
     563             :                                 const vi::VisibilityIterator2& iter,
     564             :                                 const MFrequency::Types freqFrame,
     565             :                                 const MVFrequency restFreq,
     566             :                                 const MDoppler::Types veldef, const Int row){
     567             : 
     568             :          // The input frequencies (a reference)
     569           0 :          Vector<Double> inFreq(vb.getFrequencies(row));
     570           0 :          MSColumns msc(iter.ms());
     571             : 
     572           0 :      MEpoch ep(Quantity(vb.time()(row)/86400.0, "d"), msc.timeMeas()(0).getRef());
     573           0 :          MDirection dir(msc.field().phaseDirMeasCol()(vb.fieldId()(row))(IPosition(1,0)));
     574           0 :          Int spw=vb.spectralWindows()(row);
     575           0 :          MFrequency::Types obsMFreqType=(MFrequency::Types)(msc.spectralWindow().measFreqRef()(spw));
     576           0 :          toVelocity(outVel, freqFrame, inFreq, obsMFreqType, ep, dir, restFreq, veldef);
     577           0 :   }
     578           0 :  void VisBufferUtil::toVelocity(Vector<Double>& outVel,
     579             :                   const MFrequency::Types outFreqFrame,
     580             :                   const Vector<Double>& inFreq,
     581             :                   const MFrequency::Types inFreqFrame,
     582             :                   const MEpoch& ep,
     583             :                   const MDirection& dir,
     584             :                   const MVFrequency restFreq,
     585             :                   const MDoppler::Types veldef){
     586             : 
     587             : 
     588             : 
     589             :          // The output velocities
     590           0 :          outVel.resize(inFreq.nelements());
     591             : 
     592             :          // Reset the timestamp
     593           0 :          mframe_.resetEpoch(ep);
     594             : 
     595             :          // Reset the direction
     596           0 :          mframe_.resetDirection(dir);
     597             : 
     598             :          // The frequency conversion engine:
     599             : 
     600           0 :          MFrequency::Types newMFreqType=outFreqFrame;
     601           0 :          if (outFreqFrame==MFrequency::N_Types)
     602             :                  // Don't convert frame
     603           0 :                  newMFreqType=inFreqFrame;
     604             : 
     605             :          MFrequency::Convert toNewFrame(inFreqFrame,
     606           0 :                                           MFrequency::Ref(newMFreqType, mframe_));
     607             : 
     608             :          // The velocity conversion engine:
     609           0 :          MDoppler::Ref dum1(MDoppler::RELATIVISTIC);
     610           0 :          MDoppler::Ref dum2(veldef);
     611           0 :          MDoppler::Convert dopConv(dum1, dum2);
     612             : 
     613             :          // Cope with unspecified rest freq
     614           0 :          MVFrequency rf=restFreq;
     615           0 :          if (restFreq.getValue()<=0.0)
     616           0 :               rf=toNewFrame(inFreq(inFreq.nelements()/2)).getValue();
     617             : 
     618             :          // Do the conversions
     619           0 :          for (uInt k=0; k< inFreq.nelements(); ++k){
     620           0 :                  MDoppler eh = toNewFrame(inFreq(k)).toDoppler(rf);
     621           0 :                  MDoppler eh2 = dopConv(eh);
     622           0 :                  outVel(k)=eh2.getValue().get().getValue();
     623           0 :                 }
     624             : 
     625             : 
     626             : 
     627             : 
     628           0 :  }
     629             : 
     630           0 :  MDirection VisBufferUtil::getPointingDir(const VisBuffer& vb, const Int antid, const Int vbrow){
     631             : 
     632           0 :    Timer tim;
     633           0 :    tim.mark();
     634           0 :    const MSColumns& msc=vb.msColumns();
     635             :    //cerr << "oldMSId_p " << oldMSId_p << " vb " <<  vb.msId() << endl;
     636           0 :    if(vb.msId() < 0)
     637           0 :      throw(AipsError("VisBuffer is not attached to an ms so cannot get pointing "));
     638           0 :    if(oldMSId_p != vb.msId()){
     639           0 :      oldMSId_p=vb.msId();
     640           0 :      if(timeAntIndex_p.shape()(0) < (oldMSId_p+1)){
     641           0 :        timeAntIndex_p.resize(oldMSId_p+1, true);
     642           0 :        cachedPointingDir_p.resize(oldMSId_p+1, true);
     643             :      }
     644           0 :      if(  timeAntIndex_p[oldMSId_p].empty()){
     645           0 :        Vector<Double> tOrig;
     646           0 :        msc.time().getColumn(tOrig);
     647           0 :        Vector<Double> t;
     648           0 :        rejectConsecutive(tOrig, t);
     649           0 :        Vector<uInt>  uniqIndx;
     650           0 :        uInt nTimes=GenSortIndirect<Double>::sort (uniqIndx, t, Sort::Ascending, Sort::QuickSort|Sort::NoDuplicates);
     651           0 :        uInt nAnt=msc.antenna().nrow();
     652           0 :        const MSPointingColumns& mspc=msc.pointing();
     653           0 :        Vector<Double> tUniq(nTimes);
     654           0 :        for (uInt k=0; k <nTimes; ++k){
     655           0 :          tUniq[k]= t[uniqIndx[k]];
     656             :        }
     657             :        Bool tstor, timcolstor, intcolstor, antcolstor;
     658           0 :        Double * tuniqptr=tUniq.getStorage(tstor);
     659           0 :        Int cshape=cachedPointingDir_p[oldMSId_p].shape()[0];
     660           0 :        cachedPointingDir_p[oldMSId_p].resize(cshape+nTimes*nAnt, True);
     661           0 :        Vector<Double> timecol;
     662           0 :        Vector<Double> intervalcol;
     663           0 :        Vector<Int> antcol;
     664           0 :        mspc.time().getColumn(timecol, True);
     665           0 :        mspc.interval().getColumn(intervalcol, True);
     666           0 :        mspc.antennaId().getColumn(antcol, True);
     667           0 :        Double *tcolptr=timecol.getStorage(timcolstor);
     668           0 :        Double *intcolptr=intervalcol.getStorage(intcolstor);
     669           0 :        Int * antcolptr=antcol.getStorage(antcolstor);
     670           0 :        Int npointrow=msc.pointing().nrow();
     671           0 : #pragma omp parallel for firstprivate(nTimes, tuniqptr, tcolptr, antcolptr, intcolptr, npointrow), shared(mspc)
     672             :        for (uInt a=0; a < nAnt; ++a){
     673             : 
     674             :          //Double wtime1=omp_get_wtime();
     675             :          Vector<ssize_t> indices;
     676             :          Vector<MDirection> theDirs(nTimes);
     677             :          pointingIndex(tcolptr, antcolptr, intcolptr, npointrow, a, nTimes, tuniqptr, indices);
     678             : 
     679             : #pragma omp critical
     680             :          {
     681             :            for (uInt k=0; k <nTimes; ++k){
     682             : 
     683             : 
     684             :              // std::ostringstream oss;
     685             :              // oss.precision(13);
     686             :              // oss << tuniqptr[k] << "_" << a;
     687             :              // String key=oss.str();
     688             :              std::pair<double, int> key=make_pair(t[uniqIndx[k]],a);
     689             :              timeAntIndex_p[oldMSId_p][key]=indices[k] > -1 ? cshape : -1;
     690             : 
     691             :              if(indices[k] >-1){
     692             : 
     693             :                cachedPointingDir_p[oldMSId_p][cshape]=mspc.directionMeas(indices[k]);
     694             :                cshape+=1;
     695             :              }
     696             : 
     697             : 
     698             :            }
     699             :          }//end critical
     700             : 
     701             : 
     702             :        }
     703             : 
     704           0 :        cachedPointingDir_p[oldMSId_p].resize(cshape, True);
     705           0 :      }
     706             : 
     707             :    }
     708             : 
     709             :    /////
     710             :    //    String index=String::toString(vb.time()(vbrow))+String("_")+String::toString(antid);
     711             :    // std::ostringstream oss;
     712             :    // oss.precision(13);
     713             :    // oss << vb.time()(vbrow) << "_" << antid  ;
     714             :    // String index=oss.str();
     715             :    //cerr << "index "<< index << endl;
     716             :    ////////////
     717             :    /*
     718             :   for (auto it = timeAntIndex_p[oldMSId_p].begin(); it != timeAntIndex_p[oldMSId_p].end();       ++it)
     719             :     {
     720             :       cerr << (*it).first << " --> " << (*it).second << endl;
     721             :     }
     722             :    */
     723             :    /////////////
     724           0 :    std::pair<double, int> index=make_pair(vb.time()(vbrow), antid);
     725           0 :    Int rowincache=timeAntIndex_p[oldMSId_p][index];
     726             :          ///////TESTOO
     727             :          /* if(rowincache>=0){
     728             :            cerr << "msid " << oldMSId_p << " key "<< index << " index " << rowincache<<  "   "  << cachedPointingDir_p[oldMSId_p][rowincache] << endl;
     729             :            }*/
     730             :          /////////////
     731             :          //tim.show("retrieved cache");
     732           0 :    if(rowincache <0)
     733           0 :      return vb.phaseCenter();
     734           0 :    return cachedPointingDir_p[oldMSId_p][rowincache];
     735             : 
     736             :  }
     737           0 :   MDirection VisBufferUtil::getPointingDir(const vi::VisBuffer2& vb, const Int antid, const Int vbrow, const MDirection::Types dirframe, const Bool usePointing){
     738             : 
     739             :     //Double wtime0=omp_get_wtime();
     740           0 :          Int rowincache=-1;
     741           0 :          if(usePointing){
     742           0 :            if(oldMSId_p != vb.msId()){
     743           0 :              MSColumns msc(vb.ms());
     744           0 :              oldMSId_p=vb.msId();
     745           0 :              if(timeAntIndex_p.shape()(0) < (oldMSId_p+1)){
     746           0 :                timeAntIndex_p.resize(oldMSId_p+1, true);
     747           0 :                cachedPointingDir_p.resize(oldMSId_p+1, true);
     748             :              }
     749           0 :              MEpoch::Types timeType=MEpoch::castType(msc.timeMeas()(0).getRef().getType());
     750           0 :              Unit timeUnit(msc.timeMeas().measDesc().getUnits()(0).getName());
     751           0 :              MPosition pos;
     752           0 :              String tel;
     753           0 :              if (vb.subtableColumns().observation().nrow() > 0) {
     754           0 :                tel =vb.subtableColumns().observation().telescopeName()(msc.observationId()(0));
     755             :              }
     756           0 :              if (tel.length() == 0 || !tel.contains("VLA") ||
     757           0 :                  !MeasTable::Observatory(pos,tel)) {
     758             :                // unknown observatory, use first antenna
     759           0 :                Int ant1=vb.antenna1()(0);
     760           0 :                pos=vb.subtableColumns().antenna().positionMeas()(ant1);
     761             :              }
     762           0 :              if(  timeAntIndex_p[oldMSId_p].empty()){
     763           0 :                Vector<Double> tOrig;
     764           0 :                msc.time().getColumn(tOrig);
     765           0 :                Vector<Double> t;
     766           0 :                rejectConsecutive(tOrig, t);
     767           0 :                Vector<uInt>  uniqIndx;
     768           0 :                uInt nTimes=GenSortIndirect<Double>::sort (uniqIndx, t, Sort::Ascending, Sort::QuickSort|Sort::NoDuplicates);
     769           0 :                uInt nAnt=msc.antenna().nrow();
     770           0 :                          const MSPointingColumns& mspc=msc.pointing();
     771           0 :                          Vector<Double> tUniq(nTimes);
     772           0 :                          for (uInt k=0; k <nTimes; ++k){
     773           0 :                            tUniq[k]= t[uniqIndx[k]];
     774             :                          }
     775             :                          Bool tstor, timcolstor, intcolstor, antcolstor;
     776           0 :                          Double * tuniqptr=tUniq.getStorage(tstor);
     777           0 :                          Int cshape=cachedPointingDir_p[oldMSId_p].shape()[0];
     778           0 :                          cachedPointingDir_p[oldMSId_p].resize(cshape+nTimes*nAnt, True);
     779           0 :                          Vector<Double> timecol;
     780           0 :                          Vector<Double> intervalcol;
     781           0 :                          Vector<Int> antcol;
     782           0 :                          mspc.time().getColumn(timecol, True);
     783           0 :                          mspc.interval().getColumn(intervalcol, True);
     784           0 :                          mspc.antennaId().getColumn(antcol, True);
     785           0 :                          Double *tcolptr=timecol.getStorage(timcolstor);
     786           0 :                          Double *intcolptr=intervalcol.getStorage(intcolstor);
     787           0 :                          Int * antcolptr=antcol.getStorage(antcolstor);
     788           0 :                          Int npointrow=vb.ms().pointing().nrow();
     789             :                          //ofstream myfile;
     790             :                          //myfile.open ("POINTING.txt", ios::trunc);
     791           0 : #pragma omp parallel for firstprivate(nTimes, tuniqptr, tcolptr, antcolptr, intcolptr, npointrow, timeType, timeUnit, pos, dirframe), shared(mspc)
     792             :                          for (uInt a=0; a < nAnt; ++a){
     793             : 
     794             :                            //Double wtime1=omp_get_wtime();
     795             :                            Vector<ssize_t> indices;
     796             :                            //Vector<MDirection> theDirs(nTimes);
     797             :                            pointingIndex(tcolptr, antcolptr, intcolptr, npointrow, a, nTimes, tuniqptr, indices);
     798             : 
     799             : #pragma omp critical
     800             :                            {
     801             :                              MEpoch timenow(Quantity(tuniqptr[0], timeUnit),timeType);
     802             :                              MeasFrame mframe(timenow, pos);
     803             :                              MDirection::Convert cvt(MDirection(), MDirection::Ref(dirframe, mframe));
     804             :                              for (uInt k=0; k <nTimes; ++k){
     805             : 
     806             : 
     807             :                                /*std::ostringstream oss;
     808             :                                oss.precision(13);
     809             :                                oss << tuniqptr[k] << "_" << a;
     810             :                                String key=oss.str();
     811             :                                */
     812             :                                //                              myfile <<std::setprecision(13) <<  tuniqptr[k] << "_" << a << " index "<<  indices[k] << "\n";
     813             :                                pair<double, int> key=make_pair(tuniqptr[k],a);
     814             :                                timeAntIndex_p[oldMSId_p][key]=indices[k] > -1 ? cshape : -1;
     815             : 
     816             :                                if(indices[k] >-1){
     817             :                                  timenow=MEpoch(Quantity(tuniqptr[k], timeUnit),timeType);
     818             :                                  mframe.resetEpoch(timenow);
     819             :                                  cachedPointingDir_p[oldMSId_p][cshape]=cvt(mspc.directionMeas(indices[k]));
     820             : 
     821             :                                  cshape+=1;
     822             :                                }
     823             : 
     824             : 
     825             :                              }
     826             :                            }//end critical
     827             : 
     828             : 
     829             :                          }
     830           0 :                          cachedPointingDir_p[oldMSId_p].resize(cshape, True);
     831           0 :              }
     832             : 
     833           0 :            }
     834             : 
     835             :            /////
     836             :            //    String index=String::toString(vb.time()(vbrow))+String("_")+String::toString(antid);
     837             :            /* std::ostringstream oss;
     838             :            oss.precision(13);
     839             :            oss << vb.time()(vbrow) << "_" << antid  ;
     840             :            String index=oss.str();
     841             :            */
     842           0 :            pair<double, int> index=make_pair(vb.time()(vbrow),antid);
     843           0 :            rowincache=timeAntIndex_p[oldMSId_p].at(index);
     844             : 
     845             :          //tim.show("retrieved cache");
     846             :          }///if usepointing
     847           0 :          if(rowincache <0)
     848           0 :            return getPhaseCenter(vb);
     849           0 :          return cachedPointingDir_p[oldMSId_p][rowincache];
     850             : 
     851             : 
     852             : 
     853             :  }
     854             : 
     855           0 :   void VisBufferUtil::pointingIndex(Double*& timecol, Int*& antcol, Double*& intervalcol, const rownr_t nrow,  const Int ant, const Int ntimes, Double*& ptime, Vector<ssize_t>& indices){
     856             : 
     857           0 :     indices.resize(ntimes);
     858             : 
     859           0 :     indices.set(-1);
     860             : 
     861           0 :     for(Int pt=0; pt < ntimes; ++pt){
     862             :       //cerr << "  " << guessRow ;
     863             : 
     864             :       /*for (Int k=0; k< 2; ++k){
     865             :         Int start=guessRow;
     866             :         Int end=nrow;
     867             :         if(k==1){
     868             :           start=0;
     869             :           end=guessRow;
     870             :         }
     871             :       */
     872           0 :       Double nearval=1e99;
     873           0 :       ssize_t nearestIndx=-1;
     874           0 :       ssize_t start=0;
     875           0 :       ssize_t end=nrow;
     876           0 :       for (ssize_t i=start; i<end; i++) {
     877           0 :         if(intervalcol[i]<=0.0 && ant==antcol[i]){
     878           0 :           if(abs(timecol[i]-ptime[pt]) < nearval){
     879           0 :             nearestIndx=i;
     880           0 :             nearval=abs(timecol[i]-ptime[pt]);
     881             :           }
     882             :         }
     883             :       }
     884           0 :       indices[pt]=nearestIndx;
     885             : 
     886             : 
     887           0 :       for (ssize_t i=start; i<end; i++) {
     888           0 :           if(ant == antcol[i]){
     889           0 :             Double halfInt=0.0;
     890           0 :             Bool done=False;
     891           0 :             if(intervalcol[i]<=0.0){
     892             :             //  if(abs(timecol[inx[i]]-ptime[pt]) < nearval){
     893             :             //  nearestIndx=inx[i];
     894             :             //  }
     895           0 :               ssize_t counter=0;
     896           0 :               ssize_t adder=1;
     897           0 :               done=False;
     898             :                 //            while(!( (timecol[i+counter]!=timecol[i]))){
     899           0 :               while(!done){
     900           0 :                 counter=counter+adder;
     901           0 :                 if((ssize_t)nrow <= i+counter){
     902           0 :                   adder=-1;
     903           0 :                   counter=0;
     904             :                 }
     905             :                 ////Could not find another point (interval is infinite)  hence only 1 valid point
     906           0 :                 if( (i+counter) < 0){
     907           0 :                   cerr << "HIT BREAK " << endl;
     908           0 :                   indices[pt]=i;
     909           0 :                   break;
     910             :                 }
     911           0 :                 if( (antcol[i+counter]==ant && timecol[i+counter] != timecol[i]) ){
     912           0 :                   done=True;
     913             :                 }
     914             :               }
     915             : 
     916             :               //if(ant==12 && abs(timecol[i+counter]-timecol[i]) > 10.0){
     917             :               //cerr << "i " << i << "  counter " << counter << " done " << done << " adder " << adder << "ant count "<< antcol[i+counter] << "  diff " <<   abs(timecol[i+counter]-timecol[i]) << endl;
     918             :               // }
     919           0 :               halfInt = abs(timecol[i+counter]-timecol[i])/2.0;
     920             :             }
     921             :             else{
     922           0 :               halfInt = intervalcol[i]/2.0;
     923             :             }
     924           0 :             if (halfInt>0.0) {
     925             : 
     926           0 :               if ((timecol[i] >= (ptime[pt] - halfInt)) && (timecol[i] <= (ptime[pt] + halfInt))) {
     927             :                 ////TESTOO
     928             :                 //if(ant==12){
     929             :                 //  cerr << "timecol " << timecol[i] << " halfInt " << halfInt << " TEST " << timecol[nearestIndx] << " inx " << i << "   " << nearestIndx << endl;
     930             :                 //}
     931           0 :                 indices[pt]=abs(timecol[i]-ptime[pt]) <  nearval ? i : nearestIndx;
     932             :                 ////////TESTOO
     933           0 :                 if(indices[pt] > 4688000){
     934           0 :                   cerr <<  indices[pt] << " timecol " << timecol[i] << " halfInt " << halfInt << " TEST " << timecol[nearestIndx] << "  nearval " << nearval << " inx " << i << "   " << nearestIndx << endl;
     935             : 
     936             :                 }
     937             :                 ///////////////////
     938           0 :               break;
     939             :               }
     940             :             } else {
     941             :               // valid for all times (we should also handle interval<0 -> timestamps)
     942           0 :               cerr << "JUMPY " << i << " ant " << ant << " halfint " << halfInt << " done "<< done <<  endl;
     943           0 :               indices[pt]=i;
     944           0 :               break;
     945             :             }
     946             : 
     947             :           }//if ant
     948             :         }//start end
     949             : 
     950             :         //}//k
     951             : 
     952             :     }//pt
     953             : 
     954             :     //cerr << "ant " << ant << " indices " << indices << endl;
     955           0 :   }
     956             : 
     957        1212 :    MDirection VisBufferUtil::getPhaseCenter(const vi::VisBuffer2& vb, const Double timeo){
     958             :      //Timer tim;
     959             : 
     960        1212 :      Double timeph = timeo > 0.0 ? timeo : vb.time()(0);
     961             :          //MDirection outdir;
     962        1212 :          if(oldPCMSId_p != vb.msId()){
     963           3 :            MSColumns msc(vb.ms());
     964             :            //tim.mark();
     965             :            //cerr << "MSID: "<< oldPCMSId_p <<  "    " << vb.msId() << endl;
     966           3 :            oldPCMSId_p=vb.msId();
     967           3 :            if(cachedPhaseCenter_p.shape()(0) < (oldPCMSId_p+1)){
     968           3 :              cachedPhaseCenter_p.resize(oldPCMSId_p+1, true);
     969           3 :              cachedPhaseCenter_p[oldPCMSId_p]=map<Double, MDirection>();
     970             :            }
     971           3 :            if( cachedPhaseCenter_p[oldPCMSId_p].empty()){
     972           3 :                    Vector<Double> tOrig;
     973           3 :                    msc.time().getColumn(tOrig);
     974           3 :                    Vector<Int> fieldId;
     975           3 :                    msc.fieldId().getColumn(fieldId);
     976           3 :                    Vector<Double> t;
     977           3 :                    Vector<Int> origindx;
     978           3 :                    rejectConsecutive(tOrig, t, origindx);
     979           3 :                    Vector<uInt>  uniqIndx;
     980             : 
     981           3 :                    uInt nTimes=GenSortIndirect<Double>::sort (uniqIndx, t, Sort::Ascending, Sort::QuickSort|Sort::NoDuplicates);
     982             :                    //cerr << "ntimes " << nTimes << "  " << uniqIndx  << "\n  origInx " << origindx << endl;
     983           3 :                    const MSFieldColumns& msfc=msc.field();
     984         603 :                    for (uInt k=0; k <nTimes; ++k){
     985             :                      //cerr << t[uniqIndx[k]] << "   " <<  fieldId[origindx[uniqIndx[k]]] << endl;
     986             :                      //cerr << msfc.phaseDirMeas(fieldId[origindx[uniqIndx[k]]], t[uniqIndx[k]]) << endl;
     987             :                      //cerr << "size " <<  cachedPhaseCenter_p[oldPCMSId_p].size() << endl;
     988         600 :                      String ephemIfAny=msfc.ephemPath(fieldId[origindx[uniqIndx[k]]]);
     989         600 :                      if(ephemIfAny=="" || !Table::isReadable(ephemIfAny, False)){
     990         600 :                        (cachedPhaseCenter_p[oldPCMSId_p])[t[uniqIndx[k]]]=msfc.phaseDirMeas(fieldId[origindx[uniqIndx[k]]], t[uniqIndx[k]]);
     991             :                      }
     992             :                      else{
     993           0 :                        Vector<MDirection> refDir(msfc.referenceDirMeasCol()(fieldId[origindx[uniqIndx[k]]]));
     994           0 :                        (cachedPhaseCenter_p[oldPCMSId_p])[t[uniqIndx[k]]]=getEphemBasedPhaseDir(vb, ephemIfAny, refDir(0),   t[uniqIndx[k]]);
     995           0 :                      }
     996             : 
     997         600 :                    }
     998             : 
     999             : 
    1000           3 :            }
    1001             :            //tim.show("After caching all phasecenters");
    1002           3 :          }
    1003             :          //tim.mark();
    1004        1212 :          MDirection retval;
    1005        1212 :          auto it=cachedPhaseCenter_p[oldPCMSId_p].find(timeph);
    1006        1212 :          if(it != cachedPhaseCenter_p[oldPCMSId_p].end()){
    1007        1212 :            retval=it->second;
    1008             :          }
    1009             :          else{
    1010           0 :            auto upp= cachedPhaseCenter_p[oldPCMSId_p].upper_bound(timeph);
    1011           0 :            auto low= cachedPhaseCenter_p[oldPCMSId_p].lower_bound(timeph);
    1012           0 :            if (upp==cachedPhaseCenter_p[oldPCMSId_p].begin())
    1013           0 :              retval=(cachedPhaseCenter_p[oldPCMSId_p].begin())->second;
    1014           0 :            else if(low==cachedPhaseCenter_p[oldPCMSId_p].end()){
    1015           0 :              --low;
    1016           0 :              retval=low->second;
    1017             :            }
    1018             :            else{
    1019           0 :              if(fabs(timeph - (low->first)) < fabs(timeph - (upp->first))){
    1020           0 :                retval=low->second;
    1021             :              }
    1022             :              else{
    1023           0 :                retval=upp->second;
    1024             :              }
    1025             : 
    1026             :            }
    1027             :          }
    1028             :          //tim.show("retrieved cache");
    1029             :          //cerr << std::setprecision(12) <<"msid " << oldPCMSId_p << " time "<< timeph << " val "  << retval.toString() << endl;
    1030             : 
    1031        2424 :          return retval;
    1032             : 
    1033             : 
    1034             : 
    1035           0 :  }
    1036             : 
    1037             : 
    1038           6 :   MDirection VisBufferUtil::getEphemBasedPhaseDir(const vi::VisBuffer2& vb, const String& ephemPath, const MDirection&refDir,  const Double t){
    1039             :     
    1040             :     
    1041           6 :     if(!Table::isReadable(ephemPath, False))
    1042           6 :       return refDir;
    1043           0 :     if(!(vb.getVi()->getImpl())){
    1044           0 :       throw(AipsError("VisibilityIterator is not attached to an ms"));
    1045             :     }
    1046           0 :     MEpoch ep(Quantity(t, "s"), vb.getVi()->getImpl()->getEpoch().getRef());
    1047           0 :     mframe_.resetEpoch(ep);
    1048           0 :     MeasComet mcomet(Path(ephemPath).absoluteName());
    1049           0 :     mframe_.set(mcomet);
    1050           0 :     MDirection::Ref outref1(MDirection::AZEL, mframe_);
    1051           0 :     MDirection tmpazel=MDirection::Convert(MDirection(MDirection::COMET), outref1)();
    1052           0 :     MDirection::Types outtype=(MDirection::Types) refDir.getRef().getType();
    1053           0 :     MDirection::Ref outref(outtype, mframe_);
    1054           0 :     MDirection outdir=MDirection::Convert(tmpazel, outref)();
    1055           0 :     MVDirection mvoutdir(outdir.getAngle());
    1056           0 :     MVDirection mvrefdir(refDir.getAngle());
    1057             :     //copying what ROMSFieldColumns::extractDirMeas  does
    1058           0 :     mvoutdir.shift(mvrefdir.getAngle(), True);
    1059           0 :     return MDirection(mvoutdir, outtype);
    1060           0 :   }
    1061             : 
    1062           6 :    MDirection VisBufferUtil::getEphemDir(const vi::VisBuffer2& vb,
    1063             :                                          const Double timeo){
    1064             : 
    1065           6 :      Double timeEphem = timeo > 0.0 ? timeo : vb.time()(0);
    1066           6 :      const MSFieldColumns &msfc = vb.subtableColumns().field();
    1067           6 :      Int fieldId=vb.fieldId()(0);
    1068          12 :      MDirection refDir(Quantity(0, "deg"), Quantity(0, "deg"),(MDirection::Types)msfc.ephemerisDirMeas(fieldId, timeEphem).getRef().getType());
    1069             :      //Now do the parallax correction
    1070          18 :      return getEphemBasedPhaseDir(vb, msfc.ephemPath(fieldId), refDir, timeEphem);
    1071             : 
    1072             : 
    1073           6 :    }
    1074             : 
    1075             :  //utility to reject consecutive similar value for sorting
    1076           0 :  void VisBufferUtil::rejectConsecutive(const Vector<Double>& t, Vector<Double>& retval){
    1077           0 :      uInt n=t.nelements();
    1078           0 :      if(n >0){
    1079           0 :        retval.resize(n);
    1080           0 :        retval[0]=t[0];
    1081             :      }
    1082             :      else
    1083           0 :        return;
    1084           0 :      Int prev=0;
    1085           0 :      for (uInt k=1; k < n; ++k){
    1086           0 :        if(t[k] != retval(prev)){
    1087           0 :            ++prev;
    1088             : 
    1089           0 :            retval[prev]=t[k];
    1090             :        }
    1091             :      }
    1092           0 :      retval.resize(prev+1, true);
    1093             : 
    1094             :    }
    1095           3 : void VisBufferUtil::rejectConsecutive(const Vector<Double>& t, Vector<Double>& retval, Vector<Int>& indx){
    1096           3 :     uInt n=t.nelements();
    1097           3 :     if(n >0){
    1098           3 :       retval.resize(n);
    1099           3 :       indx.resize(n);
    1100           3 :       retval[0]=t[0];
    1101           3 :       indx[0]=0;
    1102             :     }
    1103             :     else
    1104           0 :       return;
    1105           3 :     Int prev=0;
    1106      210600 :     for (uInt k=1; k < n; ++k){
    1107      210597 :       if(t[k] != retval(prev)){
    1108         597 :         ++prev;
    1109             :         //retval.resize(prev+1, true);
    1110         597 :         retval[prev]=t[k];
    1111             :         //indx.resize(prev+1, true);
    1112         597 :         indx[prev]=k;
    1113             :       }
    1114             :     }
    1115           3 :     retval.resize(prev+1, true);
    1116           3 :     indx.resize(prev+1, true);
    1117             : 
    1118             :   }
    1119             : 
    1120             : // helper function to swap the y and z axes of a Cube
    1121           0 :  void   VisBufferUtil::swapyz(Cube<Complex>& out, const Cube<Complex>& in)
    1122             : {
    1123           0 :   IPosition inShape=in.shape();
    1124           0 :   uInt nxx=inShape(0),nyy=inShape(2),nzz=inShape(1);
    1125             :   //resize breaks  references...so out better have the right shape
    1126             :   //if references is not to be broken
    1127           0 :   if(out.nelements()==0)
    1128           0 :     out.resize(nxx,nyy,nzz);
    1129             :   Bool deleteIn,deleteOut;
    1130           0 :   const Complex* pin = in.getStorage(deleteIn);
    1131           0 :   Complex* pout = out.getStorage(deleteOut);
    1132           0 :   uInt i=0, zOffset=0;
    1133           0 :   for (uInt iz=0; iz<nzz; ++iz, zOffset+=nxx) {
    1134           0 :     Int yOffset=zOffset;
    1135           0 :     for (uInt iy=0; iy<nyy; ++iy, yOffset+=nxx*nzz) {
    1136           0 :       for (uInt ix=0; ix<nxx; ++ix){
    1137           0 :         pout[i++] = pin[ix+yOffset];
    1138             :       }
    1139             :     }
    1140             :   }
    1141           0 :   out.putStorage(pout,deleteOut);
    1142           0 :   in.freeStorage(pin,deleteIn);
    1143           0 : }
    1144             : 
    1145             : // helper function to swap the y and z axes of a Cube
    1146           0 : void VisBufferUtil::swapyz(Cube<Bool>& out, const Cube<Bool>& in)
    1147             : {
    1148           0 :   IPosition inShape=in.shape();
    1149           0 :   uInt nxx=inShape(0),nyy=inShape(2),nzz=inShape(1);
    1150           0 :   if(out.nelements()==0)
    1151           0 :     out.resize(nxx,nyy,nzz);
    1152             :   Bool deleteIn,deleteOut;
    1153           0 :   const Bool* pin = in.getStorage(deleteIn);
    1154           0 :   Bool* pout = out.getStorage(deleteOut);
    1155           0 :   uInt i=0, zOffset=0;
    1156           0 :   for (uInt iz=0; iz<nzz; iz++, zOffset+=nxx) {
    1157           0 :     Int yOffset=zOffset;
    1158           0 :     for (uInt iy=0; iy<nyy; iy++, yOffset+=nxx*nzz) {
    1159           0 :       for (uInt ix=0; ix<nxx; ix++) pout[i++] = pin[ix+yOffset];
    1160             :     }
    1161             :   }
    1162           0 :   out.putStorage(pout,deleteOut);
    1163           0 :   in.freeStorage(pin,deleteIn);
    1164           0 : }
    1165             : 
    1166             : 
    1167             : 
    1168             : 
    1169             : } //# NAMESPACE CASA - END
    1170             : 

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