LCOV - code coverage report
Current view: top level - synthesis/TransformMachines - StokesImageUtil.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 1197 0.0 %
Date: 2024-10-10 11:40:37 Functions: 0 37 0.0 %

          Line data    Source code
       1             : //# StokesImageUtil.cc: Stokes Image Utilities
       2             : //# Copyright (C) 1996,1997,1998,1999,2000,2001,2002,2003
       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/Arrays/Matrix.h>
      32             : #include <casacore/casa/Arrays/MatrixMath.h>
      33             : #include <casacore/casa/Arrays/ArrayMath.h>
      34             : #include <casacore/casa/Arrays/Cube.h>
      35             : #include <casacore/casa/BasicMath/Math.h>
      36             : #include <casacore/casa/BasicSL/Complex.h>
      37             : #include <casacore/scimath/Mathematics/FFTServer.h>
      38             : #include <casacore/casa/BasicSL/Constants.h>
      39             : #include <casacore/casa/Utilities/Assert.h>
      40             : #include <casacore/lattices/Lattices/Lattice.h>
      41             : #include <casacore/lattices/LEL/LatticeExpr.h>
      42             : #include <casacore/lattices/Lattices/LatticeIterator.h>
      43             : #include <casacore/lattices/Lattices/LatticeStepper.h>
      44             : #include <casacore/lattices/LatticeMath/LatticeConvolver.h>
      45             : #include <casacore/scimath/Fitting/NonLinearFitLM.h>
      46             : #include <casacore/scimath/Functionals/Gaussian2D.h>
      47             : #include <casacore/scimath/Mathematics/Interpolate2D.h>
      48             : #include <casacore/casa/IO/ArrayIO.h>
      49             : 
      50             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      51             : #include <casacore/ms/MeasurementSets/MSDopplerUtil.h>
      52             : 
      53             : #include <msvis/MSVis/StokesVector.h>
      54             : #include <synthesis/TransformMachines/StokesImageUtil.h>
      55             : #include <casacore/images/Images/PagedImage.h>
      56             : #include <casacore/images/Images/SubImage.h>
      57             : #include <casacore/images/Images/ImageBeamSet.h>
      58             : #include <casacore/casa/OS/File.h>
      59             : 
      60             : #include <casacore/casa/Quanta/UnitMap.h>
      61             : #include <casacore/casa/Quanta/UnitVal.h>
      62             : #include <casacore/measures/Measures/Stokes.h>
      63             : #include <casacore/coordinates/Coordinates/CoordinateSystem.h>
      64             : #include <casacore/coordinates/Coordinates/DirectionCoordinate.h>
      65             : #include <casacore/coordinates/Coordinates/SpectralCoordinate.h>
      66             : #include <casacore/coordinates/Coordinates/StokesCoordinate.h>
      67             : #include <casacore/coordinates/Coordinates/Projection.h>
      68             : #include <casacore/casa/Logging/LogSink.h>
      69             : #include <casacore/casa/Logging/LogMessage.h>
      70             : 
      71             : #include <synthesis/TransformMachines2/Utils.h>
      72             : 
      73             : #include <iostream>
      74             : #include <ctime>
      75             : 
      76             : using namespace casacore;
      77             : namespace casa {
      78             : 
      79             : 
      80             : 
      81             : // <summary> 
      82             : // </summary>
      83             : 
      84             : // <reviewed reviewer="" date="" tests="tMEGI" demos="">
      85             : 
      86             : // <prerequisite>
      87             : // </prerequisite>
      88             : //
      89             : // <etymology>
      90             : // </etymology>
      91             : //
      92             : // <synopsis> 
      93             : // </synopsis> 
      94             : //
      95             : // <example>
      96             : // <srcblock>
      97             : // </srcblock>
      98             : // </example>
      99             : //
     100             : // <motivation>
     101             : // </motivation>
     102             : //
     103             : // <todo asof="">
     104             : // </todo>
     105             : 
     106             : // In-place convolve. image is 4 dimensional. RA and Dec first.
     107           0 : void StokesImageUtil::Convolve(ImageInterface<Float>& image,
     108             :                                ImageInterface<Float>& psf) {
     109             : 
     110             : 
     111           0 :   Double availablemem=Double(HostInfo::memoryFree())*1024.0;
     112             :   //Do an in memory if x-y complex can fit in remaining memory
     113           0 :   if(availablemem < Double(image.shape()(0)*image.shape()(1))*6.0*8.0 ){
     114           0 :     LatticeConvolver<Float> lattCon(psf);
     115           0 :     lattCon.linear(image);
     116           0 :   }
     117             :   else{
     118             :     
     119           0 :     Vector<Int> map;
     120           0 :     AlwaysAssert(StokesMap(map, image.coordinates()), AipsError);
     121             :     
     122           0 :     Vector<Int> psfmap;
     123           0 :     AlwaysAssert(StokesMap(psfmap, psf.coordinates()), AipsError);
     124             :     
     125           0 :     Int nx = image.shape()(map(0));
     126           0 :     Int ny = image.shape()(map(1));
     127             :     
     128             :     // Make FFT machine
     129           0 :     FFTServer<Float,Complex> fft(IPosition(2, nx, ny));
     130             :     
     131             :     // Get the image into a Matrix for Fourier transformation
     132           0 :     Array<Complex> xfr;
     133           0 :     Matrix<Complex> cft;
     134             :     
     135           0 :     LatticeStepper ls(image.shape(), IPosition(4, nx, ny, 1, 1),
     136           0 :                       IPosition(4, map(0), map(1), map(2), map(3)));
     137           0 :     LatticeIterator<Float> li(image, ls);
     138             :     
     139             :     // Get the PSF into a Matrix for Fourier transformation
     140           0 :     LatticeStepper psfls(psf.shape(), IPosition(4, nx, ny, 1, 1),
     141           0 :                          IPosition(4, map(0), map(1), map(2), map(3)));
     142           0 :     RO_LatticeIterator<Float> psfli(psf, psfls);
     143           0 :     psfli.reset();
     144             :     //fft.fft(xfr, psfli.matrixCursor());
     145           0 :     fft.fft0(xfr, psfli.matrixCursor());
     146             :     
     147             :     // Loop over all planes
     148           0 :     for (li.reset();!li.atEnd();li++) {
     149             :       //fft.fft(cft, li.matrixCursor());
     150           0 :       fft.fft0(cft,li.matrixCursor());
     151           0 :       cft *= xfr;
     152             :       // fft.fft(li.rwMatrixCursor(), cft);
     153           0 :       fft.fft0(li.rwMatrixCursor(),cft,false);
     154           0 :       fft.flip(li.rwMatrixCursor(), false, false);
     155             :     }
     156           0 :   } 
     157           0 : };
     158             : 
     159           0 : void StokesImageUtil::Convolve(ImageInterface<Float>& image, 
     160             :                                  ImageBeamSet& beams, Bool normalizeVolume){
     161             : 
     162           0 :   Int nbeams=beams.shape()(0);
     163             :   
     164           0 :   Int freqAx=CoordinateUtil::findSpectralAxis(image.coordinates());
     165           0 :   Int nchan=image.shape()(freqAx);
     166           0 :   if((nchan != nbeams) || (nchan==1)){
     167           0 :     GaussianBeam elbeam=beams(0, 0);
     168           0 :     Convolve(image, elbeam, normalizeVolume);     
     169           0 :   }
     170             :   else{
     171           0 :     IPosition blc=image.shape();
     172           0 :     blc=0;
     173           0 :     IPosition trc=image.shape()-1;
     174           0 :     for (Int k=0; k < nchan; ++k){
     175           0 :       blc[freqAx]=k;
     176           0 :       trc[freqAx]=k;
     177           0 :       Slicer slc(blc, trc, Slicer::endIsLast);
     178           0 :       SubImage<Float> subim(image, slc, true);
     179           0 :       GaussianBeam elbeam=beams(k,0);
     180           0 :       Convolve(subim, elbeam, normalizeVolume);
     181             : 
     182           0 :     }
     183           0 :   }
     184           0 : }
     185             : 
     186           0 : void StokesImageUtil::Convolve(ImageInterface<Float>& image,
     187             :                                GaussianBeam& beam,
     188             :                                Bool normalizeVolume)
     189             : {
     190           0 :   Convolve(image, beam.getMajor().get("arcsec").getValue(),
     191           0 :            beam.getMinor().get("arcsec").getValue(),
     192           0 :            beam.getPA().get("deg").getValue(),
     193             :            normalizeVolume);
     194           0 : }
     195             : 
     196           0 : void StokesImageUtil::Convolve(ImageInterface<Float>& image, Float bmaj,
     197             :                                Float bmin, Float bpa,
     198             :                                Bool normalizeVolume) {
     199             :   
     200           0 :   Vector<Float> beam(3);
     201           0 :   beam(0)=bmaj*C::arcsec;
     202           0 :   beam(1)=bmin*C::arcsec;
     203           0 :   beam(2)=(bpa+90.0)*C::degree;
     204             :   PagedImage<Float>
     205           0 :     cleanpsf(IPosition(4, image.shape()(0), image.shape()(1), 1, 1),
     206             :              image.coordinates(),
     207           0 :              File::newUniqueName("./","imagesolver::cleanpsf").originalName());
     208           0 :   cleanpsf.table().markForDelete();
     209           0 :   MakeGaussianPSF(cleanpsf, beam, normalizeVolume);
     210           0 :   Convolve(image, cleanpsf);
     211           0 : }
     212             : 
     213           0 : void StokesImageUtil::MakeGaussianPSF(ImageInterface<Float>& psf,
     214             :                                       Quantity& bmaj, Quantity& bmin,
     215             :                                       Quantity& bpa,
     216             :                                       Bool normalizeVolume) 
     217             : {
     218           0 :   Vector<Float> beam(3);
     219           0 :   beam(0)=bmaj.get("arcsec").getValue();
     220           0 :   beam(1)=bmin.get("arcsec").getValue();
     221           0 :   beam(2)=bpa.get("deg").getValue();
     222           0 :   MakeGaussianPSF(psf, beam, normalizeVolume);
     223           0 : }
     224             : 
     225             : // Make an image into a Gaussian PSF
     226           0 : void StokesImageUtil::MakeGaussianPSF(ImageInterface<Float>& psf, Vector<Float>& beam,
     227             :                                       Bool normalizeVolume) {
     228             :   
     229           0 :   Int nx=psf.shape()(0);
     230           0 :   Int ny=psf.shape()(1);
     231           0 :   Matrix<Float> ipsf(nx, ny);
     232             :   
     233           0 :   Double cospa=cos(beam(2));
     234           0 :   Double sinpa=sin(beam(2));
     235           0 :   Vector<Double> rp=psf.coordinates().referencePixel();
     236           0 :   Vector<Double> d=psf.coordinates().increment();
     237           0 :   Double refi=rp(0);
     238           0 :   Double refj=rp(1);
     239           0 :   AlwaysAssert(beam(0)>0.0,AipsError);
     240           0 :   AlwaysAssert(beam(1)>0.0,AipsError);
     241             :   Double sbmaj, sbmin;
     242             :   
     243             :   // ---old
     244             :   // Assumes that the cell sizes are the same in both directions!
     245             :   //sbmaj=4.0*log(2.0)*square(d(0)/beam(0));
     246             :   //sbmin=4.0*log(2.0)*square(d(0)/beam(1));
     247             :   // ---old
     248             : 
     249             :   // Evaluate the Gaussian beam using real-world coordinates, to handle rectangular pixels (cas-7171)
     250           0 :   sbmaj=4.0*log(2.0)*square(1.0/beam(0));
     251           0 :   sbmin=4.0*log(2.0)*square(1.0/beam(1));
     252             : 
     253           0 :   Vector<Double>fd(fabs(d));
     254             : 
     255           0 :   Float volume=0.0;
     256           0 :   for (Int j=0;j<ny;j++) {
     257           0 :     for (Int i=0;i<nx;i++) {
     258             :       //   ---old
     259             :       //      Double x =   cospa * (Double(i)-refi) + sinpa * (Double(j)-refj);
     260             :       //      Double y = - sinpa * (Double(i)-refi) + cospa * (Double(j)-refj);
     261             :       //   ---old
     262           0 :       Double x =   cospa * (Double(i)-refi)*fd(0) + sinpa * (Double(j)-refj)*fd(1);
     263           0 :       Double y = - sinpa * (Double(i)-refi)*fd(0) + cospa * (Double(j)-refj)*fd(1);
     264           0 :       Double radius = sbmaj*square(x) + sbmin*square(y);
     265           0 :       if (radius<20.) {
     266           0 :         ipsf(i,j) = exp(-radius);
     267           0 :         volume+=ipsf(i,j);
     268             :       }
     269             :       else {
     270           0 :         ipsf(i,j)=0.;
     271             :       }
     272             :     }
     273             :   }
     274           0 :   if(normalizeVolume) ipsf/=volume;
     275           0 :   psf.putSlice(ipsf, IPosition(psf.ndim(),0), IPosition(psf.ndim(),1));
     276             :   
     277           0 : }
     278             : 
     279           0 : Float  StokesImageUtil::normalizePSF(casacore::ImageInterface<casacore::Float>& psf){
     280           0 :   AlwaysAssert(psf.ndim()==4,AipsError);
     281             :   
     282           0 :   Float retval=-1e10;
     283           0 :   Vector<Int> map;
     284           0 :   AlwaysAssert(StokesMap(map, psf.coordinates()), AipsError);
     285           0 :   Int nx = psf.shape()(map(0));
     286           0 :   Int ny = psf.shape()(map(1));
     287           0 :   if(nx < 32 || ny < 32)
     288           0 :     throw(AipsError("Will not normalize images less than 32 pixels"));
     289           0 :   Int npol = psf.shape()(map(2));
     290           0 :   Int nchan = psf.shape()(map(3));
     291           0 :   IPosition blc(4);
     292           0 :   IPosition trc(4);
     293           0 :   IPosition blc8(4,0,0,0,0);
     294           0 :   IPosition trc8(4,0,0,0,0);
     295           0 :   blc(map(0))=0; blc(map(1))=0;
     296           0 :   trc(map(0))=nx-1; trc(map(1))=ny-1;
     297           0 :   blc8(map(0))=nx/2-nx/16; blc8(map(1))=ny/2-ny/16;
     298           0 :   trc8(map(0))=nx/2+nx/16; trc8(map(1))=ny/2+ny/16;
     299           0 :   Slicer inner8(blc8, trc8,  Slicer::endIsLast);
     300           0 :   for (Int k=0; k < nchan ; ++k){
     301           0 :     blc(map(3))=k;
     302           0 :     trc(map(3))=k;
     303           0 :     for (Int j=0; j < npol; ++j){
     304           0 :       blc(map(2))=j;
     305           0 :       trc(map(2))=j;
     306           0 :       Slicer sl(blc, trc, Slicer::endIsLast);
     307           0 :       SubImage<Float> psfSub(psf, sl, True);
     308           0 :       Float maxCenter=max(psfSub.getSlice(inner8));
     309           0 :       if(maxCenter > retval)
     310           0 :         retval=maxCenter;
     311           0 :       if(maxCenter !=0){
     312           0 :         psfSub.copyData( (LatticeExpr<Float>)(psfSub/maxCenter));
     313             :       }
     314             :       else{
     315           0 :         psfSub.set(0.0);
     316             :       }
     317           0 :     }
     318             :   }
     319           0 :   return retval;
     320           0 : }
     321             : 
     322             : 
     323             : // Zero specified elements of a Stokes image
     324           0 : void StokesImageUtil::Zero(ImageInterface<Float>& image, Vector<Bool>& mask) {
     325             :   
     326           0 :   AlwaysAssert(image.ndim()==4,AipsError);
     327           0 :   AlwaysAssert(mask.shape()(0)==4,AipsError);
     328             :   
     329           0 :   Vector<Int> map;
     330           0 :   AlwaysAssert(StokesMap(map, image.coordinates()), AipsError);
     331             :   
     332           0 :   Int nx = image.shape()(map(0));
     333           0 :   Int ny = image.shape()(map(1));
     334           0 :   Int npol = image.shape()(map(2));
     335           0 :   Int nchan = image.shape()(map(3));
     336             :   
     337           0 :   LatticeStepper ls(image.shape(), IPosition(4, nx, 1, 1, 1),
     338           0 :                     IPosition(4, map(0), map(1), map(2), map(3)));
     339           0 :   LatticeIterator<Float> li(image, ls);
     340             :   
     341             :   // Loop over all planes
     342           0 :   li.reset();
     343           0 :   for (Int chan=0;chan<nchan;chan++) {
     344           0 :     for(Int pol=0;pol<npol;pol++) {
     345           0 :       for(Int iy=0;iy<ny;iy++,li++) {
     346           0 :         if(mask(pol)) {
     347           0 :           li.woVectorCursor()=0.0;
     348             :         }
     349             :       }
     350             :     }
     351             :   }
     352             :   
     353           0 : }
     354             : 
     355           0 : void StokesImageUtil::MaskFrom(ImageInterface<Float>& mask,
     356             :                                ImageInterface<Float>& image,
     357             :                                const Quantity& threshold) 
     358             : {
     359           0 :   MaskFrom(mask, image, threshold.get("Jy").getValue());
     360           0 : }
     361             : 
     362           0 : void StokesImageUtil::MaskFrom(ImageInterface<Float>& mask,
     363             :                                ImageInterface<Float>& image,
     364             :                                const Double thres) 
     365             : {
     366           0 :   AlwaysAssert(image.ndim()==4,AipsError);
     367           0 :   AlwaysAssert(mask.shape()==image.shape(),AipsError);
     368             :   
     369           0 :   Vector<Int> map;
     370           0 :   AlwaysAssert(StokesMap(map, image.coordinates()), AipsError);
     371             :   
     372           0 :   Int nx = image.shape()(map(0));
     373           0 :   Int npol = image.shape()(map(2));
     374             :   
     375           0 :   LatticeStepper ls(image.shape(), IPosition(4, nx, 1, npol, 1),
     376           0 :                     IPosition(4, map(0), map(1), map(2), map(3)));
     377           0 :   RO_LatticeIterator<Float> li(image, ls);
     378           0 :   LatticeIterator<Float> mli(mask, ls);
     379             :   
     380             :   // Loop over all planes
     381           0 :   for (li.reset(),mli.reset();!li.atEnd()&&!mli.atEnd();li++,mli++) {
     382           0 :     if(npol>1) {
     383           0 :       mli.rwMatrixCursor()=0.0;
     384           0 :       for (Int ix=0;ix<nx;ix++) {
     385           0 :         if(li.matrixCursor()(ix,0)>thres) {
     386           0 :           for (Int pol=0;pol<npol;pol++) mli.rwMatrixCursor()(ix,pol)=1.0;
     387             :         }
     388             :       }
     389             :     }
     390             :     else {
     391           0 :       mli.rwVectorCursor()=0.0;
     392           0 :       for (Int ix=0;ix<nx;ix++) {
     393           0 :         if(li.vectorCursor()(ix)>thres) {
     394           0 :           mli.rwVectorCursor()(ix)=1.0;
     395             :         }
     396             :       }
     397             :     }
     398             :   }
     399           0 : }
     400             : 
     401           0 : void StokesImageUtil::MaskOnStokesI(ImageInterface<Float>& image,
     402             :                                     const Quantity& threshold) 
     403             : {
     404             :   
     405           0 :   Double thres=threshold.get("Jy").getValue();
     406             :   
     407           0 :   AlwaysAssert(image.ndim()==4,AipsError);
     408             :   
     409           0 :   Vector<Int> map;
     410           0 :   AlwaysAssert(StokesMap(map, image.coordinates()), AipsError);
     411             :   
     412           0 :   Int nx = image.shape()(map(0));
     413           0 :   Int npol = image.shape()(map(2));
     414             :   
     415           0 :   LatticeStepper ls(image.shape(), IPosition(4, nx, 1, npol, 1),
     416           0 :                     IPosition(4, map(0), map(1), map(2), map(3)));
     417           0 :   LatticeIterator<Float> li(image, ls);
     418             :   
     419             :   // Loop over all planes
     420           0 :   for (li.reset();!li.atEnd();li++) {
     421           0 :     for (Int ix=0;ix<nx;ix++) {
     422           0 :       if(npol>1) {
     423           0 :         if(li.matrixCursor()(ix,0)<thres) {
     424           0 :           for (Int pol=0;pol<npol;pol++) li.rwMatrixCursor()(ix,pol)=0.0;
     425             :         }
     426             :       }
     427             :       else {
     428           0 :         if(li.vectorCursor()(ix)<thres) {
     429           0 :           li.rwVectorCursor()(ix)=0.0;
     430             :         }
     431             :       }
     432             :     }
     433             :   }
     434             :   
     435           0 : }
     436             : 
     437             : // Constrain (a) Stokes I to be > 0 and (b) I > abs(V) and
     438             : // (c) fractional pol<1.0
     439           0 : void StokesImageUtil::Constrain(ImageInterface<Float>& image) {
     440             :   
     441           0 :   AlwaysAssert(image.ndim()==4,AipsError);
     442             :   
     443           0 :   Vector<Int> map;
     444           0 :   AlwaysAssert(StokesMap(map, image.coordinates()), AipsError);
     445             :   
     446           0 :   Int nx = image.shape()(map(0));
     447           0 :   Int npol = image.shape()(map(2));
     448             :   
     449           0 :   LatticeStepper ls(image.shape(), IPosition(4, nx, 1, npol, 1),
     450           0 :                     IPosition(4, map(0), map(2), map(1), map(3)));
     451           0 :   LatticeIterator<Float> li(image, ls);
     452             :   
     453             :   // Loop over all planes
     454           0 :   for (li.reset();!li.atEnd();li++) {
     455             :     
     456             :     // Make a copy of the cursor
     457           0 :     Matrix<Float>& limage=li.rwMatrixCursor();
     458             :     
     459           0 :     for (Int ix=0;ix<nx;ix++) {
     460             :       // I >=0
     461           0 :       Bool zero=false;
     462           0 :       if(limage(ix,0)<0.0) {
     463           0 :         zero=true;
     464             :       }
     465             :       // I >= abs(V)
     466           0 :       else if (npol==2) {
     467           0 :         if(limage(ix,0)<abs(limage(ix,1))) zero=true;
     468             :       }
     469             :       // fractional pol < 1.0
     470           0 :       else if (npol==4) {
     471           0 :         StokesVector sv(limage(ix,0),limage(ix,1),
     472           0 :                         limage(ix,2),limage(ix,3));
     473           0 :         if(sv.minEigenValue()<0.0) zero=true;
     474             :       }
     475           0 :       if(zero) for (Int pol=0;pol<npol;pol++) limage(ix,pol)=0.0;
     476             :     }
     477             :   }
     478           0 : }
     479             : 
     480             : //See CAS-13022 for FitGaussianPSF algorithm details
     481           0 : Bool StokesImageUtil::FitGaussianPSF(ImageInterface<Float>& psf, ImageBeamSet& elbeam, Float psfcutoff){
     482             :   
     483           0 :   Bool retval=true;
     484           0 :   Int freqAx=CoordinateUtil::findSpectralAxis(psf.coordinates());
     485           0 :   Vector<Stokes::StokesTypes> whichPols;
     486           0 :   Int polAx=CoordinateUtil::findStokesAxis(whichPols, psf.coordinates());
     487           0 :   Int nchan=psf.shape()(freqAx);
     488           0 :   IPosition blc=psf.shape();
     489           0 :   blc=0;
     490           0 :   IPosition trc=psf.shape()-1;
     491           0 :   trc[polAx]=0;
     492           0 :   elbeam=ImageBeamSet(nchan, 1);
     493           0 :   IPosition ipos(2,0,0);
     494           0 :   Matrix<GaussianBeam> tempBeam(nchan,1);
     495           0 :   Vector<Bool> fitted(nchan, false);
     496             : 
     497           0 :   for (Int k=0; k < nchan;++k){ 
     498           0 :     blc[freqAx]=k;
     499           0 :     trc[freqAx]=k;
     500           0 :     Slicer slc(blc, trc, Slicer::endIsLast);
     501           0 :     SubImage<Float> subpsf(psf, slc, false);
     502             :     try{
     503           0 :       fitted(k)=FitGaussianPSF(subpsf, tempBeam(k,0), psfcutoff);
     504             :     }
     505           0 :     catch (AipsError x_error){
     506           0 :       Int ik=k;
     507           0 :       fitted(k)=false;
     508           0 :       while ((ik > 0) && !fitted(k)){
     509           0 :         if(fitted(ik-1)){
     510           0 :           fitted(k)=true;
     511           0 :           tempBeam(k,0)=tempBeam(ik-1, 0);
     512             :         }
     513           0 :         --ik;
     514             :       }
     515           0 :     } 
     516           0 :     ipos(0)=k;
     517           0 :   }
     518           0 :   Float maxMaj=0.0;
     519           0 :   Float minMaj=C::flt_max;
     520           0 :   Int posMax=0;
     521           0 :   DirectionCoordinate directionCoord=psf.coordinates().directionCoordinate(psf.coordinates().findCoordinate(Coordinate::DIRECTION));
     522           0 :   String dirunit=directionCoord.worldAxisUnits()(0);
     523           0 :   for(Int k=0; k < nchan; ++k){
     524           0 :           if(fitted(k) && (maxMaj < tempBeam(k,0).getMajor(dirunit))){
     525           0 :                   maxMaj=tempBeam(k,0).getMajor(dirunit);
     526           0 :                   posMax=k;
     527             :           }
     528           0 :           if(fitted(k) && (minMaj > tempBeam(k,0).getMajor(dirunit))){
     529           0 :                           minMaj=tempBeam(k,0).getMajor(dirunit);
     530           0 :                           posMax=k;
     531             :           }
     532             :   }
     533             :   //If the beams are within 0.5 pixel the same resolution then
     534             :   //who cares to have a beam per plane
     535           0 :   if(abs(minMaj-maxMaj) < 0.5*abs(directionCoord.increment()(0))){
     536           0 :           GaussianBeam theBeam=tempBeam(posMax,0);
     537           0 :           tempBeam.resize(1,1);
     538           0 :           tempBeam(0,0)=theBeam;
     539           0 :           fitted.resize(1);
     540           0 :           fitted=true;
     541           0 :   }
     542           0 :   if(!anyTrue(fitted)){
     543           0 :       retval=false;
     544           0 :       throw(AipsError("No valid fits were found to PSF"));
     545             :   }
     546           0 :   if(!allTrue(fitted)){
     547           0 :      for (Int k=0; k < nchan;++k){ 
     548           0 :        int ik=k;
     549           0 :        while((ik < (nchan-1)) && !fitted(k)){
     550           0 :          if(fitted(ik+1)){
     551           0 :            fitted(k)=true;
     552           0 :            tempBeam(k,0)=tempBeam(ik+1, 0);
     553             :          }
     554           0 :          ++ik;
     555             :        }
     556             :      }
     557             :   }
     558           0 :   elbeam=ImageBeamSet(tempBeam.shape());
     559           0 :   elbeam.setBeams(tempBeam);
     560             :   
     561           0 :   return retval;
     562           0 : }
     563             : 
     564           0 : Bool StokesImageUtil::FitGaussianPSF(ImageInterface<Float>& psf, 
     565             :                                      GaussianBeam& beam, Float psfcutoff)
     566             : {
     567           0 :         Vector<Float> vbeam(3, 0.0);
     568           0 :   Bool status=true;
     569           0 :   if(!FitGaussianPSF(psf, vbeam, psfcutoff)) status=false;
     570           0 :   beam = GaussianBeam(
     571           0 :                   Quantity(abs(vbeam[0]),"arcsec"),
     572           0 :                   Quantity(abs(vbeam[1]),"arcsec"),
     573           0 :                   Quantity(vbeam[2],"deg")
     574           0 :         );
     575           0 :   return status;
     576             : 
     577           0 : }
     578             : 
     579             : 
     580           0 : void StokesImageUtil::FindNpoints(Int& npoints, IPosition& blc,  IPosition& trc, Int nrow, Float amin, Int px, Int py, Vector<Double>& deltas, Matrix<Double>& x , Vector<Double>& y, Vector<Double>& sigma,  Matrix<Float>& lpsf){
     581             :     
     582           0 :     Int maxnpoints=(2*nrow+1)*(2*nrow+1);
     583           0 :     Matrix<Double> ix(maxnpoints,2);
     584           0 :     Vector<Double> iy(maxnpoints), isigma(maxnpoints);
     585           0 :     ix=0.0; iy=0.0; isigma=0.0;
     586           0 :     npoints = 0;
     587             :     
     588             :     //IPosition blc(2), trc(2);
     589             : //blc = 0; trc = 0;
     590             :     
     591           0 :     blc(0) = lpsf.shape()(0)-1;
     592           0 :     blc(1) = lpsf.shape()(1)-1;
     593           0 :     trc(0) = 0;
     594           0 :     trc(1) = 0;
     595             :     
     596           0 :     IPosition psf_shape = lpsf.shape();
     597             : 
     598             :     //we sample the central part of a, 2*nrow+1 by 2*nrow+1
     599             :     
     600           0 :     Int iflip = 1;
     601           0 :     Int jflip = 1;
     602             :     // loop through rows. Include both above and below in case
     603             :     // we are fitting an image feature
     604             :     
     605           0 :     for(Int jlo = 0;jlo<2;jlo++) {
     606           0 :       jflip*=-1;
     607             :       // loop from 0 to nrow then from 1 to nrow
     608           0 :       for(Int j = jlo;j<=nrow;j++) {
     609             :         // the current row under consideration
     610           0 :         Int jrow = py + j*jflip;
     611             :         // loop down row doing alternate halves. work our way
     612             :         // out from the center until we cross threshold
     613             :         // don't include any sidelobes!
     614           0 :         for(Int ilo=0;ilo<2;ilo++) {
     615           0 :       iflip*=-1;
     616             :       // start at center row this may or may not be in the lobe,
     617             :       // if it's narrow and the pa is near 45 degrees
     618             :       
     619             :       
     620           0 :       if((jrow > (psf_shape(1)-1)) || (jrow < 0 ) ) break;
     621             :       //cout << "11.** " << maxnpoints << ",*,"<< npoints << ",*," << px << ",*," << jrow << endl;
     622           0 :       Bool inlobe = lpsf(px,jrow)>amin;
     623             :     
     624             :       //cout << "12.** " << maxnpoints << ",*,"<< npoints << ",*," << px << ",*," << jrow << endl;
     625           0 :       for(Int i = ilo;i<=nrow;i++) {
     626           0 :         if(npoints < maxnpoints){
     627           0 :           Int irow = px + i*iflip;
     628             :           // did we step out of the lobe?
     629             :          
     630           0 :           if((irow > (psf_shape(0)-1)) || (irow < 0 ) ) break;
     631             :           //cout << "irow , jrow " << irow  << ",*," << jrow  << ",*," << lpsf.shape() << ",*," << px << ",*," << py << endl;
     632           0 :           if (inlobe&&(lpsf(irow,jrow)<amin)) break;
     633           0 :           if (lpsf(irow,jrow)>amin) {
     634             :             //cout << "$%$irow , jrow " << lpsf.shape() << ",*,"<< irow << "," << jrow << ",*, "<< irow - px << ",*," << jrow - py << ",*, " << lpsf(irow,jrow) << ",*, " << inlobe << ",*, " << npoints <<  endl;
     635           0 :             inlobe = true;
     636             :             // the sign on the ra can cause problems.  we just fit
     637             :             // for what the beam "looks" like here, and worry about
     638             :             // it later.
     639           0 :             ix(npoints,0) = (irow-px)*abs(deltas(0));
     640           0 :             ix(npoints,1) = (jrow-py)*abs(deltas(1));
     641           0 :             iy(npoints) = lpsf(irow,jrow);
     642             :               //cout << "1.**" << endl;
     643             :             
     644           0 :               if(blc(0) > irow) blc(0) = irow;
     645           0 :               if(blc(1) > jrow) blc(1) = jrow;
     646             :               
     647           0 :               if(trc(0) < irow) trc(0) = irow;
     648           0 :               if(trc(1) < jrow) trc(1) = jrow;
     649             :               //cout << "2.**" << endl;
     650             :   
     651           0 :             isigma(npoints) = 1.0;
     652           0 :             ++npoints;
     653             :              // cout << "3.** " << maxnpoints << ",*,"<< npoints << endl;
     654           0 :             if(npoints > (maxnpoints-1)) {
     655           0 :           inlobe=false;
     656             :               //cout << "Over max points .** " << maxnpoints << ",*,"<< npoints << endl;
     657             :           //break;
     658           0 :                 goto endSearch;
     659             :             }
     660             :              // cout << "5.** " << maxnpoints << ",*,"<< npoints << endl;
     661             :           }
     662             :         }
     663             :       }
     664             :         }
     665             :       }
     666             :     }
     667             :     
     668           0 :     endSearch:
     669             :     
     670             :     //cout << "2. blc, trc " << blc << ",*," << trc << endl;
     671             :     //Vector<Double> y(npoints), sigma(npoints);
     672             :     //Matrix<Double> x(npoints,2);
     673             :     //cout << "hallo " << endl;
     674             :     
     675           0 :     y.resize(npoints);
     676           0 :     x.resize(npoints,2);
     677           0 :     sigma.resize(npoints);
     678             :     
     679             :     //cout << "2. findNPoints " << npoints << " " << amin << endl;
     680             :     
     681           0 :     for (Int ip=0;ip<npoints;ip++) {
     682           0 :       x(ip,0)=ix(ip,0); x(ip,1)=ix(ip,1);
     683           0 :       y(ip)=iy(ip);
     684           0 :       sigma(ip)=isigma(ip);
     685           0 :       if(!(isigma(ip)>0.0)) break;
     686             :     }
     687             :     
     688             :     //Ensure that it is square
     689           0 :     if(blc(0) > blc(1)){
     690           0 :         blc(0) = blc(1);
     691             :     }else{
     692           0 :         blc(1) = blc(0);
     693             :     }
     694             :     
     695           0 :     if(trc(0) > trc(1)){
     696           0 :         trc(1) = trc(0);
     697             :     }else{
     698           0 :         trc(0) = trc(1);
     699             :     }
     700             :     
     701             :     
     702           0 : }
     703             : 
     704           0 : void StokesImageUtil::ResamplePSF(Matrix<Float>& psf, Int& oversampling, Matrix<Float>& resampledPsf, String& InterpMethod)
     705             : {
     706           0 :     Int nx = psf.shape()(0);
     707           0 :     Int ny = psf.shape()(1);
     708           0 :     Int nxRe = nx*oversampling - oversampling + 1;
     709           0 :     Int nyRe = ny*oversampling - oversampling + 1;
     710             :     
     711           0 :     Vector<Double> pos(2);
     712           0 :     resampledPsf.resize(nxRe,nyRe);
     713             :     
     714             :     Interpolate2D::Method method;
     715           0 :     if(InterpMethod == "NEAREST") method = Interpolate2D::NEAREST;
     716           0 :     if(InterpMethod == "LINEAR") method = Interpolate2D::LINEAR;
     717           0 :     if(InterpMethod == "CUBIC") method = Interpolate2D::CUBIC;
     718           0 :     if(InterpMethod == "LANCZOS") method = Interpolate2D::LANCZOS;
     719             :     
     720           0 :     Interpolate2D resampleInterp(method);
     721             : //Interpolate2D resampleInterp(Interpolate2D::CUBIC);
     722             :     
     723             :     Bool ok;
     724             :     Float result;
     725             :     
     726           0 :     for (Int i=0; i < nxRe ; ++i){
     727           0 :         for (Int j=0; j < nyRe ; ++j){
     728           0 :             pos(0) = (Float) i/(Float) oversampling;
     729           0 :             pos(1) = (Float) j/(Float) oversampling;
     730             :             
     731           0 :             ok = resampleInterp.interp(result, pos, psf);
     732             : //cout << "pos is" << pos << " result " << result << " psf " << psf(i,j)<< endl;
     733           0 :             resampledPsf(i,j) = result;
     734             :         }
     735             :     }
     736             :     
     737             :     
     738           0 : }
     739             : 
     740             : 
     741           0 : Bool StokesImageUtil::FitGaussianPSF(ImageInterface<Float>& psf, Vector<Float>& beam, Float psfcutoff) {
     742             :   
     743           0 :   LogIO os(LogOrigin("StokesImageUtil", "FitGaussianPSF()",WHERE));
     744           0 :   os << LogIO::DEBUG1 << "Psfcutoff is  " << psfcutoff << LogIO::POST;
     745             :     
     746           0 :   Float npix = 20;
     747           0 :   Int expand_pixel = 5;
     748           0 :   Int target_npoints = 3001;
     749           0 :   String InterpMethod = "CUBIC";
     750             : 
     751             :   //##########################################################
     752             :   
     753           0 :   Vector<Double> deltas;
     754           0 :   deltas=psf.coordinates().increment();
     755             :   
     756           0 :   Vector<Int> map;
     757           0 :   AlwaysAssert(StokesMap(map, psf.coordinates()), AipsError);
     758             :   
     759           0 :   Int nx = psf.shape()(map(0));
     760           0 :   Int ny = psf.shape()(map(1));
     761             :   //// Int nchan = psf.shape()(map(3)); // apparently not used and no side effects
     762           0 :   Int px=0;
     763           0 :   Int py=0;
     764           0 :   Float bamp=0;
     765           0 :   Matrix<Float> lpsf;
     766           0 :   locatePeakPSF(psf, px, py, bamp, lpsf);
     767             : 
     768             :   //check if peak is ZERO
     769           0 :   if( bamp < 1e-07 ) {
     770           0 :     throw(AipsError("Psf peak is zero"));
     771             :   }
     772             : 
     773             :   //check if peak is outside inner quarter
     774           0 :   if(px < nx/4.0 || px > 3.0*nx/4.0 || py < ny/4.0 || py > 3.0*ny/4.0) {    
     775           0 :     throw(AipsError("Peak of psf is outside the inner quarter of defined image"));
     776             :   }
     777             : 
     778             :  
     779           0 :   if((bamp > 1.1) || (bamp < 0.9)) // No warning if 10% error in PSF peak
     780           0 :     os << LogIO::WARN << "Peak of PSF is " << bamp << LogIO::POST;
     781             : 
     782             : 
     783           0 :   static const Float fdiam = 2.5*abs(deltas(0))/C::arcsec;
     784             : try{  
     785             : 
     786             : 
     787           0 :   if(bamp==0.0) {
     788           0 :           beam[0] = fdiam;
     789           0 :           beam[1] = fdiam;
     790           0 :           beam[2] = 0.0;
     791           0 :     os << LogIO::WARN << "Could not find peak " << LogIO::POST;
     792           0 :     return false;
     793             :   }
     794             :     
     795             : 
     796             :   
     797           0 :   lpsf/=bamp; //Normalize
     798             : 
     799             :   // The selection code attempts to avoid including any sidelobes, even
     800             :   // if they exceed the threshold, by starting from the center column and
     801             :   // working out, exiting the loop when it crosses the threshold.  It
     802             :   // assumes that the first time it finds a "good" point starting from
     803             :   // the center and working out that it's in the main lobe.  Narrow,
     804             :   // sharply ringing beams inclined at 45 degrees will confuse it, but 
     805             :   // that's even more pathological than most VLBI beams.
     806             :   
     807           0 :   Float amin=psfcutoff;
     808           0 :   Int nrow=npix;
     809             :   
     810             :   //we sample the central part of a, 2*nrow+1 by 2*nrow+1
     811           0 :   Bool converg=false;
     812           0 :   Vector<Double> solution;
     813           0 :   Int kounter=0;
     814             :     
     815           0 :  while(amin > 0.009 && !converg && (kounter < 50)){
     816           0 :   kounter+=1;
     817           0 :   Int npoints=0;
     818           0 :   Vector<Double> y, sigma;
     819           0 :   Matrix<Double> x;
     820           0 :   IPosition blc(2), trc(2);
     821             :      
     822           0 :   FindNpoints(npoints, blc, trc, nrow, amin, px, py, deltas, x , y, sigma, lpsf);
     823           0 :   os << LogIO::DEBUG1 << "First FindNpoints is " << npoints << LogIO::POST;
     824             :      
     825           0 :   blc = blc-expand_pixel;
     826           0 :   trc = trc+expand_pixel;
     827             :      
     828           0 :   if(blc(0) < 0) blc(0)=0;
     829           0 :   if(blc(1) < 0) blc(1)=0;
     830           0 :   if(trc(0) >= lpsf.shape()(0)) trc(0)=lpsf.shape()(0)-1;
     831           0 :   if(trc(1) >= lpsf.shape()(1)) trc(1)=lpsf.shape()(1)-1;
     832             :      
     833           0 :   Matrix<Float> lpsfWindowed = lpsf(blc,trc);
     834           0 :   os << LogIO::DEBUG1 << "The windowed Psf shape is " << lpsfWindowed.shape() << LogIO::POST;
     835           0 :   Matrix<Float> resampledPsf;
     836             :      
     837           0 :   Int oversampling = (Int) sqrt(target_npoints/(lpsfWindowed.shape()(0)*lpsfWindowed.shape()(1)));
     838           0 :    if(oversampling == 0){
     839           0 :          oversampling = 1;
     840             :    }
     841           0 :    os << LogIO::DEBUG1 << "The oversampling is " << oversampling << LogIO::POST;
     842             :      
     843           0 :   ResamplePSF(lpsfWindowed, oversampling, resampledPsf,InterpMethod);
     844           0 :   os << LogIO::DEBUG1 << "The resampled windowed Psf shape is " << lpsfWindowed.shape() << LogIO::POST;
     845             :      
     846             :   Float minVal, maxVal;
     847           0 :   IPosition minPos(2);
     848           0 :   IPosition maxPos(2);
     849           0 :   minMax(minVal, maxVal, minPos, maxPos, resampledPsf);
     850           0 :   resampledPsf = resampledPsf/maxVal;
     851             :     
     852           0 :   Vector<Double> resampledDeltas = deltas/ (Double) oversampling;
     853             :      
     854             :   Int minLen;
     855           0 :   if((trc(0) - blc(0)) > (trc(1) - blc(1)) ){
     856           0 :     minLen = trc(1) - blc(1) + 1;
     857             :   }else{
     858           0 :     minLen = trc(0) - blc(0) + 1;
     859             :   }
     860             :      
     861           0 :   Int nrowRe = (Int) (oversampling*minLen - 1)/2;
     862           0 :   FindNpoints(npoints, blc, trc, nrowRe, amin,  maxPos(0), maxPos(1), resampledDeltas, x , y, sigma, resampledPsf);
     863           0 :   os << LogIO::DEBUG1 << "Second FindNpoints is " << npoints << LogIO::POST;
     864             : 
     865           0 :   Gaussian2D<AutoDiff<Double> > gauss2d;
     866           0 :   gauss2d[0] = 1.0; //Height of Gaussian
     867           0 :   gauss2d[1] = 0.0; //The center of the Gaussian in the x direction
     868           0 :   gauss2d[2] = 0.0; //The center of the Gaussian in the y direction.
     869             :   //gauss2d[3] = 2.5*abs(resampledDeltas(0)); //The width (FWHM) of the Gaussian on one axis.
     870           0 :   gauss2d[3] = 2.5*abs(deltas(0));
     871           0 :   gauss2d[4] = 0.5; //A modified axial ratio.
     872             :   
     873             :   // Fix height and center
     874           0 :   gauss2d.mask(0) = false;
     875           0 :   gauss2d.mask(1) = false;
     876           0 :   gauss2d.mask(2) = false;
     877             :   
     878             :   // CAS-13515: Fitting sometimes fails with "NonLinearFitLM: error in loop solution". This occurs in casacore/scimath/Fitting/NonLinearFitLM.tcc LSQFit::invertRect() due to a matrix that can not be inverted.
     879             :   // This problem is solved by retrying fit with a different position angle.
     880           0 :   Bool loopSolutionFound=false;
     881           0 :   Int retryCounter = 0;
     882           0 :   Double posAng = 1.0; //Initial position angle.
     883           0 :   Int nRetries = 10;
     884           0 :   while(!loopSolutionFound && retryCounter < nRetries){
     885             :       //Create casacore fitter and fit Gaussian to subset of PSF interpolated values.
     886           0 :       gauss2d[5] = posAng; //The position angle.
     887           0 :       NonLinearFitLM<Double> fitter;
     888             :       // Set maximum number of iterations to 1000
     889           0 :       fitter.setMaxIter(1000);
     890             :       
     891             :       // Set converge criteria.  Default is 0.001
     892           0 :       fitter.setCriteria(0.0001);
     893             :       
     894             :       // Set the function and initial values
     895           0 :       fitter.setFunction(gauss2d);
     896             :       
     897             :       try{
     898             :           // The current parameter values are used as the initial guess.
     899           0 :           solution = fitter.fit(x, y, sigma);
     900           0 :           loopSolutionFound = true;
     901           0 :       }catch(AipsError x_error){
     902           0 :           loopSolutionFound = false;
     903           0 :           retryCounter++;
     904           0 :           posAng = 1.0 + retryCounter*M_PI/nRetries;
     905           0 :           os << LogIO::NORMAL3 << "Fit failed, another atempt will be made with position angle  " << posAng  << " rad." << LogIO::POST;
     906           0 :       }
     907           0 :       converg=fitter.converged();
     908           0 :   }
     909             :      
     910           0 :   if(!loopSolutionFound)
     911             :   {
     912           0 :     throw(AipsError(String("Error in StokesImageUtil::FitGaussianPSF: error in loop solution.")));
     913             :   }
     914             : 
     915           0 :   if (!converg) {
     916           0 :     beam(0)=2.5*abs(deltas(0))/C::arcsec;
     917           0 :     beam(1)=2.5*abs(deltas(0))/C::arcsec;
     918           0 :     beam(2)=0.0;
     919             : 
     920             :     //fit did not coverge...reduce the minimum i.e expand the field a bit
     921           0 :     amin/=1.5;
     922             :     
     923           0 :     os << LogIO::WARN << "The fit did not coverge; another atempt will be made with psfcutoff " << amin << LogIO::POST;
     924             :   }
     925             :   
     926           0 :  }
     927           0 :  if (converg) {
     928           0 :    if (abs(solution(4))>1.0) {
     929           0 :      beam(0)=abs(solution(3)*solution(4))/C::arcsec;
     930           0 :      beam(1)=abs(solution(3))/C::arcsec;
     931           0 :      beam(2)=solution(5)/C::degree-90.0;
     932             :    } else {
     933           0 :      beam(0)=abs(solution(3))/C::arcsec;
     934           0 :      beam(1)=abs(solution(3)*solution(4))/C::arcsec;
     935           0 :      beam(2)=solution(5)/C::degree;
     936             :    }
     937             :    
     938           0 :    beam(2)=fmod(beam(2), Float(360.0));
     939             :    //while (abs(beam(2)/180.0)> 1) {
     940             :    //  if (beam(2) > 180.0) beam(2)-=360.0;
     941             :    //  else beam(2)+=360.0;
     942             :    //}
     943             :    //CAS-8627: adjust pa to the range -90d, +90d
     944           0 :    while (abs(beam(2)/90.0)> 1) {
     945           0 :      if (beam(2) > 270.0) beam(2)-=360.0;
     946           0 :      else if (beam(2) > 90.0) beam(2) -=180.0;
     947           0 :      else if (beam(2) < -270.0) beam(2) +=360.0;
     948           0 :      else beam(2)+=180.0;
     949             :    }
     950             :      
     951           0 :    return true;
     952             :  }
     953             :  else os << LogIO::WARN << "The fit did not coverge; check your PSF" <<
     954           0 :         LogIO::POST; 
     955           0 :  return false;
     956             : 
     957           0 :  } catch (AipsError x_error) {
     958           0 :          beam[0] = fdiam;
     959           0 :          beam[1] = fdiam;
     960           0 :          beam[2] = 0.0;
     961             :     os << LogIO::SEVERE << "Caught Exception: "<< x_error.getMesg() <<
     962           0 :       LogIO::POST;
     963           0 :     return false;
     964           0 :    } 
     965             : 
     966           0 : }
     967             : 
     968           0 : void StokesImageUtil::locatePeakPSF(ImageInterface<Float>& in, Int& xpos, Int& ypos, Float& amp, Matrix<Float>& lpsf){
     969           0 :   Vector<Int> map;
     970           0 :   AlwaysAssert(StokesMap(map, in.coordinates()), AipsError);
     971             :   
     972           0 :   Int nx = in.shape()(map(0));
     973           0 :   Int ny = in.shape()(map(1));
     974           0 :   Int nchan = in.shape()(map(3));
     975           0 :   xpos=0;
     976           0 :   ypos=0;
     977             :   Float psfmax;
     978             : 
     979           0 :   amp=0;
     980             : 
     981             : 
     982           0 :   IPosition oneplane(in.ndim(), nx, ny, 1, 1);
     983           0 :   LatticeStepper psfls(in.shape(), oneplane,
     984           0 :                        IPosition(4,map(0),map(1),map(3),map(2)));
     985           0 :   RO_LatticeIterator<Float> psfli(in,psfls);
     986           0 :   while (nchan >= 1 && amp < 0.9){
     987           0 :     lpsf=psfli.matrixCursor();
     988             :     
     989           0 :     IPosition psfposmax(lpsf.ndim());
     990           0 :     IPosition psfposmin(lpsf.ndim());
     991             :     Float psfmin;
     992             :     
     993           0 :     minMax(psfmin, psfmax, psfposmin, psfposmax, lpsf); 
     994             :     
     995           0 :     xpos=psfposmax(0);
     996           0 :     ypos=psfposmax(1);
     997             :     
     998             : 
     999             : 
    1000           0 :     amp=lpsf(xpos,ypos);
    1001             : 
    1002           0 :     ++psfli;
    1003           0 :     --nchan;
    1004           0 :   }
    1005             : 
    1006           0 : }
    1007             : 
    1008           0 : void StokesImageUtil::directCFromR(ImageInterface<Complex>& out, const ImageInterface<Float>& in) {
    1009           0 :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1010           0 :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1011           0 :   AlwaysAssert(in.shape()(3)==out.shape()(3), AipsError);
    1012             :   
    1013           0 :   Vector<Int> inmap;
    1014           0 :   AlwaysAssert(StokesMap(inmap, in.coordinates()), AipsError);
    1015           0 :   Vector<Int> outmap;
    1016           0 :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1017             :   
    1018           0 :   Int innpol = in.shape()(inmap(2));
    1019           0 :   Int outnpol = out.shape()(outmap(2));
    1020           0 :   if(innpol != outnpol){
    1021           0 :     throw(AipsError("Cannot convert directly between images of different polarization shape"));
    1022             :   }
    1023           0 :   Vector<Int> inMap(innpol), outMap(outnpol); 
    1024             :   StokesImageUtil::PolRep outPolFrame;
    1025           0 :   Int nStokesOut=CStokesPolMap(outMap, outPolFrame, out.coordinates());
    1026             :   StokesImageUtil::PolRep inPolFrame;
    1027           0 :   Int nStokesIn=CStokesPolMap(inMap, inPolFrame, in.coordinates());
    1028           0 :   AlwaysAssert(nStokesOut, AipsError);
    1029           0 :   AlwaysAssert(nStokesIn, AipsError);
    1030             : 
    1031           0 :   if(inPolFrame != outPolFrame){
    1032           0 :     throw(AipsError("Cannot convert directly between polarization types"));
    1033             :   }
    1034           0 :   IPosition inblc(4,0,0,0,0);
    1035           0 :   IPosition intrc(4,0,0,0,0);
    1036           0 :   intrc(inmap(0))=in.shape()(inmap(0))-1;
    1037           0 :   intrc(inmap(1))=in.shape()(inmap(1))-1;
    1038           0 :   intrc(inmap(2))=0;
    1039           0 :   intrc(inmap(3))= in.shape()(inmap(3))-1;
    1040           0 :   IPosition outblc(4,0,0,0,0);
    1041           0 :   IPosition outtrc(4,0,0,0,0);
    1042           0 :   outtrc(outmap(0))=in.shape()(outmap(0))-1;
    1043           0 :   outtrc(outmap(1))=in.shape()(outmap(1))-1;
    1044           0 :   outtrc(outmap(2))=0;
    1045           0 :   outtrc(outmap(3))= in.shape()(outmap(3))-1;
    1046             :   
    1047           0 :   for (Int k=0; k < innpol ; ++k){
    1048           0 :     inblc(inmap(2))=k;
    1049           0 :     intrc(inmap(2))=k;
    1050           0 :     Int outindex=-1;
    1051           0 :     for ( Int j=0; j < innpol; ++j){
    1052           0 :       if(inMap[k]==outMap[j])
    1053           0 :         outindex=j;
    1054             :     }
    1055           0 :     if(outindex < 0){
    1056           0 :       throw(AipsError("cannot match polarization in direct copy"));
    1057             :     }
    1058           0 :     outblc(outmap(2))=outindex;
    1059           0 :     outtrc(outmap(2))=outindex;
    1060           0 :     Slicer slin(inblc, intrc, Slicer::endIsLast);
    1061           0 :     Slicer slout(outblc, outtrc, Slicer::endIsLast);
    1062           0 :     SubImage<Complex> sliceout(out, slout, true);
    1063           0 :     SubImage<Float> slicein(in, slin);
    1064           0 :     sliceout.copyData(LatticeExpr<Complex>(toComplex(slicein)));
    1065           0 :   }
    1066             : 
    1067             : 
    1068             : 
    1069             : 
    1070           0 : }
    1071             : 
    1072           0 : void StokesImageUtil::directCToR(ImageInterface<Float>& out, ImageInterface<Complex>& in) {
    1073           0 :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1074           0 :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1075           0 :   AlwaysAssert(in.shape()(3)==out.shape()(3), AipsError);
    1076             :   
    1077           0 :   Vector<Int> inmap;
    1078           0 :   AlwaysAssert(StokesMap(inmap, in.coordinates()), AipsError);
    1079           0 :   Vector<Int> outmap;
    1080           0 :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1081             :   
    1082           0 :   Int innpol = in.shape()(inmap(2));
    1083           0 :   Int outnpol = out.shape()(outmap(2));
    1084           0 :   if(innpol != outnpol){
    1085           0 :     throw(AipsError("Cannot convert directly between images of different polarization shape"));
    1086             :   }
    1087           0 :   Vector<Int> inMap(innpol), outMap(outnpol); 
    1088             :   StokesImageUtil::PolRep outPolFrame;
    1089           0 :   Int nStokesOut=CStokesPolMap(outMap, outPolFrame, out.coordinates());
    1090             :   StokesImageUtil::PolRep inPolFrame;
    1091           0 :   Int nStokesIn=CStokesPolMap(inMap, inPolFrame, in.coordinates());
    1092             : 
    1093             : 
    1094           0 :   AlwaysAssert(nStokesOut, AipsError);
    1095           0 :   AlwaysAssert(nStokesIn, AipsError);
    1096           0 :   if(inPolFrame != outPolFrame){
    1097           0 :     throw(AipsError("Cannot convert directly between polarization types"));
    1098             :   }
    1099           0 :   IPosition inblc(4,0,0,0,0);
    1100           0 :   IPosition intrc(4,0,0,0,0);
    1101           0 :   intrc(inmap(0))=in.shape()(inmap(0))-1;
    1102           0 :   intrc(inmap(1))=in.shape()(inmap(1))-1;
    1103           0 :   intrc(inmap(2))=0;
    1104           0 :   intrc(inmap(3))= in.shape()(inmap(3))-1;
    1105           0 :   IPosition outblc(4,0,0,0,0);
    1106           0 :   IPosition outtrc(4,0,0,0,0);
    1107           0 :   outtrc(outmap(0))=in.shape()(outmap(0))-1;
    1108           0 :   outtrc(outmap(1))=in.shape()(outmap(1))-1;
    1109           0 :   outtrc(outmap(2))=0;
    1110           0 :   outtrc(outmap(3))= in.shape()(outmap(3))-1;
    1111             : 
    1112           0 :   for (Int k=0; k < innpol ; ++k){
    1113           0 :     inblc(inmap(2))=k;
    1114           0 :     intrc(inmap(2))=k;
    1115           0 :     Int outindex=-1;
    1116           0 :     for ( Int j=0; j < innpol; ++j){
    1117           0 :       if(inMap[k]==outMap[j])
    1118           0 :         outindex=j;
    1119             :     }
    1120           0 :     if(outindex < 0){
    1121           0 :       throw(AipsError("cannot match polarization in direct copy"));
    1122             :     }
    1123           0 :     outblc(outmap(2))=outindex;
    1124           0 :     outtrc(outmap(2))=outindex;
    1125           0 :     Slicer slin(inblc, intrc, Slicer::endIsLast);
    1126           0 :     Slicer slout(outblc, outtrc, Slicer::endIsLast);
    1127           0 :     SubImage<Float> sliceout(out, slout, true);
    1128           0 :     SubImage<Complex> slicein(in, slin);
    1129           0 :     sliceout.copyData(LatticeExpr<Float>(real(slicein)));
    1130           0 :   }
    1131             :   
    1132             :   
    1133           0 : }
    1134             : 
    1135           0 : void StokesImageUtil::To(ImageInterface<Float>& out, ImageInterface<Complex>& in) {
    1136             :   
    1137           0 :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1138           0 :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1139           0 :   AlwaysAssert(in.shape()(3)==out.shape()(3), AipsError);
    1140             :   
    1141           0 :   Vector<Int> map;
    1142           0 :   AlwaysAssert(StokesMap(map, in.coordinates()), AipsError);
    1143           0 :   Vector<Int> outmap;
    1144           0 :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1145             : 
    1146           0 :   Int nx = in.shape()(map(0));
    1147           0 :   Int innpol = in.shape()(map(2));
    1148           0 :   Int outnpol = out.shape()(outmap(2));
    1149             :   
    1150             :   // Loop over all planes
    1151           0 :   LatticeStepper inls(in.shape(), IPosition(4, nx, 1, innpol, 1),
    1152           0 :                       IPosition(4, map(0), map(2), map(1), map(3)));
    1153           0 :   LatticeStepper outls(out.shape(), IPosition(4, nx, 1, outnpol, 1),
    1154           0 :                        IPosition(4, map(0), map(2), map(1), map(3)));
    1155           0 :   RO_LatticeIterator<Complex> inli(in,  inls);
    1156           0 :   LatticeIterator<Float>  outli(out, outls);
    1157             :   
    1158           0 :   Vector<Int> inMap(innpol), outMap(outnpol);
    1159           0 :   StokesImageUtil::PolRep polFrame=StokesImageUtil::CIRCULAR;
    1160           0 :   Int nStokesIn=CStokesPolMap(inMap, polFrame, in.coordinates());
    1161           0 :   Int nStokesOut=StokesPolMap(outMap, out.coordinates());
    1162             :   
    1163           0 :   if(nStokesOut <=0){
    1164           0 :     directCToR(out, in);
    1165           0 :     return;
    1166             :   }
    1167           0 :   AlwaysAssert(nStokesOut, AipsError);
    1168             :   // Try taking real part only (uses LatticeExpr)
    1169           0 :   if(nStokesIn==0) {
    1170           0 :     nStokesIn=StokesPolMap(inMap, in.coordinates());
    1171           0 :     if(nStokesIn==nStokesOut) {
    1172           0 :       outli=LatticeIterator<Float>  (out, inls); 
    1173             :       //replaced copyData with iteration as it seems to load the whole array in memory
    1174           0 :        for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd();
    1175           0 :          inli++,outli++) {
    1176           0 :          outli.woCursor()=real(inli.cursor());
    1177             : 
    1178             :        }
    1179             :       
    1180             : 
    1181             :        // out.copyData(LatticeExpr<Float>(real(in)));
    1182           0 :       return;
    1183             :     }
    1184           0 :     throw(AipsError("Illegal conversion in ToStokesImage"));
    1185             :   }
    1186             :   
    1187           0 :   Vector<Complex> cs(4);
    1188           0 :   cs=Complex(0.0);
    1189           0 :   CStokesVector csv(0.0, 0.0, 0.0, 0.0);
    1190           0 :   StokesVector sv(0.0, 0.0, 0.0, 0.0);
    1191             :   Int pol;
    1192           0 :   if(nStokesIn==1) {
    1193           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd();
    1194           0 :          inli++,outli++) {
    1195           0 :       for (Int ix=0;ix<nx;ix++) {
    1196           0 :         cs(inMap(0))=inli.vectorCursor()(ix);
    1197           0 :         csv=CStokesVector(cs(0), cs(1), cs(2), cs(3));
    1198           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1199           0 :           applySlinInv(sv, csv);
    1200             :         }
    1201             :         else {
    1202           0 :           applyScircInv(sv, csv);
    1203             :         }
    1204           0 :         if(nStokesOut==1) {
    1205           0 :           outli.rwVectorCursor()(ix)=sv(outMap(0));
    1206             :         }
    1207             :         else {
    1208           0 :           for (pol=0;pol<outnpol;pol++)
    1209           0 :             outli.rwMatrixCursor()(ix,pol)=sv(outMap(pol));
    1210             :         }
    1211             :       }
    1212             :     }
    1213             :   }
    1214             :   else {
    1215           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd(); inli++,outli++) {
    1216           0 :       for (Int ix=0;ix<nx;ix++) {
    1217           0 :         cs=Complex(0.0);
    1218           0 :         for (pol=0;pol<innpol;pol++) cs(inMap(pol))=inli.matrixCursor()(ix,pol);
    1219           0 :         csv=CStokesVector(cs(0), cs(1), cs(2), cs(3));
    1220           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1221           0 :           applySlinInv(sv, csv);
    1222             :         }
    1223             :         else {
    1224           0 :           applyScircInv(sv, csv);
    1225             :         }
    1226           0 :         if(nStokesOut==1) {
    1227           0 :           outli.rwVectorCursor()(ix)=sv(outMap(0));
    1228             :         }
    1229             :         else {
    1230           0 :           for (pol=0;pol<outnpol;pol++) {
    1231           0 :             outli.rwMatrixCursor()(ix,pol)=sv(outMap(pol));
    1232             :           }
    1233             :         }
    1234             :       }
    1235             :     }
    1236             :   }
    1237           0 : };
    1238             : 
    1239           0 : void StokesImageUtil::ToStokesPSF(ImageInterface<Float>& out, ImageInterface<Complex>& in) {
    1240             :   
    1241           0 :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1242           0 :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1243           0 :   AlwaysAssert(in.shape()(3)==out.shape()(3), AipsError);
    1244             :   
    1245           0 :   Vector<Int> map;
    1246           0 :   AlwaysAssert(StokesMap(map, in.coordinates()), AipsError);
    1247           0 :   Vector<Int> outmap;
    1248           0 :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1249             :   
    1250           0 :   Int nx = in.shape()(map(0));
    1251           0 :   Int innpol = in.shape()(map(2));
    1252           0 :   Int outnpol = out.shape()(outmap(2));
    1253             :   
    1254             :   // Loop over all planes
    1255           0 :   LatticeStepper inls(in.shape(), IPosition(4, nx, 1, innpol, 1),
    1256           0 :                       IPosition(4, map(0), map(2), map(1), map(3)));
    1257           0 :   LatticeStepper outls(out.shape(), IPosition(4, nx, 1, outnpol, 1),
    1258           0 :                        IPosition(4, map(0), map(2), map(1), map(3)));
    1259           0 :   RO_LatticeIterator<Complex> inli(in,  inls);
    1260           0 :   LatticeIterator<Float>  outli(out, outls);
    1261             :   
    1262           0 :   Vector<Int> inMap(innpol), outMap(outnpol);
    1263           0 :   StokesImageUtil::PolRep polFrame=StokesImageUtil::CIRCULAR;
    1264           0 :   Int nStokesIn=CStokesPolMap(inMap, polFrame, in.coordinates());
    1265           0 :   Int nStokesOut=StokesPolMap(outMap, out.coordinates());
    1266           0 :   if(nStokesOut <=0){
    1267           0 :     directCToR(out, in);
    1268           0 :     return;
    1269             :   }
    1270           0 :   AlwaysAssert(nStokesOut, AipsError);
    1271             :   // Try taking real part only (uses LatticeExpr)
    1272           0 :   if(nStokesIn==0) {
    1273           0 :     nStokesIn=StokesPolMap(inMap, in.coordinates());
    1274           0 :     if(nStokesIn==nStokesOut) {
    1275             :       //replaced copyData with iteration as it seems to load the whole array in memory
    1276           0 :       outli=LatticeIterator<Float>  (out, inls);
    1277           0 :       for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd();
    1278           0 :          inli++,outli++) {
    1279           0 :          outli.woCursor()=real(inli.cursor());
    1280             : 
    1281             :        }
    1282             :       
    1283             :       //out.copyData(LatticeExpr<Float>(real(in)));
    1284           0 :       return;
    1285             :     }
    1286           0 :     throw(AipsError("Illegal conversion in ToStokesImage"));
    1287             :   }
    1288             : 
    1289             :   /* STOKESDBG */  //cout << "ToStokesPSF - nstokesIn :  " <<  nStokesIn << " inmap : " << inMap << "  nstokesOut : " << nStokesOut << " outmap : " << outMap << endl;
    1290             :   /* STOKESDBG */  //cout << "IN (data) stokesCoord : " << ( (in.coordinates()).stokesCoordinate( (in.coordinates()).findCoordinate(Coordinate::STOKES)  ) ).stokes() << "     OUT (image) stokesCoord : " << ( (out.coordinates()).stokesCoordinate( (out.coordinates()).findCoordinate(Coordinate::STOKES)  ) ).stokes() << endl;
    1291             : 
    1292           0 :   Vector<Int> inST =  ( (in.coordinates()).stokesCoordinate( (in.coordinates()).findCoordinate(Coordinate::STOKES)  ) ).stokes();
    1293           0 :   Vector<Int> outST = ( (out.coordinates()).stokesCoordinate( (out.coordinates()).findCoordinate(Coordinate::STOKES)  ) ).stokes();
    1294             : 
    1295           0 :   Vector<Complex> cs(4);
    1296           0 :   cs=Complex(0.0);
    1297           0 :   CStokesVector csv(0.0, 0.0, 0.0, 0.0);
    1298           0 :   StokesVector sv(0.0, 0.0, 0.0, 0.0);
    1299             :   Int pol;
    1300           0 :   if(nStokesIn==1) {
    1301           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd();
    1302           0 :          inli++,outli++) {
    1303           0 :       for (Int ix=0;ix<nx;ix++) {
    1304           0 :         cs(inMap(0))=inli.vectorCursor()(ix);
    1305           0 :         csv=CStokesVector(cs(0), cs(1), cs(2), cs(3));
    1306           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1307           0 :           applySlinInv(sv, csv);
    1308             :         }
    1309             :         else {
    1310           0 :           applyScircInv(sv, csv);
    1311             :         }
    1312             :         // nstokesout will be 1, 2 or 4 only.
    1313           0 :         if(nStokesOut==1) {
    1314             :           //outli.rwVectorCursor()(ix)=sv(0); //sv(outMap(0));
    1315             :           // If outstokescoord = I or Q, use (I:0) : XX+YY for the PSF
    1316             :           // If outstokescoord = U or V, use (U:2) : XY+YX  for the PSF
    1317           0 :           if( polFrame==StokesImageUtil::LINEAR )
    1318             :             { 
    1319           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::Q ) 
    1320           0 :                   outli.rwVectorCursor()(ix)=sv(0);
    1321           0 :               if( Stokes::type(outST[0])==Stokes::U || Stokes::type(outST[0])==Stokes::V ) 
    1322           0 :                   outli.rwVectorCursor()(ix)=sv(2);
    1323             :             }
    1324           0 :           if( polFrame==StokesImageUtil::CIRCULAR )
    1325             :             { 
    1326           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::V ) 
    1327           0 :                   outli.rwVectorCursor()(ix)=sv(0);
    1328           0 :               if( Stokes::type(outST[0])==Stokes::Q || Stokes::type(outST[0])==Stokes::U ) 
    1329           0 :                   outli.rwVectorCursor()(ix)=sv(1);
    1330             :             }
    1331             :         }
    1332           0 :         else if(nStokesOut==2) {
    1333             :           // If outstokescoord = IQ, use (I:0) : XX+YY for the PSF in both planes
    1334             :           // If outstokescoord = UV, use (U:2) : XY+YX  for the PSF in both planes
    1335           0 :          if( polFrame==StokesImageUtil::LINEAR )
    1336             :             { 
    1337           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::Q || 
    1338           0 :                  Stokes::type(outST[1])==Stokes::I || Stokes::type(outST[1])==Stokes::Q ) 
    1339           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(0);   outli.rwMatrixCursor()(ix,1)=sv(0); }
    1340           0 :               if( Stokes::type(outST[0])==Stokes::U || Stokes::type(outST[0])==Stokes::V ||
    1341           0 :                   Stokes::type(outST[1])==Stokes::U || Stokes::type(outST[1])==Stokes::V ) 
    1342           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(2); outli.rwMatrixCursor()(ix,1)=sv(2); }
    1343             :             }
    1344           0 :           if( polFrame==StokesImageUtil::CIRCULAR )
    1345             :             { 
    1346           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::V ||
    1347           0 :                  Stokes::type(outST[1])==Stokes::I || Stokes::type(outST[1])==Stokes::V ) 
    1348           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(0); outli.rwMatrixCursor()(ix,1)=sv(0); }
    1349           0 :               if( Stokes::type(outST[0])==Stokes::Q || Stokes::type(outST[0])==Stokes::U ||
    1350           0 :                   Stokes::type(outST[1])==Stokes::Q || Stokes::type(outST[1])==Stokes::U ) 
    1351           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(1); outli.rwMatrixCursor()(ix,1)=sv(1); }
    1352             :             }
    1353             :         }
    1354             :         else { // nstokesout = 4  : do a one-to-one mapping.
    1355           0 :           for (pol=0;pol<outnpol;pol++)
    1356           0 :             outli.rwMatrixCursor()(ix,pol)=sv(outMap(pol));
    1357             :         }
    1358             :       }
    1359             :     }
    1360             :   }
    1361             :   else {
    1362           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd(); inli++,outli++) {
    1363           0 :       for (Int ix=0;ix<nx;ix++) {
    1364           0 :         cs=Complex(0.0);
    1365           0 :         for (pol=0;pol<innpol;pol++) cs(inMap(pol))=inli.matrixCursor()(ix,pol);
    1366           0 :         csv=CStokesVector(cs(0), cs(1), cs(2), cs(3));
    1367           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1368           0 :           applySlinInv(sv, csv);
    1369             :         }
    1370             :         else {
    1371           0 :           applyScircInv(sv, csv);
    1372             :         }
    1373           0 :         if(nStokesOut==1) {
    1374             :           //outli.rwVectorCursor()(ix)=sv(0); //sv(outMap(0));
    1375             :           // If outstokescoord = I or Q, use (I:0)
    1376             :           // If outstokescoord = U or V, use (U:2)
    1377           0 :           if( polFrame==StokesImageUtil::LINEAR )
    1378             :             { 
    1379           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::Q ) 
    1380           0 :                   outli.rwVectorCursor()(ix)=sv(0);
    1381           0 :               if( Stokes::type(outST[0])==Stokes::U || Stokes::type(outST[0])==Stokes::V ) 
    1382           0 :                   outli.rwVectorCursor()(ix)=sv(2);
    1383             :             }
    1384           0 :           if( polFrame==StokesImageUtil::CIRCULAR )
    1385             :             { 
    1386           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::V ) 
    1387           0 :                   outli.rwVectorCursor()(ix)=sv(0);
    1388           0 :               if( Stokes::type(outST[0])==Stokes::Q || Stokes::type(outST[0])==Stokes::U ) 
    1389           0 :                   outli.rwVectorCursor()(ix)=sv(1);
    1390             :             }
    1391             :         }
    1392           0 :         else if(nStokesOut==2) {
    1393             :           // If outstokescoord = IQ, use (I:0) : XX+YY for the PSF in both planes
    1394             :           // If outstokescoord = UV, use (U:2) : XY+YX  for the PSF in both planes
    1395           0 :          if( polFrame==StokesImageUtil::LINEAR )
    1396             :             { 
    1397           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::Q || 
    1398           0 :                  Stokes::type(outST[1])==Stokes::I || Stokes::type(outST[1])==Stokes::Q ) 
    1399           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(0);   outli.rwMatrixCursor()(ix,1)=sv(0); }
    1400           0 :               if( Stokes::type(outST[0])==Stokes::U || Stokes::type(outST[0])==Stokes::V ||
    1401           0 :                   Stokes::type(outST[1])==Stokes::U || Stokes::type(outST[1])==Stokes::V ) 
    1402           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(2); outli.rwMatrixCursor()(ix,1)=sv(2); }
    1403             :             }
    1404           0 :           if( polFrame==StokesImageUtil::CIRCULAR )
    1405             :             { 
    1406           0 :               if(Stokes::type(outST[0])==Stokes::I || Stokes::type(outST[0])==Stokes::V ||
    1407           0 :                  Stokes::type(outST[1])==Stokes::I || Stokes::type(outST[1])==Stokes::V ) 
    1408           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(0); outli.rwMatrixCursor()(ix,1)=sv(0); }
    1409           0 :               if( Stokes::type(outST[0])==Stokes::Q || Stokes::type(outST[0])==Stokes::U ||
    1410           0 :                   Stokes::type(outST[1])==Stokes::Q || Stokes::type(outST[1])==Stokes::U ) 
    1411           0 :                 { outli.rwMatrixCursor()(ix,0)=sv(1); outli.rwMatrixCursor()(ix,1)=sv(1); }
    1412             :             }
    1413             :         }
    1414             :         else { // nstokesout = 4
    1415           0 :           for (pol=0;pol<outnpol;pol++) {
    1416           0 :             outli.rwMatrixCursor()(ix,pol)=sv(outMap(0));
    1417             :           }
    1418             :         }
    1419             :       }
    1420             :     }
    1421             :   }
    1422           0 : };
    1423             : 
    1424           0 : void StokesImageUtil::ToStokesSumWt(Matrix<Float> sumwtStokes, Matrix<Float> sumwtCorr, const CoordinateSystem& outcoord, const CoordinateSystem& incoord)
    1425             : {
    1426             : 
    1427           0 :   AlwaysAssert( sumwtStokes.shape()[1] == sumwtCorr.shape()(1) , AipsError );
    1428           0 :   Vector<Int> inmap;
    1429           0 :   AlwaysAssert(StokesMap(inmap, incoord), AipsError);
    1430           0 :   Vector<Int> outmap;
    1431           0 :   AlwaysAssert(StokesMap(outmap, outcoord), AipsError);
    1432             : 
    1433             :   
    1434           0 :   Int innpol = sumwtCorr.shape()[0];
    1435           0 :   Int outnpol = sumwtStokes.shape()[0];
    1436             :   
    1437             :   
    1438           0 :   Vector<Int> inMap(innpol), outMap(outnpol);
    1439           0 :   StokesImageUtil::PolRep polFrame=StokesImageUtil::CIRCULAR;
    1440           0 :   Int nStokesIn=CStokesPolMap(inMap, polFrame, incoord);
    1441           0 :   Int nStokesOut=StokesPolMap(outMap, outcoord);
    1442           0 :   if(nStokesOut <=0  || nStokesIn==0)  {
    1443           0 :     if(innpol != outnpol)
    1444           0 :       throw(AipsError("Cannot copy sumwt as input and output have different pol axis length"));
    1445           0 :     convertArray(sumwtStokes, sumwtCorr);
    1446           0 :     return;
    1447             :   }
    1448           0 :   if( nStokesOut==1 && nStokesIn==2){
    1449             :     
    1450           0 :     for(uInt chan=0;chan<sumwtStokes.shape()[1];chan++)
    1451             :       {
    1452           0 :         sumwtStokes(0,chan) = min(sumwtCorr(0,chan),sumwtCorr(1, chan));
    1453             :       }     
    1454             :   }
    1455           0 :  if( nStokesOut==2 && nStokesIn==2){
    1456             :     
    1457           0 :     for(uInt chan=0;chan<sumwtStokes.shape()[1];chan++)
    1458             :       {
    1459           0 :         sumwtStokes(0,chan) = min(sumwtCorr(0,chan),sumwtCorr(1, chan));
    1460           0 :         sumwtStokes(1,chan) = min(sumwtCorr(1,chan),sumwtCorr(1, chan));
    1461             :       }     
    1462             :   } 
    1463           0 :  if( nStokesOut==4 && nStokesIn==4){
    1464             :     
    1465           0 :    for(uInt chan=0;chan<sumwtStokes.shape()[1];chan++)
    1466             :      {
    1467           0 :        if(polFrame==StokesImageUtil::LINEAR){
    1468           0 :          sumwtStokes(0,chan) = min(sumwtCorr(0,chan),sumwtCorr(3, chan));
    1469           0 :          sumwtStokes(1,chan) = min(sumwtCorr(0,chan),sumwtCorr(3, chan));
    1470           0 :          sumwtStokes(2,chan) = min(sumwtCorr(1,chan),sumwtCorr(2, chan));
    1471           0 :          sumwtStokes(3,chan) = min(sumwtCorr(1,chan),sumwtCorr(2, chan));
    1472             :        }
    1473             :        else{
    1474           0 :          sumwtStokes(0,chan) = min(sumwtCorr(0,chan),sumwtCorr(3, chan));
    1475           0 :          sumwtStokes(1,chan) = min(sumwtCorr(1,chan),sumwtCorr(2, chan));
    1476           0 :          sumwtStokes(2,chan) = min(sumwtCorr(1,chan),sumwtCorr(2, chan));
    1477           0 :          sumwtStokes(3,chan) = min(sumwtCorr(0,chan),sumwtCorr(3, chan));
    1478             :        }
    1479             :      } 
    1480             :  }
    1481             :   
    1482             : 
    1483           0 : }
    1484             : 
    1485           0 : void StokesImageUtil::ToStokesSumWt(Matrix<Float> sumwtStokes, Matrix<Float> sumwtCorr)
    1486             : {
    1487           0 :   AlwaysAssert( sumwtStokes.shape()[1] == sumwtCorr.shape()(1) , AipsError ); //same nchan
    1488           0 :   AlwaysAssert( sumwtCorr.shape()[0] > 0, AipsError ); // at least one correlation gridded.
    1489             : 
    1490             :   /// Pick the value from the first correlation plane, and fill it into all stokes planes.
    1491             :   /// This is valid when the same weights are used across correlations.
    1492           0 :   for(uInt pol=0;pol<sumwtStokes.shape()[0];pol++)
    1493             :     {
    1494           0 :       for(uInt chan=0;chan<sumwtStokes.shape()[1];chan++)
    1495             :         {
    1496           0 :           sumwtStokes(pol,chan) = sumwtCorr(0,chan);
    1497             :         }
    1498             :     }
    1499             : 
    1500           0 : }
    1501             : 
    1502             : 
    1503             : #if 0
    1504             : void StokesImageUtil::ToStokesPSF(ImageInterface<Float>& out, ImageInterface<Complex>& in) {
    1505             :   
    1506             :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1507             :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1508             :   AlwaysAssert(out.shape()(2)==out.shape()(3), AipsError);
    1509             :   AlwaysAssert(in.shape()(3)==out.shape()(4), AipsError);
    1510             :   
    1511             :   Vector<Int> map;
    1512             :   AlwaysAssert(StokesMap(map, in.coordinates()), AipsError);
    1513             :   Vector<Int> outmap;
    1514             :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1515             :   
    1516             :   Int nx = in.shape()(map(0));
    1517             :   Int innpol = in.shape()(map(2));
    1518             :   Int outnpol = out.shape()(outmap(2));
    1519             :   
    1520             :   // Loop over all planes. For the input we get a line of complex pixels
    1521             :   // for the output we put a line of float matrices
    1522             :   LatticeStepper inls(in.shape(), IPosition(4, nx, 1, innpol, 1),
    1523             :                       IPosition(4, map(0), map(2), map(1), map(3)));
    1524             :   LatticeStepper outls(out.shape(), IPosition(5, nx, 1, outnpol, outnpol, 1),
    1525             :                        IPosition(5, map(0), map(3), map(1), map(2), 4));
    1526             :   RO_LatticeIterator<Complex> inli(in,  inls);
    1527             :   LatticeIterator<Float>  outli(out, outls);
    1528             :   
    1529             :   Vector<Int> inMap(innpol), outMap(outnpol);
    1530             :   StokesImageUtil::PolRep polFrame;
    1531             :   Int nStokesIn=CStokesPolMap(inMap, polFrame, in.coordinates());
    1532             :   AlwaysAssert(nStokesIn, AipsError);
    1533             :   Int nStokesOut=StokesPolMap(outMap, out.coordinates());
    1534             :   AlwaysAssert(nStokesOut, AipsError);
    1535             :   
    1536             :   Matrix<Complex> s(4,4), sAdjoint(4,4);
    1537             :   s=0;
    1538             :   if(polFrame==StokesImageUtil::LINEAR) {
    1539             :     s(0,0)=Complex(0.5);
    1540             :     s(0,1)=Complex(0.5);
    1541             :     s(1,2)=Complex(0.5);
    1542             :     s(1,3)=Complex(0.0,0.5);
    1543             :     s(2,2)=Complex(0.5);
    1544             :     s(2,3)=Complex(0.0,-0.5);
    1545             :     s(3,0)=Complex(0.5);
    1546             :     s(3,1)=Complex(-0.5);
    1547             :   }
    1548             :   else {
    1549             :     s(0,0)=Complex(0.5);
    1550             :     s(0,3)=Complex(0.5);
    1551             :     s(1,1)=Complex(0.5);
    1552             :     s(1,2)=Complex(0.0,0.5);
    1553             :     s(2,1)=Complex(0.5);
    1554             :     s(2,2)=Complex(0.0,-0.5);
    1555             :     s(3,0)=Complex(0.5);
    1556             :     s(3,3)=Complex(-0.5);
    1557             :   }
    1558             :   sAdjoint=adjoint(s);
    1559             :   
    1560             :   Matrix<Complex> lambda(4,4);
    1561             :   lambda=Complex(0.0);
    1562             :   
    1563             :   Matrix<Float> stokesPSF(4,4);
    1564             :   Int i, j;
    1565             :   for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd(); inli++,outli++) {
    1566             :     for (Int ix=0;ix<nx;ix++) {
    1567             :       // Get the channel
    1568             :       // Fill in the weight vector
    1569             :       if(innpol==1) {
    1570             :         lambda(inMap(0),inMap(0))=inli.vectorCursor()(ix);
    1571             :       }
    1572             :       else {
    1573             :         for (i=0;i<innpol;i++) lambda(inMap(i),inMap(i))=
    1574             :                                  inli.matrixCursor()(ix,i);
    1575             :       }
    1576             :       stokesPSF=real(product(s,product(lambda, sAdjoint)));
    1577             :       if(nStokesOut==1) {
    1578             :         outli.rwVectorCursor()(ix)=stokesPSF(outMap(0),outMap(0));
    1579             :       }
    1580             :       else {
    1581             :         for (j=0;j<outnpol;j++) {
    1582             :           for (i=0;i<outnpol;i++) {
    1583             :             outli.rwCubeCursor()(ix,i,j)=stokesPSF(outMap(i),outMap(j));
    1584             :           }
    1585             :         }
    1586             :       }
    1587             :     }
    1588             :   }
    1589             : };
    1590             : #endif
    1591             : 
    1592           0 : void StokesImageUtil::From(ImageInterface<Complex>& out,
    1593             :                            const ImageInterface<Float>& in) {
    1594             :   
    1595           0 :   AlwaysAssert(in.shape()(0)==out.shape()(0), AipsError);
    1596           0 :   AlwaysAssert(in.shape()(1)==out.shape()(1), AipsError);
    1597           0 :   AlwaysAssert(in.shape()(3)==out.shape()(3), AipsError);
    1598             :   
    1599             :   
    1600           0 :   Vector<Int> map;
    1601           0 :   AlwaysAssert(StokesMap(map, in.coordinates()), AipsError);
    1602           0 :   Vector<Int> outmap;
    1603           0 :   AlwaysAssert(StokesMap(outmap, out.coordinates()), AipsError);
    1604             :   
    1605           0 :   Int nx = in.shape()(map(0));
    1606           0 :   Int innpol = in.shape()(map(2));
    1607           0 :   Int outnpol = out.shape()(outmap(2));
    1608             :   
    1609           0 :   Vector<Int> inMap(innpol), outMap(outnpol);
    1610           0 :   StokesImageUtil::PolRep polFrame=StokesImageUtil::LINEAR;
    1611           0 :   Int nStokesIn=StokesPolMap(inMap, in.coordinates());
    1612           0 :   if(nStokesIn <=0){
    1613           0 :     directCFromR(out, in);
    1614           0 :     return;
    1615             :   }
    1616           0 :   AlwaysAssert(nStokesIn, AipsError);
    1617           0 :   Int nStokesOut=CStokesPolMap(outMap, polFrame, out.coordinates());
    1618           0 :   if(nStokesOut==0) {
    1619           0 :     nStokesOut=StokesPolMap(outMap, out.coordinates());
    1620           0 :     if(nStokesIn==nStokesOut) {
    1621           0 :       out.copyData(LatticeExpr<Complex>(toComplex(in)));
    1622           0 :       return;
    1623             :     }
    1624           0 :     throw(AipsError("Illegal conversion in FromStokesImage"));
    1625             :   }
    1626             :   
    1627             :   // Loop over all planes
    1628           0 :   LatticeStepper inls(in.shape(), IPosition(4, nx, 1, innpol, 1),
    1629           0 :                       IPosition(4, map(0), map(2), map(1), map(3)));
    1630           0 :   LatticeStepper outls(out.shape(), IPosition(4, nx, 1, outnpol, 1),
    1631           0 :                        IPosition(4, map(0), map(2), map(1), map(3)));
    1632           0 :   RO_LatticeIterator<Float> inli(in,  inls);
    1633           0 :   LatticeIterator<Complex>  outli(out, outls);
    1634             :   
    1635           0 :   Vector<Float> s(4);
    1636           0 :   CStokesVector csv(0.0, 0.0, 0.0, 0.0);
    1637           0 :   StokesVector sv(0.0, 0.0, 0.0, 0.0);
    1638             :   Int pol;
    1639           0 :   if(nStokesIn==1) {
    1640           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd(); inli++,outli++) {
    1641           0 :       for (Int ix=0;ix<nx;ix++) {
    1642           0 :         s=0.0;
    1643           0 :         s(inMap(0))=inli.vectorCursor()(ix);
    1644           0 :         sv=StokesVector(s(0), s(1), s(2), s(3));
    1645           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1646           0 :           applySlin(csv, sv);
    1647             :         }
    1648             :         else {
    1649           0 :           applyScirc(csv, sv);
    1650             :         }
    1651           0 :         if(nStokesOut==1) {
    1652           0 :           outli.rwVectorCursor()(ix)=csv(outMap(0));
    1653             :         }
    1654             :         else {
    1655           0 :           for (pol=0;pol<outnpol;pol++) {
    1656           0 :             outli.rwMatrixCursor()(ix,pol)=csv(outMap(pol));
    1657             :           }
    1658             :         }
    1659             :       }
    1660             :     }
    1661             :   }
    1662             :   else {
    1663           0 :     for (inli.reset(), outli.reset(); !inli.atEnd() && !outli.atEnd(); inli++,outli++) {
    1664           0 :       for (Int ix=0;ix<nx;ix++) {
    1665           0 :         s=0.0;
    1666           0 :         for(pol=0;pol<innpol;pol++) s(inMap(pol))=inli.matrixCursor()(ix,pol);
    1667           0 :         sv=StokesVector(s(0), s(1), s(2), s(3));
    1668           0 :         if(polFrame==StokesImageUtil::LINEAR) {
    1669           0 :           applySlin(csv, sv);
    1670             :         }
    1671             :         else {
    1672           0 :           applyScirc(csv, sv);
    1673             :         }
    1674           0 :         if(nStokesOut==1) {
    1675           0 :           outli.rwVectorCursor()(ix)=csv(outMap(0));
    1676             :         }
    1677             :         else {
    1678           0 :           for (pol=0;pol<outnpol;pol++) {
    1679           0 :             outli.rwMatrixCursor()(ix,pol)=csv(outMap(pol));
    1680             :           }
    1681             :         }
    1682             :       }
    1683             :     }
    1684             :   }
    1685           0 : };
    1686             : 
    1687             : // map(axis) is the polarization in the sequence I,Q,U,V
    1688             : // This is the sequence used by StokesVector
    1689           0 : Int StokesImageUtil::StokesPolMap(Vector<Int>& map, const CoordinateSystem& coord) {
    1690             :   
    1691           0 :   map=-1;
    1692             :   Int stokesIndex;
    1693           0 :   stokesIndex= coord.findCoordinate(Coordinate::STOKES);
    1694           0 :   StokesCoordinate stokesCoord=coord.stokesCoordinate(stokesIndex);
    1695             :   Int pol, p;
    1696           0 :   Bool Found= stokesCoord.toPixel(p, Stokes::I)||
    1697           0 :     stokesCoord.toPixel(p, Stokes::Q)||
    1698           0 :     stokesCoord.toPixel(p, Stokes::U)||
    1699           0 :     stokesCoord.toPixel(p, Stokes::V);
    1700           0 :   if(Found) {
    1701           0 :     pol=0;
    1702           0 :     Int found=0;
    1703           0 :     if(stokesCoord.toPixel(p, Stokes::I)) {map(p)=pol;found++;} pol++;
    1704           0 :     if(stokesCoord.toPixel(p, Stokes::Q)) {map(p)=pol;found++;} pol++;
    1705           0 :     if(stokesCoord.toPixel(p, Stokes::U)) {map(p)=pol;found++;} pol++;
    1706           0 :     if(stokesCoord.toPixel(p, Stokes::V)) {map(p)=pol;found++;} pol++;
    1707           0 :     return found;
    1708             :   }
    1709           0 :   return 0;
    1710           0 : }
    1711             : 
    1712             : // map(axis) is the polarization in the sequence XX,XY,YX,YY or RR,RL,LR,LL.
    1713             : // This is the sequence used by CStokesVector
    1714           0 : Int StokesImageUtil::CStokesPolMap(Vector<Int>& map, StokesImageUtil::PolRep& polFrame,
    1715             :                                    const CoordinateSystem& coord) {
    1716             :   
    1717           0 :   map=-1;
    1718             :   Int stokesIndex;
    1719           0 :   stokesIndex=coord.findCoordinate(Coordinate::STOKES);
    1720           0 :   StokesCoordinate stokesCoord=coord.stokesCoordinate(stokesIndex);
    1721             :   Int pol, p;
    1722           0 :   Int found=0;
    1723           0 :   Bool Linear= stokesCoord.toPixel(p, Stokes::XX)||
    1724           0 :     stokesCoord.toPixel(p, Stokes::XY)||
    1725           0 :     stokesCoord.toPixel(p, Stokes::YX)||
    1726           0 :     stokesCoord.toPixel(p, Stokes::YY);
    1727           0 :   if(Linear) {
    1728           0 :     pol=0;
    1729           0 :     if(stokesCoord.toPixel(p, Stokes::XX)) {map(p)=pol;found++;} pol++;
    1730           0 :     if(stokesCoord.toPixel(p, Stokes::XY)) {map(p)=pol;found++;} pol++;
    1731           0 :     if(stokesCoord.toPixel(p, Stokes::YX)) {map(p)=pol;found++;} pol++;
    1732           0 :     if(stokesCoord.toPixel(p, Stokes::YY)) {map(p)=pol;found++;} pol++;
    1733           0 :     polFrame=StokesImageUtil::LINEAR;
    1734           0 :     return found;
    1735             :   }
    1736           0 :   Bool Circular= stokesCoord.toPixel(p, Stokes::LL)||
    1737           0 :     stokesCoord.toPixel(p, Stokes::LR)||
    1738           0 :     stokesCoord.toPixel(p, Stokes::RL)||
    1739           0 :     stokesCoord.toPixel(p, Stokes::RR);
    1740             : 
    1741             : 
    1742           0 :   if(Circular) {
    1743           0 :     pol=0;
    1744           0 :     if(stokesCoord.toPixel(p, Stokes::RR)) {map(p)=pol;found++;} pol++;
    1745           0 :     if(stokesCoord.toPixel(p, Stokes::RL)) {map(p)=pol;found++;} pol++;
    1746           0 :     if(stokesCoord.toPixel(p, Stokes::LR)) {map(p)=pol;found++;} pol++;
    1747           0 :     if(stokesCoord.toPixel(p, Stokes::LL)) {map(p)=pol;found++;} pol++;
    1748           0 :     polFrame=StokesImageUtil::CIRCULAR;
    1749           0 :     return found;
    1750             :   }
    1751           0 :   return 0;
    1752           0 : }
    1753             : 
    1754           0 : CoordinateSystem StokesImageUtil::StokesCoordFromMS(const IPosition& shape, Vector<Double>& deltas,
    1755             :                                                     MeasurementSet& ms) {
    1756           0 :   Vector<Int> whichStokes(0);
    1757           0 :   return StokesCoordFromMS(shape, deltas, ms, whichStokes);
    1758           0 : }
    1759             : 
    1760           0 : CoordinateSystem StokesImageUtil::StokesCoordFromMS(const IPosition& shape, Vector<Double>& deltas,
    1761             :                                                     MeasurementSet& ms, Vector<Int>& whichStokes,
    1762             :                                                     Bool doCStokes, Int fieldID, Int SPWID, Int feedID) {
    1763             :   
    1764           0 :   MSColumns msc(ms);
    1765             :   
    1766           0 :   Int nx=shape(0);
    1767           0 :   Int ny=shape(1);
    1768           0 :   Int npol=shape(2);
    1769           0 :   Int nchan=shape(3);
    1770             :   
    1771           0 :   Vector<Double> refCoord=msc.field().phaseDir()(fieldID); 
    1772           0 :   Vector<Double> refPixel(2); 
    1773           0 :   refPixel(0)=Double(nx/2);
    1774           0 :   refPixel(1)=Double(ny/2);
    1775             :   
    1776           0 :   Matrix<Double> xform(2,2);
    1777           0 :   xform=0.0;xform.diagonal()=1.0;
    1778             :   DirectionCoordinate myRaDec(MDirection::J2000,
    1779             :                               Projection::SIN,
    1780           0 :                               refCoord(0), refCoord(1),
    1781           0 :                               deltas(0), deltas(1),
    1782             :                               xform,
    1783           0 :                               refPixel(0), refPixel(1));
    1784             :   
    1785             :   // Frequency
    1786           0 :   Vector<Double> chanFreq=msc.spectralWindow().chanFreq()(SPWID); 
    1787           0 :   if(nchan==0) nchan=chanFreq.shape()(SPWID);
    1788           0 :   Double refChan=0.0;
    1789           0 :   Vector<Double> freqResolution=msc.spectralWindow().resolution()(SPWID); 
    1790             : 
    1791             :   // Retrieve the first rest frequency used with this SPW_ID (for now)
    1792           0 :   MSDopplerUtil msdoppler(ms);
    1793           0 :   Vector<Double> restFreqArray;
    1794             :   Double restFreq;
    1795           0 :   if (msdoppler.dopplerInfo(restFreqArray,SPWID,fieldID)) {
    1796           0 :     restFreq=restFreqArray(0);
    1797             :   } else {
    1798           0 :     restFreq=1.0;
    1799             :   };
    1800             :   
    1801           0 :   SpectralCoordinate mySpectral(MFrequency::TOPO,  chanFreq(0),
    1802           0 :                                 freqResolution(0), refChan,
    1803           0 :                                 restFreq);
    1804             :   
    1805             :   // Polarization: If the specified whichStokes are ok, we use them
    1806             :   // otherwise we guess
    1807           0 :   if(Int(whichStokes.nelements())!=npol) {
    1808           0 :     Vector<String> polType=msc.feed().polarizationType()(feedID);
    1809           0 :     whichStokes.resize(npol);
    1810             :     // Polarization
    1811           0 :     if(doCStokes) {
    1812           0 :       if (polType(0)=="X" || polType(0)=="Y") {
    1813           0 :         switch(npol) {
    1814           0 :         case 1:
    1815           0 :           whichStokes.resize(1);
    1816           0 :           whichStokes(0)=Stokes::I;
    1817           0 :           break;
    1818           0 :         case 2:
    1819           0 :           whichStokes.resize(2);
    1820           0 :           whichStokes(0)=Stokes::XX;
    1821           0 :           whichStokes(1)=Stokes::YY;
    1822           0 :           break;
    1823           0 :         default:
    1824           0 :           whichStokes.resize(4);
    1825           0 :           whichStokes(0)=Stokes::XX;
    1826           0 :           whichStokes(1)=Stokes::XY;
    1827           0 :           whichStokes(2)=Stokes::YX;
    1828           0 :           whichStokes(3)=Stokes::YY;
    1829             :         }
    1830             :       }
    1831             :       else {
    1832           0 :         switch(npol) {
    1833           0 :         case 1:
    1834           0 :           whichStokes.resize(1);
    1835           0 :           whichStokes(0)=Stokes::I;
    1836           0 :           break;
    1837           0 :         case 2:
    1838           0 :           whichStokes.resize(2);
    1839           0 :           whichStokes(0)=Stokes::LL;
    1840           0 :           whichStokes(1)=Stokes::RR;
    1841           0 :           break;
    1842           0 :         default:
    1843           0 :           whichStokes.resize(4);
    1844           0 :           whichStokes(0)=Stokes::LL;
    1845           0 :           whichStokes(1)=Stokes::LR;
    1846           0 :           whichStokes(2)=Stokes::RL;
    1847           0 :           whichStokes(3)=Stokes::RR;
    1848             :         };
    1849             :       }
    1850             :     }
    1851             :     else {
    1852           0 :       switch(npol) {
    1853           0 :       case 1:
    1854           0 :         whichStokes.resize(1);
    1855           0 :         whichStokes(0)=Stokes::I;
    1856           0 :         break;
    1857           0 :       case 2:
    1858           0 :         whichStokes.resize(2);
    1859           0 :         whichStokes(0)=Stokes::I;
    1860           0 :         if (polType(0)=="X" || polType(0)=="Y") {
    1861           0 :           whichStokes(1)=Stokes::Q;
    1862             :         }
    1863             :         else {
    1864           0 :           whichStokes(1)=Stokes::V;
    1865             :         }
    1866           0 :         break;
    1867           0 :       case 3:
    1868           0 :         whichStokes.resize(3);
    1869           0 :         whichStokes(0)=Stokes::I;
    1870           0 :         whichStokes(1)=Stokes::Q;
    1871           0 :         whichStokes(2)=Stokes::U;
    1872           0 :         break;
    1873           0 :       case 4:
    1874           0 :         whichStokes.resize(4);
    1875           0 :         whichStokes(0)=Stokes::I;
    1876           0 :         whichStokes(1)=Stokes::Q;
    1877           0 :         whichStokes(2)=Stokes::U;
    1878           0 :         whichStokes(3)=Stokes::V;
    1879           0 :         break;
    1880             :       };
    1881             :     }
    1882           0 :   }
    1883           0 :   StokesCoordinate myStokes(whichStokes);
    1884             :   
    1885             :   // Now set up coordinates for image. If the shape is
    1886             :   // 5 dimensional then we add another StokesCoordinate
    1887           0 :   CoordinateSystem coordInfo; 
    1888           0 :   coordInfo.addCoordinate(myRaDec);
    1889           0 :   coordInfo.addCoordinate(myStokes);
    1890           0 :   if(shape.nelements()==5) coordInfo.addCoordinate(myStokes);
    1891           0 :   coordInfo.addCoordinate(mySpectral);
    1892           0 :   return coordInfo;
    1893             :   
    1894           0 : }
    1895             : 
    1896             : /*  This function sets up the Stokes labelling for the polarization planes of 
    1897             :     'cImage', the complex image that stores gridded correlations.
    1898             :       
    1899             :      For example, if 'V' is asked for, we need to grid RR and LL (npol = 2 pol planes in cImage).
    1900             : 
    1901             :      Called from the first call of ImageStokesImageUtil::cImage().
    1902             : 
    1903             :      Input :  shape = shape of cImage. 
    1904             :                 polRep : Circular or Linear - present in the data. 
    1905             :      Input/Output : coords = Input polarization labelling is that of the target image ('V')
    1906             :                                          Output polarization labelling is for the correlations ('RR','LL').
    1907             :                            whichStokes = empty on input (first time). 
    1908             :                                                   Fill in the data correlation labels ('RR', 'LL')
    1909             : 
    1910             : */
    1911           0 : CoordinateSystem StokesImageUtil::CStokesCoord(//const IPosition& shape,
    1912             :                                                const CoordinateSystem& coord,
    1913             :                                                Vector<Int>& whichStokes,
    1914             :                                                StokesImageUtil::PolRep polRep) {
    1915             :   /*  
    1916             :   Int nx=shape(0);
    1917             :   Int ny=shape(1);
    1918             :   Int npol=shape(2);
    1919             :   Int nchan=shape(3);
    1920             :   AlwaysAssert(nx>0, AipsError);
    1921             :   AlwaysAssert(ny>0, AipsError);
    1922             :   AlwaysAssert(npol>0, AipsError);
    1923             :   AlwaysAssert(nchan>0, AipsError);
    1924             :   */
    1925             : 
    1926           0 :   Int directionIndex=coord.findCoordinate(Coordinate::DIRECTION);
    1927           0 :   DirectionCoordinate directionCoord=coord.directionCoordinate(directionIndex);
    1928             :   
    1929           0 :   Int spectralIndex=coord.findCoordinate(Coordinate::SPECTRAL);
    1930           0 :   SpectralCoordinate spectralCoord=coord.spectralCoordinate(spectralIndex);
    1931             :  
    1932           0 :   Int stokesIndex=coord.findCoordinate(Coordinate::STOKES);
    1933             :   StokesCoordinate
    1934           0 :     stokesCoord=coord.stokesCoordinate(stokesIndex);
    1935             : 
    1936             :   /* STOKESDBG */ //cout << "Util : CStokesCoord - input - stokesCoord : " << stokesCoord.stokes()  << endl;
    1937             :  
    1938             :   // Polarization: If the specified whichStokes are ok, we use them
    1939             :   //  if(Int(whichStokes.nelements())!=npol) {
    1940             :   //  whichStokes.resize(npol);
    1941             :   //  whichStokes=0;
    1942           0 :     changeLabelsStokesToCorrStokes(stokesCoord, polRep, whichStokes);
    1943             :     //}
    1944           0 :   AlwaysAssert(whichStokes.nelements(), AipsError);
    1945           0 :   StokesCoordinate stokesCoordOut(whichStokes);
    1946             : 
    1947             :   /* STOKESDBG */ //cout << "Util : CStokesCoord - output - stokesCoord : " << stokesCoordOut.stokes() << endl;
    1948             :  
    1949             :   // Now set up coordinates
    1950           0 :   CoordinateSystem coordInfo; 
    1951           0 :   coordInfo.addCoordinate(directionCoord);
    1952           0 :   coordInfo.addCoordinate(stokesCoordOut);
    1953           0 :   coordInfo.addCoordinate(spectralCoord);
    1954           0 :   return coordInfo;
    1955             : 
    1956           0 : }
    1957             : 
    1958             : /*
    1959             :      Logic : Read the desired image stokes from "stokesCoord" : 'V'
    1960             :                 Read the desired "npol" from the length of stokesCoord : '2'
    1961             :                 For npol = 1,2,3,4, if any image-pol choice requires an explicit mapping
    1962             :                                             to correlations, resize 'whichStokes' accordingly, and fill in.
    1963             :                              For example, 'V' is mapped to 'RR,LL' for Circular, and 'XY,YX' for Linear.
    1964             :                 Finally, check that all correlations in 'whichStokes' are present in the data.
    1965             : 
    1966             :       Subsequent calls to this function -- which already have the input stokesCoord in the 
    1967             :       correlation basis, will not do anything.
    1968             : 
    1969             :       Rules :
    1970             :            npol = 1 : I, XX,YY,XY,YX,RR,LL.RL,LR  --- choose only one correlation 
    1971             :                           Q, U, V -- map to 2 correlations as required for Circular vs Linear
    1972             :                           Note : "I" is a special-case for which ftmachines and gridders know how to use only one plane.
    1973             :            npol = 2 : RRLL,RLLR,XXYY,XYYX;  IV,QU for Circular;  IQ,UV for Linear -- map to 2 correlations
    1974             :                            IV, QU for Linear; IQ,UV for Circular -- map to 4 correlations
    1975             :            npol = 3,4 : Choose all 4 correlations.
    1976             : 
    1977             :       'whichStokes' contains the output
    1978             : */
    1979           0 : void StokesImageUtil::changeLabelsStokesToCorrStokes(StokesCoordinate &stokesCoord, 
    1980             :                                                      StokesImageUtil::PolRep polRep, //Int npol,
    1981             :                                                  Vector<Int>&whichStokes)
    1982             : {
    1983           0 :     Int inputNPol = (stokesCoord.stokes()).nelements();
    1984           0 :     Vector<Int> svec = stokesCoord.stokes();
    1985           0 :     AlwaysAssert( (inputNPol==1 || inputNPol==2 || inputNPol==3 || inputNPol), AipsError );
    1986             : 
    1987           0 :     switch( inputNPol )
    1988             :     {
    1989           0 :     case 1:
    1990           0 :            whichStokes.resize(1);
    1991             :            // by default, set to what the input is. This will take care of RR,LL,RL,LR,XX,YY,XY,YX and I.
    1992           0 :            whichStokes[0]=svec[0];
    1993             :            // for Q,U,V, two correlations needs to be gridded
    1994           0 :            if(polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::Q)
    1995           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::RL; whichStokes[1]=Stokes::LR; }
    1996           0 :            else if(polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::U)
    1997           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::RL; whichStokes[1]=Stokes::LR; }
    1998           0 :            else if(polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::V)
    1999           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::RR; whichStokes[1]=Stokes::LL; }
    2000           0 :            else if(polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::Q)
    2001           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::XX; whichStokes[1]=Stokes::YY; }
    2002           0 :            else if(polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::U)
    2003           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::XY; whichStokes[1]=Stokes::YX; }
    2004           0 :            else if(polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::V)
    2005           0 :                   {whichStokes.resize(2); whichStokes[0]=Stokes::XY; whichStokes[1]=Stokes::YX; }
    2006           0 :       break;
    2007           0 :     case 2:
    2008           0 :            whichStokes.resize(2);
    2009             :            // by default, set to what the input is. This will take care of RRLL, RLLR, XXYY, XYYX
    2010           0 :            whichStokes(0)=svec[0];
    2011           0 :            whichStokes(1)=svec[1];           
    2012             :            // only 2 correlations need to be gridded
    2013           0 :            if(polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::I && Stokes::type(svec[1])==Stokes::V) 
    2014           0 :                 {whichStokes(0)=Stokes::RR; whichStokes(1)=Stokes::LL;}
    2015           0 :            else if(polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::Q && Stokes::type(svec[1])==Stokes::U) 
    2016           0 :                 {whichStokes(0)=Stokes::RL; whichStokes(1)=Stokes::LR;}
    2017           0 :            else if(polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::I && Stokes::type(svec[1])==Stokes::Q) 
    2018           0 :                 {whichStokes(0)=Stokes::XX; whichStokes(1)=Stokes::YY;}
    2019           0 :            else if(polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::U && Stokes::type(svec[1])==Stokes::V) 
    2020           0 :                 {whichStokes(0)=Stokes::XY; whichStokes(1)=Stokes::YX;}
    2021             :            // all 4 correlations to be gridded. Only difference with above is CIRC to LIN
    2022           0 :            else if( (polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::I && Stokes::type(svec[1])==Stokes::V) ||
    2023           0 :                       (polRep==StokesImageUtil::LINEAR && Stokes::type(svec[0])==Stokes::Q && Stokes::type(svec[1])==Stokes::U) )
    2024             :                       {
    2025           0 :                           whichStokes.resize(4); 
    2026           0 :                           whichStokes(0)=Stokes::XX; whichStokes(1)=Stokes::XY; 
    2027           0 :                           whichStokes(2)=Stokes::YX; whichStokes(3)=Stokes::YY;
    2028             :                       }
    2029           0 :            else if( (polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::I && Stokes::type(svec[1])==Stokes::Q) ||
    2030           0 :                       (polRep==StokesImageUtil::CIRCULAR && Stokes::type(svec[0])==Stokes::U && Stokes::type(svec[1])==Stokes::V) )
    2031             :                       {
    2032           0 :                            whichStokes.resize(4); 
    2033           0 :                            whichStokes(0)=Stokes::RR; whichStokes(1)=Stokes::RL; 
    2034           0 :                            whichStokes(2)=Stokes::LR; whichStokes(3)=Stokes::LL;
    2035             :                       }
    2036           0 :        break;
    2037           0 :     case 3: /* If npol=3, all 4 correlations need to be gridded */
    2038             :     case 4:  /* Select all 4 correlations when npol=4 */
    2039           0 :         whichStokes.resize(4);
    2040           0 :         if( polRep==StokesImageUtil::LINEAR)
    2041             :         {
    2042           0 :            whichStokes(0)=Stokes::XX;
    2043           0 :            whichStokes(1)=Stokes::XY;
    2044           0 :            whichStokes(2)=Stokes::YX;
    2045           0 :            whichStokes(3)=Stokes::YY;
    2046             :         }
    2047             :         else
    2048             :         {
    2049           0 :            whichStokes(0)=Stokes::RR;
    2050           0 :            whichStokes(1)=Stokes::RL;
    2051           0 :            whichStokes(2)=Stokes::LR;
    2052           0 :            whichStokes(3)=Stokes::LL;
    2053             :         }
    2054           0 :         break;
    2055             :     }
    2056             : 
    2057             :     // Verify that all entries in whichStokes are present in the data 
    2058             :     // This is to catch things like : dataset contains only RR,LL, but the user has asked for IQUV.
    2059             :     
    2060             : 
    2061           0 : }// end of changeStokesToCorrStokes
    2062             : 
    2063             : 
    2064             : /*  This function is not called from anywhere !!!!  It should go. */
    2065             : #if 0
    2066             : CoordinateSystem
    2067             : StokesImageUtil::CStokesCoordFromImage(const ImageInterface<Complex>& image,
    2068             :                                        Vector<Int>& whichStokes,
    2069             :                                        StokesImageUtil::PolRep polRep) {
    2070             : 
    2071             :   IPosition shape=image.shape();
    2072             : 
    2073             :   Int npol=shape(2);
    2074             :   
    2075             :   CoordinateSystem coord=image.coordinates();
    2076             : 
    2077             :   Int directionIndex=coord.findCoordinate(Coordinate::DIRECTION);
    2078             :   DirectionCoordinate directionCoord=coord.directionCoordinate(directionIndex);
    2079             : 
    2080             :   Int spectralIndex=coord.findCoordinate(Coordinate::SPECTRAL);
    2081             :   SpectralCoordinate spectralCoord=coord.spectralCoordinate(spectralIndex);
    2082             : 
    2083             :   // Polarization: If the specified whichStokes are ok, we use them
    2084             :   // otherwise we guess
    2085             :   if(Int(whichStokes.nelements())!=npol) {
    2086             :     whichStokes.resize(npol);
    2087             :     // Polarization
    2088             :     if (polRep==StokesImageUtil::LINEAR) {
    2089             :       switch(npol) {
    2090             :       case 1:
    2091             :         whichStokes.resize(1);
    2092             :         whichStokes(1)=Stokes::I;
    2093             :         break;
    2094             :       case 2:
    2095             :         whichStokes.resize(2);
    2096             :         whichStokes(1)=Stokes::XX;
    2097             :         whichStokes(0)=Stokes::YY;
    2098             :         break;
    2099             :       default:
    2100             :         whichStokes.resize(4);
    2101             :         whichStokes(0)=Stokes::XX;
    2102             :         whichStokes(1)=Stokes::XY;
    2103             :         whichStokes(2)=Stokes::YX;
    2104             :         whichStokes(3)=Stokes::YY;
    2105             :       }
    2106             :     }
    2107             :     else {
    2108             :       switch(npol) {
    2109             :       case 1:
    2110             :         whichStokes.resize(1);
    2111             :         whichStokes(0)=Stokes::I;
    2112             :         break;
    2113             :       case 2:
    2114             :         whichStokes.resize(2);
    2115             :         whichStokes(0)=Stokes::LL;
    2116             :         whichStokes(1)=Stokes::RR;
    2117             :         break;
    2118             :       default:
    2119             :         whichStokes.resize(4);
    2120             :         whichStokes(0)=Stokes::LL;
    2121             :         whichStokes(1)=Stokes::LR;
    2122             :         whichStokes(2)=Stokes::RL;
    2123             :         whichStokes(3)=Stokes::RR;
    2124             :       };
    2125             :     }
    2126             :   }
    2127             :   StokesCoordinate stokesCoord(whichStokes);
    2128             :   
    2129             :   // Now set up coordinates for image.
    2130             :   CoordinateSystem coordInfo; 
    2131             :   coordInfo.addCoordinate(directionCoord);
    2132             :   coordInfo.addCoordinate(stokesCoord);
    2133             :   coordInfo.addCoordinate(spectralCoord);
    2134             :   return coordInfo;
    2135             : 
    2136             : }
    2137             : #endif
    2138             : 
    2139             : // Return a map to RA, DEC, pol, chan. 0 is RA, 1 is Dec, 2 is
    2140             : // polarization, and 3 is Channel
    2141           0 : Bool StokesImageUtil::StokesMap(Vector<Int>& map, const CoordinateSystem& coord) {
    2142             :   
    2143           0 :   map.resize(4);
    2144           0 :   map=-1;
    2145             : 
    2146           0 :   Int dirIndex=coord.findCoordinate(Coordinate::DIRECTION);
    2147           0 :   if(dirIndex>-1) {
    2148           0 :     Vector<Int> dirAxes=coord.pixelAxes(dirIndex);
    2149           0 :     if(dirAxes.nelements()>2) {
    2150           0 :       return false;
    2151             :     }
    2152           0 :     map(0)=dirAxes(0);
    2153           0 :     map(1)=dirAxes(1);
    2154           0 :   }
    2155             :   else {
    2156           0 :     return false;
    2157             :   }
    2158             : 
    2159           0 :   Int stokesIndex=coord.findCoordinate(Coordinate::STOKES);
    2160           0 :   if(stokesIndex>-1) {
    2161           0 :     Vector<Int> stokesAxes=coord.pixelAxes(stokesIndex);
    2162           0 :     if(stokesAxes.nelements()>1) {
    2163           0 :       return false;
    2164             :     }
    2165           0 :     map(2)=stokesAxes(0);
    2166           0 :   }
    2167             :   else {
    2168           0 :     return false;
    2169             :   }
    2170             : 
    2171           0 :   Int spectralIndex=coord.findCoordinate(Coordinate::SPECTRAL);
    2172           0 :   if(spectralIndex>-1) {
    2173           0 :     Vector<Int> spectralAxes=coord.pixelAxes(spectralIndex);
    2174           0 :     if(spectralAxes.nelements()>1) {
    2175           0 :       return false;
    2176             :     }
    2177           0 :     map(3)=spectralAxes(0);
    2178           0 :   }
    2179             :   else {
    2180           0 :     return false;
    2181             :   }
    2182             : 
    2183           0 :   return true;
    2184             : }
    2185             : 
    2186           0 : void StokesImageUtil::BoxMask(ImageInterface<Float>& mask,
    2187             :                               const IPosition& blc,
    2188             :                               const IPosition& trc, const Float value) 
    2189             : {
    2190           0 :   LatticeStepper ls(mask.shape(), IPosition(4, mask.shape()(0), 1, 1, 1),
    2191           0 :                     IPosition(4, 0, 1, 2, 3));
    2192           0 :   ls.subSection(blc, trc);
    2193           0 :   LatticeIterator<Float> mli(mask, ls);
    2194             :   
    2195             :   // Loop over all planes
    2196           0 :   for (mli.reset();!mli.atEnd();mli++) {
    2197           0 :     mli.rwCursor()=value;
    2198             :   }
    2199             :   
    2200           0 : }
    2201             : 
    2202             : // Change the representation used. The contents of the image
    2203             : // are not changed!
    2204           0 : void StokesImageUtil::changeCStokesRep(ImageInterface<Complex>& image,
    2205             :                                        StokesImageUtil::PolRep polRep) {
    2206             : 
    2207           0 :   CoordinateSystem coords=image.coordinates();
    2208             : 
    2209           0 :   Int stokesIndex=coords.findCoordinate(Coordinate::STOKES);
    2210             :   StokesCoordinate
    2211           0 :     stokesCoord=coords.stokesCoordinate(stokesIndex);
    2212             : 
    2213             :   ///// Int npol=stokesCoord.stokes().nelements(); // apparently not used and no side effects
    2214             :  
    2215             :   /* STOKESDBG */ //cout << "Util::changeCStokesRep - input - stokescoord : " << stokesCoord.stokes() << "   npol : " << npol << endl;
    2216             : 
    2217           0 :   Vector<Int> whichStokes(0);
    2218             :   //whichStokes=0;
    2219           0 :   changeLabelsStokesToCorrStokes(stokesCoord, polRep,  whichStokes);
    2220             : 
    2221           0 :   StokesCoordinate newStokesCoord(whichStokes);
    2222           0 :   coords.replaceCoordinate(newStokesCoord, stokesIndex);
    2223           0 :   image.setCoordinateInfo(coords);
    2224             :   /* STOKESDBG */ //cout << "Util::changeCStokesRep - output - stokescoord : " << newStokesCoord.stokes() << endl;
    2225           0 : }
    2226             : 
    2227           0 : Bool StokesImageUtil::
    2228             : standardImageCoordinates(const ImageInterface<Complex>& image) {
    2229           0 :   return (standardImageCoordinates(image.coordinates()));
    2230             : };
    2231             : 
    2232           0 : Bool StokesImageUtil::
    2233             : standardImageCoordinates(const ImageInterface<Float>& image) {
    2234           0 :   return (standardImageCoordinates(image.coordinates()));
    2235             : };
    2236             : 
    2237           0 : Bool StokesImageUtil::
    2238             : standardImageCoordinates(const CoordinateSystem& coords) {
    2239           0 :   Bool isStandard = true;
    2240             :   {
    2241           0 :     Int ind=coords.findCoordinate(Coordinate::DIRECTION);
    2242           0 :     if (ind != 0) isStandard = false;
    2243           0 :     ind=coords.findCoordinate(Coordinate::STOKES);
    2244           0 :     if (ind != 1) isStandard = false;
    2245           0 :     ind=coords.findCoordinate(Coordinate::SPECTRAL);
    2246           0 :     if (ind != 2) isStandard = false;
    2247             :   }
    2248           0 :   return isStandard;
    2249             : };
    2250             : 
    2251             : } //#End casa namespace
    2252             : 
    2253             : 

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