LCOV - code coverage report
Current view: top level - imageanalysis/ImageAnalysis - ImagePolarimetry.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 1016 0.0 %
Date: 2024-10-09 13:55:54 Functions: 0 65 0.0 %

          Line data    Source code
       1             : //# ImagePolarimetry.cc: polarimetric analysis
       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 addressed 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             : //# $Id: ImagePolarimetry.cc 20652 2009-07-06 05:04:32Z Malte.Marquarding $
      27             : 
      28             : #include <casacore/casa/OS/Timer.h>
      29             : 
      30             : #include <imageanalysis/ImageAnalysis/ImagePolarimetry.h>
      31             : 
      32             : #include <casacore/casa/Arrays/Array.h>
      33             : #include <casacore/casa/Arrays/ArrayMath.h>
      34             : #include <casacore/casa/Arrays/Vector.h>
      35             : #include <casacore/casa/Arrays/Matrix.h>
      36             : #include <casacore/casa/Arrays/MaskedArray.h>
      37             : #include <casacore/casa/Arrays/MaskArrMath.h>
      38             : #include <casacore/coordinates/Coordinates/CoordinateSystem.h>
      39             : #include <casacore/coordinates/Coordinates/StokesCoordinate.h>
      40             : #include <casacore/coordinates/Coordinates/LinearCoordinate.h>
      41             : #include <casacore/casa/Exceptions/Error.h>
      42             : #include <casacore/scimath/Functionals/Polynomial.h>
      43             : #include <casacore/images/Images/ImageInterface.h>
      44             : #include <casacore/images/Images/SubImage.h>
      45             : #include <casacore/images/Images/ImageExpr.h>
      46             : #include <imageanalysis/ImageAnalysis/ImageFFT.h>
      47             : #include <casacore/images/Regions/ImageRegion.h>
      48             : #include <casacore/images/Images/ImageSummary.h>
      49             : #include <casacore/images/Images/TempImage.h>
      50             : #include <casacore/lattices/Lattices/Lattice.h>
      51             : #include <casacore/lattices/LRegions/LCSlicer.h>
      52             : #include <casacore/lattices/LEL/LatticeExprNode.h>
      53             : #include <casacore/lattices/LEL/LatticeExpr.h>
      54             : #include <casacore/lattices/Lattices/TiledLineStepper.h>
      55             : #include <casacore/lattices/Lattices/LatticeStepper.h>
      56             : #include <casacore/lattices/Lattices/LatticeIterator.h>
      57             : #include <casacore/lattices/Lattices/LatticeUtilities.h>
      58             : #include <casacore/lattices/Lattices/MaskedLatticeIterator.h>
      59             : #include <casacore/lattices/LatticeMath/LatticeStatistics.h>
      60             : #include <casacore/lattices/LRegions/LCPagedMask.h>
      61             : #include <casacore/casa/Logging/LogIO.h>
      62             : #include <casacore/casa/Logging/LogOrigin.h>
      63             : #include <casacore/casa/BasicMath/Math.h>
      64             : #include <casacore/casa/BasicSL/Constants.h>
      65             : #include <casacore/scimath/Mathematics/NumericTraits.h>
      66             : #include <casacore/casa/System/ProgressMeter.h>
      67             : #include <casacore/casa/Quanta/QC.h>
      68             : #include <casacore/casa/Quanta/MVAngle.h>
      69             : #include <casacore/casa/Utilities/GenSort.h>
      70             : #include <casacore/casa/Utilities/Assert.h>
      71             : #include <casacore/casa/BasicSL/String.h>
      72             : 
      73             : #include <sstream>
      74             : 
      75             : using namespace casacore;
      76             : namespace casa {
      77             : 
      78             : const std::map<ImagePolarimetry::StokesTypes, String> ImagePolarimetry::polMap = {
      79             :     {I, "I"}, {Q, "Q"}, {U, "U"}, {V, "V"}
      80             : };
      81             : 
      82           0 : ImagePolarimetry::ImagePolarimetry (const ImageInterface<Float>& image)
      83           0 : : _image(image.cloneII())
      84             : {
      85           0 :    _stokes.resize(4);
      86           0 :    _stokesStats.resize(4);
      87           0 :    _stokes.set(0);
      88           0 :    _stokesStats.set(0);
      89           0 :    _findStokes();
      90           0 :    _createBeamsEqMat();
      91           0 : }
      92             : 
      93           0 : ImagePolarimetry::ImagePolarimetry(const ImagePolarimetry &other) {
      94           0 :    operator=(other);
      95           0 : }
      96             : 
      97           0 : ImagePolarimetry &ImagePolarimetry::operator=(const ImagePolarimetry &other) {
      98           0 :    if (this != &other) {
      99           0 :       _image.reset(other._image->cloneII());
     100           0 :       const auto n = _stokes.size();
     101           0 :       for (size_t i=0; i<n; ++i) {
     102           0 :          if (_stokes[i]) {
     103           0 :             delete _stokes[i];
     104           0 :             _stokes[i] = nullptr;
     105             :          }
     106           0 :          if (other._stokes[i]) {
     107           0 :             _stokes[i] = other._stokes[i]->cloneII();
     108             :          }
     109             :       }
     110             :       // Just delete fitter. It will make a new one when needed.
     111           0 :       if (_fitter) {
     112           0 :          delete _fitter;
     113           0 :          _fitter = nullptr;
     114             :       }
     115             :       // Remake Statistics objects as needed
     116           0 :       _oldClip = 0.0;
     117           0 :       for (size_t i=0; i<n; ++i) {
     118           0 :          if (_stokesStats[i]) {
     119           0 :             delete _stokesStats[i];
     120           0 :             _stokesStats[i] = nullptr;
     121             :          }
     122             :       }
     123           0 :       _beamsEqMat.assign(other._beamsEqMat);
     124             :    }
     125           0 :    return *this;
     126             : }
     127             : 
     128           0 : ImagePolarimetry::~ImagePolarimetry() {
     129           0 :    _cleanup();
     130           0 : }
     131             : 
     132           0 : ImageExpr<Complex> ImagePolarimetry::complexLinearPolarization() {
     133           0 :     _hasQU();
     134           0 :     _checkQUBeams(false);
     135             :     LatticeExprNode node(
     136             :         casacore::formComplex(
     137           0 :             *_stokes[ImagePolarimetry::Q], *_stokes[ImagePolarimetry::U]
     138             :         )
     139           0 :     );
     140           0 :     LatticeExpr<Complex> le(node);
     141           0 :     ImageExpr<Complex> ie(le, String("ComplexLinearPolarization"));
     142             :     // Need a Complex Linear Polarization type
     143           0 :     _fiddleStokesCoordinate(ie, Stokes::Plinear);
     144           0 :     ie.setUnits(_image->units());
     145           0 :     _setInfo(ie, Q);
     146           0 :     return ie;
     147           0 : }
     148             : 
     149           0 : void ImagePolarimetry::_setInfo(
     150             :     ImageInterface<Complex>& im, StokesTypes stokes
     151             : ) const {
     152           0 :     auto info = _image->imageInfo();
     153           0 :         if (info.hasMultipleBeams()) {
     154           0 :                 info.setBeams(_stokes[stokes]->imageInfo().getBeamSet());
     155             :         }
     156           0 :         im.setImageInfo(info);
     157           0 : }
     158             : 
     159           0 : void ImagePolarimetry::_setInfo(
     160             :     ImageInterface<Float>& im, StokesTypes stokes
     161             : ) const {
     162           0 :     auto info = _image->imageInfo();
     163           0 :         if (info.hasMultipleBeams()) {
     164           0 :                 info.setBeams(_stokes[stokes]->imageInfo().getBeamSet());
     165             :         }
     166           0 :         im.setImageInfo(info);
     167           0 : }
     168             : 
     169           0 : ImageExpr<Complex> ImagePolarimetry::complexFractionalLinearPolarization() {
     170           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     171           0 :     _hasQU();
     172           0 :     ThrowIf(
     173             :        ! _stokes[ImagePolarimetry::I],
     174             :        "This image does not have Stokes I so cannot "
     175             :         "provide fractional linear polarization"
     176             :     );
     177           0 :     _checkIQUBeams(false);
     178             :     LatticeExprNode nodeQU(
     179             :         casacore::formComplex(
     180           0 :             *_stokes[ImagePolarimetry::Q], *_stokes[ImagePolarimetry::U]
     181             :         )
     182           0 :     );
     183           0 :     LatticeExprNode nodeI(*_stokes[ImagePolarimetry::I]);
     184           0 :     LatticeExpr<Complex> le(nodeQU/nodeI);
     185           0 :     ImageExpr<Complex> ie(le, String("ComplexFractionalLinearPolarization"));
     186             :     // Need a Complex Linear Polarization type
     187           0 :     _fiddleStokesCoordinate(ie, Stokes::PFlinear);
     188           0 :     ie.setUnits(Unit(""));
     189           0 :     _setInfo(ie, I);
     190           0 :     return ie;
     191           0 : }
     192             : 
     193           0 : ImageExpr<Float> ImagePolarimetry::fracLinPol(
     194             :     Bool debias, Float clip, Float sigma
     195             : ) {
     196           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     197           0 :     _hasQU();
     198           0 :     ThrowIf(
     199             :         ! _stokes[ImagePolarimetry::I],
     200             :         "This image does not have Stokes I so cannot "
     201             :         "provide fractional linear polarization"
     202             :     );
     203           0 :     Vector<StokesTypes> types(3);
     204           0 :     types[0] = I; types[1] = Q; types[2] = U;
     205           0 :     _checkIQUBeams(false);
     206           0 :     auto nodePol = _makePolIntNode(os, debias, clip, sigma, true, false);
     207           0 :     LatticeExprNode nodeI(*_stokes[ImagePolarimetry::I]);
     208           0 :     LatticeExpr<Float> le(nodePol/nodeI);
     209           0 :     ImageExpr<Float> ie(le, String("FractionalLinearPolarization"));
     210           0 :     ie.setUnits(Unit(""));
     211           0 :     auto ii = _image->imageInfo();
     212           0 :     ii.removeRestoringBeam();
     213           0 :     ie.setImageInfo(ii);
     214           0 :    _fiddleStokesCoordinate(ie, Stokes::PFlinear);
     215           0 :    return ie;
     216           0 : }
     217             : 
     218           0 : ImageExpr<Float> ImagePolarimetry::sigmaFracLinPol(Float clip, Float sigma) {
     219             :     // sigma_m = m * sqrt( (sigmaP/p)**2 + (sigmaI/I)**2) )
     220             :     // sigmaP = sigmaQU
     221             :     // sigmaI = sigmaI
     222           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     223           0 :     _hasQU();
     224           0 :     ThrowIf(
     225             :         ! _stokes[ImagePolarimetry::I],
     226             :         "This image does not have Stokes I so cannot provide "
     227             :         "fractional linear polarization"
     228             :     );
     229           0 :     _checkIQUBeams(false);
     230             :     // Make nodes.  Don't bother debiasing.
     231           0 :    Bool debias = false;
     232           0 :    auto nodePol = _makePolIntNode(os, debias, clip, sigma, true, false);
     233           0 :    LatticeExprNode nodeI(*_stokes[ImagePolarimetry::I]);
     234             : 
     235             :    // Make expression.  We assume sigmaI = sigmaQU which is true with
     236             :    // no dynamic range limititation.  Perhaps we should work out
     237             :    // sigmaI as well.
     238             : 
     239           0 :    const auto sigma2 = sigmaLinPolInt(clip, sigma);
     240           0 :    LatticeExprNode n0(nodePol/nodeI);
     241           0 :    LatticeExprNode n1(pow(sigma2/nodePol,2));
     242           0 :    LatticeExprNode n2(pow(sigma2/nodeI,2));
     243           0 :    LatticeExpr<Float> le(n0 * sqrt(n1 + n2));
     244           0 :    ImageExpr<Float> ie(le, String("FractionalLinearPolarizationError"));
     245           0 :    ie.setUnits(Unit(""));
     246           0 :    auto ii = _image->imageInfo();
     247           0 :    ii.removeRestoringBeam();
     248           0 :    ie.setImageInfo(ii);
     249           0 :    _fiddleStokesCoordinate(ie, Stokes::PFlinear);
     250           0 :    return ie;
     251           0 : }
     252             : 
     253           0 : ImageExpr<Float> ImagePolarimetry::fracTotPol(
     254             :     Bool debias, Float clip, Float sigma
     255             : ) {
     256           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     257             :     Bool doLin, doCirc;
     258           0 :     _setDoLinDoCirc(doLin, doCirc);
     259           0 :     auto nodePol = _makePolIntNode(os, debias, clip, sigma, doLin, doCirc);
     260           0 :     LatticeExprNode nodeI(*_stokes[ImagePolarimetry::I]);
     261           0 :     LatticeExpr<Float> le(nodePol/nodeI);
     262           0 :     ImageExpr<Float> ie(le, String("FractionalTotalPolarization"));
     263           0 :     ie.setUnits(Unit(""));
     264           0 :     auto ii = _image->imageInfo();
     265           0 :     ii.removeRestoringBeam();
     266           0 :     ie.setImageInfo(ii);
     267           0 :     _fiddleStokesCoordinate(ie, Stokes::PFtotal);
     268           0 :     return ie;
     269           0 : }
     270             : 
     271           0 : void ImagePolarimetry::_setDoLinDoCirc(Bool& doLin, Bool& doCirc) const {
     272           0 :         LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     273           0 :         doLin = _stokes[ImagePolarimetry::Q] && _stokes[ImagePolarimetry::U];
     274           0 :         doCirc = _stokes[ImagePolarimetry::V];
     275             :         // Should never happen
     276           0 :         AlwaysAssert((doLin || doCirc), AipsError);
     277           0 :         ThrowIf(
     278             :             ! _stokes[ImagePolarimetry::I],
     279             :                 "This image does not have Stokes I so this calculation "
     280             :             "cannot be carried out"
     281             :         );
     282           0 :         if (doLin && ! _checkIQUBeams(false, false)) {
     283             :             os << LogIO::WARN << "I, Q, and U beams are not the same, cannot do "
     284           0 :                 << "linear portion" << LogIO::POST;
     285           0 :             doLin = false;
     286             :         }
     287           0 :         if (doCirc && ! _checkIVBeams(false, false)) {
     288             :             os << LogIO::WARN << "I and V beams are not the same, cannot do "
     289           0 :                 << "circular portion" << LogIO::POST;
     290           0 :             doCirc = false;
     291             :         }
     292           0 :         ThrowIf(
     293             :             ! (doLin || doCirc), "Can do neither linear nor circular portions"
     294             :         );
     295           0 : }
     296             : 
     297           0 : ImageExpr<Float> ImagePolarimetry::sigmaFracTotPol(Float clip, Float sigma) {
     298             :     // sigma_m = m * sqrt( (sigmaP/P)**2 + (sigmaI/I)**2) )
     299             :     // sigmaP = sigmaQU
     300             :     // sigmaI = sigmaI
     301           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     302             :     Bool doLin, doCirc;
     303           0 :     _setDoLinDoCirc(doLin, doCirc);
     304             :     // Make nodes.  Don't bother debiasing.
     305           0 :     Bool debias = false;
     306           0 :     auto nodePol = _makePolIntNode(os, debias, clip, sigma, doLin, doCirc);
     307           0 :     LatticeExprNode nodeI(*_stokes[ImagePolarimetry::I]);
     308             :     // Make expression.  We assume sigmaI = sigmaQU which is true with
     309             :     // no dynamic range limitation.  Perhaps we should work out
     310             :     // sigmaI as well.
     311           0 :     const auto sigma2 = sigmaTotPolInt(clip, sigma);
     312           0 :     LatticeExprNode n0(nodePol/nodeI);
     313           0 :     LatticeExprNode n1(pow(sigma2/nodePol,2));
     314           0 :     LatticeExprNode n2(pow(sigma2/nodeI,2));
     315           0 :     LatticeExpr<Float> le(n0 * sqrt(n1 + n2));
     316           0 :     ImageExpr<Float> ie(le, String("FractionalLinearPolarizationError"));
     317           0 :     ie.setUnits(Unit(""));
     318           0 :     auto ii = _image->imageInfo();
     319           0 :     ii.removeRestoringBeam();
     320           0 :     ie.setImageInfo(ii);
     321           0 :     _fiddleStokesCoordinate(ie, Stokes::PFlinear);
     322           0 :     return ie;
     323           0 : }
     324             : 
     325           0 : void ImagePolarimetry::fourierRotationMeasure(
     326             :     ImageInterface<Complex>& cpol, Bool zeroZeroLag
     327             : ) {
     328           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     329           0 :     _hasQU();
     330           0 :     _checkQUBeams(true, false);
     331           0 :     CoordinateSystem dCS;
     332           0 :     Stokes::StokesTypes dType = Stokes::Plinear;
     333           0 :     const auto shape = singleStokesShape(dCS, dType);
     334           0 :     if(! cpol.shape().isEqual(shape)) {
     335           0 :         os << "The provided  image has the wrong shape " << cpol.shape()
     336           0 :             << endl;
     337           0 :         os << "It should be of shape " << shape  << LogIO::EXCEPTION;
     338             :     }
     339           0 :     const auto& cSys = _image->coordinates();
     340             :     Int spectralCoord, fAxis;
     341           0 :     _findFrequencyAxis (spectralCoord, fAxis, cSys, -1);
     342             :     // Make Complex (Q,U) image
     343           0 :     LatticeExprNode node;
     344           0 :     if (zeroZeroLag) {
     345             :        TempImage<Float> tQ(
     346           0 :            _stokes[ImagePolarimetry::Q]->shape(),
     347           0 :            _stokes[ImagePolarimetry::Q]->coordinates()
     348           0 :        );
     349           0 :        if (_stokes[ImagePolarimetry::Q]->isMasked()) {
     350           0 :            tQ.makeMask(String("mask0"), true, true, false, false);
     351             :        }
     352           0 :        LatticeUtilities::copyDataAndMask(
     353           0 :            os, tQ, *_stokes[ImagePolarimetry::Q], false
     354             :        );
     355           0 :        _subtractProfileMean (tQ, fAxis);
     356             :        TempImage<Float> tU(
     357           0 :            _stokes[ImagePolarimetry::U]->shape(),
     358           0 :            _stokes[ImagePolarimetry::U]->coordinates()
     359           0 :        );
     360           0 :        if (_stokes[ImagePolarimetry::U]->isMasked()) {
     361           0 :            tU.makeMask(String("mask0"), true, true, false, false);
     362             :        }
     363           0 :        LatticeUtilities::copyDataAndMask(
     364           0 :            os, tU, *_stokes[ImagePolarimetry::U], false
     365             :        );
     366           0 :        _subtractProfileMean (tU, fAxis);
     367             :        // The TempImages will be cloned be LatticeExprNode so it's ok
     368             :        // that they go out of scope
     369           0 :        node = LatticeExprNode(formComplex(tQ, tU));
     370           0 :     }
     371             :     else {
     372           0 :         node = LatticeExprNode(
     373             :             formComplex(
     374           0 :                 *_stokes[ImagePolarimetry::Q], *_stokes[ImagePolarimetry::U]
     375             :             )
     376           0 :         );
     377             :     }
     378           0 :     LatticeExpr<Complex> le(node);
     379           0 :     ImageExpr<Complex> ie(le, String("ComplexLinearPolarization"));
     380             :     // Do FFT of spectral coordinate
     381           0 :     Vector<Bool> axes(ie.ndim(),false);
     382           0 :     axes(fAxis) = true;
     383           0 :     ImageFFT<Complex> fftserver;
     384           0 :     fftserver.fft(ie, axes);
     385             :     // Recover Complex result. Coordinates are updated to include Fourier
     386             :     // coordinate, miscellaneous things (MiscInfo, ImageInfo, units, history)
     387             :     // and mask (if output has one) are copied to cpol
     388           0 :     fftserver.getComplex(cpol);
     389             :     // Fiddle time coordinate to be a RotationMeasure coordinate
     390             :     auto f = _findCentralFrequency(
     391           0 :         cSys.coordinate(spectralCoord), ie.shape()(fAxis)
     392           0 :     );
     393           0 :     _fiddleTimeCoordinate(cpol, f, spectralCoord);
     394             :     // Set Stokes coordinate to be correct type
     395           0 :     _fiddleStokesCoordinate(cpol, Stokes::Plinear);
     396             :     // Set units and ImageInfo
     397           0 :     cpol.setUnits(_image->units());
     398           0 :     _setInfo(cpol, Q);
     399           0 : }
     400             : 
     401           0 : Float ImagePolarimetry::sigmaLinPolInt(Float clip, Float sigma) {
     402             :     // sigma_P = sigma_QU
     403           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     404           0 :     ThrowIf(
     405             :         ! _stokes[ImagePolarimetry::Q] && ! _stokes[ImagePolarimetry::U],
     406             :        "This image does not have Stokes Q and U so cannot "
     407             :         "provide linear polarization"
     408             :     );
     409           0 :     _checkQUBeams(false);
     410           0 :     Float sigma2 = 0.0;
     411           0 :     if (sigma > 0) {
     412           0 :         sigma2 = sigma;
     413             :     }
     414             :     else {
     415           0 :         os << LogIO::NORMAL << "Determined noise from Q&U images to be ";
     416           0 :         auto sq = _sigma(ImagePolarimetry::Q, clip);
     417           0 :         auto su = _sigma(ImagePolarimetry::U, clip);
     418           0 :         sigma2 = (sq+su)/2.0;
     419             :     }
     420           0 :     return sigma2;
     421           0 : }
     422             : 
     423           0 : ImageExpr<Float> ImagePolarimetry::linPolPosAng(Bool radians) const {
     424           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     425           0 :     ThrowIf(
     426             :         ! _stokes[ImagePolarimetry::Q] && ! _stokes[ImagePolarimetry::U],
     427             :         "This image does not have Stokes Q and U so cannot "
     428             :         "provide linear polarization"
     429             :     );
     430           0 :     _checkQUBeams(false);
     431             :     // Make expression. LEL function "pa" returns degrees
     432           0 :     Float fac = radians ? C::pi / 180.0 : 1.0;
     433             :     LatticeExprNode node(
     434           0 :         fac*pa(*_stokes[ImagePolarimetry::U], *_stokes[ImagePolarimetry::Q])
     435           0 :     );
     436           0 :     LatticeExpr<Float> le(node);
     437           0 :     ImageExpr<Float> ie(le, String("LinearlyPolarizedPositionAngle"));
     438           0 :     ie.setUnits(Unit(radians ? "rad" : "deg"));
     439           0 :     auto ii = _image->imageInfo();
     440           0 :     ii.removeRestoringBeam();
     441           0 :     ie.setImageInfo(ii);
     442           0 :     _fiddleStokesCoordinate(ie, Stokes::Pangle);
     443           0 :     return ie;
     444           0 : }
     445             : 
     446           0 : ImageExpr<Float> ImagePolarimetry::sigmaLinPolPosAng(
     447             :     Bool radians, Float clip, Float sigma
     448             : ) {
     449             :     // sigma_PA = sigmaQU / 2P
     450           0 :     ThrowIf(
     451             :         ! (_stokes[ImagePolarimetry::Q] || _stokes[ImagePolarimetry::U]),
     452             :         "This image does not have Stokes Q and U so "
     453             :         "cannot provide linear polarization"
     454             :     );
     455           0 :     _checkQUBeams(false);
     456           0 :     Float sigma2 = sigma > 0 ? sigma : this->sigma(clip);
     457           0 :     Float fac = 0.5 * sigma2;
     458           0 :     if (! radians) {
     459           0 :         fac *= 180 / C::pi;
     460             :     }
     461             :     LatticeExprNode node(
     462           0 :         fac / amp(*_stokes[ImagePolarimetry::U], *_stokes[ImagePolarimetry::Q])
     463           0 :     );
     464           0 :     LatticeExpr<Float> le(node);
     465           0 :     ImageExpr<Float> ie(le, String("LinearlyPolarizedPositionAngleError"));
     466           0 :     ie.setUnits(Unit(radians ? "rad" : "deg"));
     467           0 :     auto ii = _image->imageInfo();
     468           0 :     ii.removeRestoringBeam();
     469           0 :     ie.setImageInfo(ii);
     470           0 :     _fiddleStokesCoordinate(ie, Stokes::Pangle);
     471           0 :     return ie;
     472           0 : }
     473             : 
     474           0 : Float ImagePolarimetry::sigma(Float clip) {
     475           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     476           0 :     Float sigma2 = 0.0;
     477           0 :     if (_stokes[ImagePolarimetry::V]) {
     478           0 :         os << LogIO::NORMAL << "Determined noise from V image to be ";
     479           0 :         sigma2 = _sigma(ImagePolarimetry::V, clip);
     480             :     }
     481           0 :     else if (
     482           0 :         _stokes[ImagePolarimetry::Q] && _stokes[ImagePolarimetry::U]
     483           0 :         && _checkQUBeams(false, false)
     484             :     ) {
     485           0 :         sigma2 = sigmaLinPolInt(clip);
     486             :     }
     487           0 :     else if (_stokes[ImagePolarimetry::Q]) {
     488             :         os << LogIO::NORMAL << "Determined noise from Q image to be "
     489           0 :             << LogIO::POST;
     490           0 :         sigma2 = _sigma(ImagePolarimetry::Q, clip);
     491             :     }
     492           0 :     else if (_stokes[ImagePolarimetry::U]) {
     493             :         os << LogIO::NORMAL << "Determined noise from U image to be "
     494           0 :             << LogIO::POST;
     495           0 :         sigma2 = _sigma(ImagePolarimetry::U, clip);
     496             :     }
     497           0 :     else if (_stokes[ImagePolarimetry::I]!=0) {
     498             :         os << LogIO::NORMAL << "Determined noise from I image to be "
     499           0 :             << LogIO::POST;
     500           0 :         sigma2 = _sigma(ImagePolarimetry::I, clip);
     501             :     }
     502           0 :     os << sigma2 << LogIO::POST;
     503           0 :     return sigma2;
     504           0 : }
     505             : 
     506           0 : void ImagePolarimetry::rotationMeasure(
     507             :     ImageInterface<Float>*& rmOutPtr, ImageInterface<Float>*& rmOutErrorPtr,
     508             :     ImageInterface<Float>*& pa0OutPtr, ImageInterface<Float>*& pa0OutErrorPtr,
     509             :     ImageInterface<Float>*& nTurnsOutPtr, ImageInterface<Float>*& chiSqOutPtr,
     510             :     Int axis,  Float rmMax, Float maxPaErr, Float sigma, Float rmFg,
     511             :     Bool showProgress
     512             : ) {
     513           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     514           0 :     _hasQU();
     515           0 :     _checkQUBeams(false);
     516             :     // Do we have anything to do ?
     517           0 :     ThrowIf(
     518             :         ! (rmOutPtr || rmOutErrorPtr || pa0OutPtr || pa0OutErrorPtr),
     519             :         "No output images specified"
     520             :     );
     521             :     // Find expected shape of output RM images (Stokes and spectral axes gone)
     522           0 :     CoordinateSystem cSysRM;
     523             :     Int fAxis, sAxis;
     524           0 :     const auto shapeRM = rotationMeasureShape(cSysRM, fAxis, sAxis, os, axis);
     525           0 :     const auto shapeNTurns = shapeRM;
     526           0 :     const auto shapeChiSq = shapeRM;
     527             :     // Check RM image shapes
     528           0 :     if (rmOutPtr && ! rmOutPtr->shape().isEqual(shapeRM)) {
     529             :         os << "The provided Rotation Measure image has the wrong shape "
     530           0 :              << rmOutPtr->shape() << endl;
     531           0 :         os << "It should be of shape " << shapeRM << LogIO::EXCEPTION;
     532             :     }
     533           0 :     if (rmOutErrorPtr && !rmOutErrorPtr->shape().isEqual(shapeRM)) {
     534             :         os << "The provided Rotation Measure error image has the wrong shape "
     535           0 :             << rmOutErrorPtr->shape() << endl;
     536           0 :         os << "It should be of shape " << shapeRM << LogIO::EXCEPTION;
     537             :     }
     538             :     // Check position angle image shapes
     539           0 :     CoordinateSystem cSysPA;
     540           0 :     const auto shapePA = positionAngleShape(cSysPA, fAxis, sAxis, os, axis);
     541           0 :     if (pa0OutPtr && ! pa0OutPtr->shape().isEqual(shapePA)) {
     542             :         os << "The provided position angle at zero wavelength image has the "
     543           0 :             << "wrong shape " << pa0OutPtr->shape() << endl;
     544           0 :         os << "It should be of shape " << shapePA << LogIO::EXCEPTION;
     545             :     }
     546           0 :     if (pa0OutErrorPtr && ! pa0OutErrorPtr->shape().isEqual(shapePA)) {
     547             :         os << "The provided position angle at zero wavelength image has the "
     548           0 :             << "wrong shape " << pa0OutErrorPtr->shape() << endl;
     549           0 :         os << "It should be of shape " << shapePA << LogIO::EXCEPTION;
     550             :     }
     551           0 :     if (nTurnsOutPtr && ! nTurnsOutPtr->shape().isEqual(shapeNTurns)) {
     552             :         os << "The provided nTurns image has the wrong shape "
     553           0 :             << nTurnsOutPtr->shape() << endl;
     554           0 :         os << "It should be of shape " << shapeNTurns << LogIO::EXCEPTION;
     555             :     }
     556           0 :     if (chiSqOutPtr && ! chiSqOutPtr->shape().isEqual(shapeChiSq)) {
     557             :         os << "The provided chi squared image has the wrong shape "
     558           0 :             << chiSqOutPtr->shape() << endl;
     559           0 :         os << "It should be of shape " << shapeChiSq << LogIO::EXCEPTION;
     560             :     }
     561             :     // Generate linear polarization position angle image expressions
     562             :     // and error in radians
     563           0 :     Bool radians = true;
     564           0 :     Float clip = 10.0;
     565           0 :     const auto pa = linPolPosAng(radians);
     566           0 :     const auto paerr = sigmaLinPolPosAng(radians, clip, sigma);
     567           0 :     CoordinateSystem cSys0 = pa.coordinates();
     568             :     // Set frequency axis units to Hz
     569           0 :     auto fAxisWorld = cSys0.pixelAxisToWorldAxis(fAxis);
     570           0 :     ThrowIf(
     571             :         fAxisWorld < 0,
     572             :         "World axis has been removed for the frequency pixel axis"
     573             :     );
     574           0 :     auto axisUnits = cSys0.worldAxisUnits();
     575           0 :     axisUnits(fAxisWorld) = String("Hz");
     576           0 :     ThrowIf(
     577             :         ! cSys0.setWorldAxisUnits(axisUnits),
     578             :         "Failed to set frequency axis units to Hz because "
     579             :         + cSys0.errorMessage()
     580             :     );
     581             :     // Do we have enough frequency pixels ?
     582           0 :     const uInt nFreq = pa.shape()(fAxis);
     583           0 :     ThrowIf(
     584             :         nFreq < 3,
     585             :         "This image only has " + String::toString(nFreq)
     586             :         + " frequencies, this is not enough"
     587             :     );
     588             :     // Copy units only over.  The output images don't have a beam
     589             :     // so unset beam.   MiscInfo and history require writable II.
     590             :     // We leave this to the caller  who knows what sort of II these are.
     591           0 :     auto ii = _image->imageInfo();
     592           0 :     ii.removeRestoringBeam();
     593           0 :     if (rmOutPtr) {
     594           0 :         rmOutPtr->setImageInfo(ii);
     595           0 :         rmOutPtr->setUnits(Unit("rad/m/m"));
     596             :     }
     597           0 :     if (rmOutErrorPtr) {
     598           0 :         rmOutErrorPtr->setImageInfo(ii);
     599           0 :         rmOutErrorPtr->setUnits(Unit("rad/m/m"));
     600             :     }
     601           0 :     if (pa0OutPtr) {
     602           0 :         pa0OutPtr->setImageInfo(ii);
     603           0 :         pa0OutPtr->setUnits(Unit("deg"));
     604             :     }
     605           0 :     if (pa0OutErrorPtr) {
     606           0 :         pa0OutErrorPtr->setImageInfo(ii);
     607           0 :         pa0OutErrorPtr->setUnits(Unit("deg"));
     608             :     }
     609           0 :     if (nTurnsOutPtr) {
     610           0 :         nTurnsOutPtr->setImageInfo(ii);
     611           0 :         nTurnsOutPtr->setUnits(Unit(""));
     612             :     }
     613           0 :     if (chiSqOutPtr) {
     614           0 :         chiSqOutPtr->setImageInfo(ii);
     615           0 :         chiSqOutPtr->setUnits(Unit(""));
     616             :     }
     617             :     // Get lambda squared in m**2
     618           0 :     Vector<Double> freqs(nFreq);
     619           0 :     Vector<Float> wsq(nFreq);
     620           0 :     Vector<Double> world;
     621           0 :     Vector<Double> pixel(cSys0.referencePixel().copy());
     622           0 :     Double c = QC::c( ).getValue(Unit("m/s"));
     623           0 :     Double csq = c*c;
     624           0 :     for (uInt i=0; i<nFreq; ++i) {
     625           0 :         pixel(fAxis) = i;
     626           0 :         ThrowIf(
     627             :             !cSys0.toWorld(world, pixel),
     628             :             "Failed to convert pixel to world because "
     629             :             + cSys0.errorMessage()
     630             :         );
     631           0 :         freqs(i) = world(fAxisWorld);
     632             :         // m**2
     633           0 :         wsq(i) = csq / freqs(i) / freqs(i);
     634             :     }
     635             :     // Sort into increasing wavelength
     636           0 :     Vector<uInt> sortidx;
     637           0 :     GenSortIndirect<Float>::sort(
     638             :         sortidx, wsq, Sort::Ascending, Sort::QuickSort|Sort::NoDuplicates
     639             :     );
     640           0 :     Vector<Float> wsqsort(sortidx.size());
     641           0 :     for (uInt i=0; i<wsqsort.size(); ++i) {
     642           0 :         wsqsort[i] = wsq[sortidx[i]];
     643             :     }
     644             :     // Make fitter
     645           0 :     if (! _fitter) {
     646           0 :         _fitter = new LinearFitSVD<Float>;
     647             :         // Create and set the polynomial functional
     648             :         // p = c(0) + c(1)*x where x = lambda**2
     649             :         // PA = PA0 + RM*Lambda**2
     650           0 :         Polynomial<AutoDiff<Float> > poly1(1);
     651             :         // Makes a copy of poly1
     652           0 :         _fitter->setFunction(poly1);
     653           0 :     }
     654             :     // Deal with masks.  The outputs are all given a mask if possible as we
     655             :     // don't know at this point whether output points will be masked or not
     656           0 :     IPosition whereRM;
     657           0 :     auto isMaskedRM = false;
     658           0 :     Lattice<Bool>* outRMMaskPtr = nullptr;
     659           0 :     if (rmOutPtr) {
     660           0 :         isMaskedRM = _dealWithMask (outRMMaskPtr, rmOutPtr, os, "RM");
     661           0 :         whereRM.resize(rmOutPtr->ndim());
     662           0 :         whereRM = 0;
     663             :     }
     664           0 :     auto isMaskedRMErr = false;
     665           0 :     Lattice<Bool>* outRMErrMaskPtr = nullptr;
     666           0 :     if (rmOutErrorPtr) {
     667           0 :         isMaskedRMErr = _dealWithMask(
     668           0 :             outRMErrMaskPtr, rmOutErrorPtr, os, String("RM error")
     669             :         );
     670           0 :         whereRM.resize(rmOutErrorPtr->ndim());
     671           0 :         whereRM = 0;
     672             :     }
     673           0 :     IPosition wherePA;
     674           0 :     auto isMaskedPa0 = false;
     675           0 :     Lattice<Bool>* outPa0MaskPtr = nullptr;
     676           0 :     if (pa0OutPtr) {
     677           0 :         isMaskedPa0 = _dealWithMask(
     678           0 :             outPa0MaskPtr, pa0OutPtr, os, String("Position Angle")
     679             :         );
     680           0 :         wherePA.resize(pa0OutPtr->ndim());
     681           0 :         wherePA = 0;
     682             :     }
     683           0 :     auto isMaskedPa0Err = false;
     684           0 :     Lattice<Bool>* outPa0ErrMaskPtr = nullptr;
     685           0 :     if (pa0OutErrorPtr) {
     686           0 :         isMaskedPa0Err = _dealWithMask(
     687             :             outPa0ErrMaskPtr, pa0OutErrorPtr, os, "Position Angle error"
     688             :         );
     689           0 :         wherePA.resize(pa0OutErrorPtr->ndim());
     690           0 :         wherePA = 0;
     691             :     }
     692           0 :     IPosition whereNTurns;
     693           0 :     auto isMaskedNTurns = false;
     694           0 :     Lattice<Bool>* outNTurnsMaskPtr = 0;
     695           0 :     if (nTurnsOutPtr) {
     696           0 :         isMaskedNTurns = _dealWithMask(
     697             :             outNTurnsMaskPtr, nTurnsOutPtr, os, "nTurns"
     698             :         );
     699           0 :         whereNTurns.resize(nTurnsOutPtr->ndim());
     700           0 :         whereNTurns = 0;
     701             :     }
     702           0 :     IPosition whereChiSq;
     703           0 :     auto isMaskedChiSq = false;
     704           0 :     Lattice<Bool>* outChiSqMaskPtr = nullptr;
     705           0 :     if (chiSqOutPtr) {
     706           0 :         isMaskedChiSq = _dealWithMask(
     707           0 :             outChiSqMaskPtr, chiSqOutPtr, os, String("chi sqared")
     708             :         );
     709           0 :         whereChiSq.resize(chiSqOutPtr->ndim());
     710           0 :         whereChiSq = 0;
     711             :     }
     712           0 :     Array<Bool> tmpMaskRM(IPosition(shapeRM.size(), 1), true);
     713           0 :     Array<Float> tmpValueRM(IPosition(shapeRM.size(), 1), 0.0f);
     714           0 :     Array<Bool> tmpMaskPA(IPosition(shapePA.size(), 1), true);
     715           0 :     Array<Float> tmpValuePA(IPosition(shapePA.size(), 1), 0.0f);
     716           0 :     Array<Float> tmpValueNTurns(IPosition(shapeNTurns.size(), 1), 0.0f);
     717           0 :     Array<Bool> tmpMaskNTurns(IPosition(shapeNTurns.size(), 1), true);
     718           0 :     Array<Float> tmpValueChiSq(IPosition(shapeChiSq.size(), 1), 0.0f);
     719           0 :     Array<Bool> tmpMaskChiSq(IPosition(shapeChiSq.size(), 1), true);
     720             :     // Iterate
     721           0 :     const IPosition tileShape = pa.niceCursorShape();
     722           0 :     TiledLineStepper ts(pa.shape(), tileShape, fAxis);
     723           0 :     RO_MaskedLatticeIterator<Float> it(pa, ts);
     724             :     Float rm, rmErr, pa0, pa0Err, rChiSq, nTurns;
     725             :     uInt j, k, l, m;
     726           0 :     static const Double degPerRad = 180/C::pi;
     727           0 :     maxPaErr /= degPerRad;
     728           0 :     maxPaErr = abs(maxPaErr);
     729           0 :     Bool doRM = whereRM.size() > 0;
     730           0 :     Bool doPA = wherePA.size() > 0;
     731           0 :     Bool doNTurns = whereNTurns.size() > 0;
     732           0 :     Bool doChiSq = whereChiSq.size() > 0;
     733           0 :     unique_ptr<ProgressMeter> pProgressMeter;
     734           0 :     if (showProgress) {
     735           0 :         Double nMin = 0.0;
     736           0 :         Double nMax = 1.0;
     737           0 :         for (Int i=0; i<Int(pa.ndim()); ++i) {
     738           0 :             if (i!=fAxis) {
     739           0 :                 nMax *= pa.shape()[i];
     740             :             }
     741             :         }
     742           0 :         pProgressMeter.reset(
     743             :             new ProgressMeter(
     744             :                 nMin, nMax, "Profiles fitted", "Fitting",
     745           0 :                 "", "", true, max(1,Int(nMax/100))
     746           0 :             )
     747             :         );
     748             :     }
     749             :     // As a (temporary?) workaround the cache of the main image is set up in
     750             :     // such a way that it can hold the full frequency and stokes axes.
     751             :     // The stokes axis is important, otherwise the cache is set up
     752             :     // (by the TiledStMan) such that it can hold only 1 stokes
     753             :     // with the result that iterating is tremendously slow.
     754             :     // We also need to cast the const away from _image.
     755           0 :     const IPosition mainShape = _image->shape();
     756           0 :     uInt nrtiles = (1 + (mainShape(fAxis)-1) / tileShape(fAxis)) *
     757           0 :             (1 + (mainShape(sAxis)-1) / tileShape(sAxis));
     758           0 :     auto* mainImagePtr = const_cast<ImageInterface<Float>*>(_image.get());
     759           0 :     mainImagePtr->setCacheSizeInTiles (nrtiles);
     760           0 :     String posString;
     761           0 :     auto ok = false;
     762           0 :     IPosition shp;
     763           0 :     for (it.reset(); ! it.atEnd(); it++) {
     764             :         // Find rotation measure for this line
     765           0 :         ok = _findRotationMeasure(
     766             :             rm, rmErr, pa0, pa0Err, rChiSq, nTurns, sortidx, wsqsort,
     767           0 :             it.vectorCursor(), it.getMask(false),
     768           0 :             paerr.getSlice(it.position(),it.cursorShape()),
     769             :             rmFg, rmMax, maxPaErr, posString
     770             :         );
     771             :         // Plonk values into output  image.  This is slow and clunky, but
     772             :         // should be relatively fast c.f. the fitting.  Could be reimplemented
     773             :         // with LatticeApply if need be.  Buffering is hard because the
     774             :         // navigator doesn't take a regular path.  If I used a LatticeStepper
     775             :         // instead, the path would be regular and then I could buffer, but then
     776             :         // the iteration would be less efficient !!!
     777           0 :         j = k = l = m = 0;
     778           0 :         for (Int i=0; i<Int(it.position().size()); ++i) {
     779           0 :             if (doRM && i != fAxis && i != sAxis) {
     780           0 :                 whereRM(j) = it.position()[i];
     781           0 :                 ++j;
     782             :             }
     783           0 :             if (doPA && i != fAxis) {
     784           0 :                 wherePA(k) = it.position()[i];
     785           0 :                 ++k;
     786             :             }
     787           0 :             if (doNTurns && i != fAxis && i != sAxis) {
     788           0 :                 whereNTurns[l] = it.position()[i];
     789           0 :                 ++l;
     790             :             }
     791           0 :             if (doChiSq && i != fAxis && i != sAxis) {
     792           0 :                 whereChiSq[m] = it.position()[i];
     793           0 :                 ++m;
     794             :             }
     795             :         }
     796           0 :         if (isMaskedRM) {
     797           0 :             tmpMaskRM.set(ok);
     798           0 :             outRMMaskPtr->putSlice(tmpMaskRM, whereRM);
     799             :         }
     800           0 :         if (isMaskedRMErr) {
     801           0 :             tmpMaskRM.set(ok);
     802           0 :             outRMErrMaskPtr->putSlice(tmpMaskRM, whereRM);
     803             :         }
     804           0 :         if (isMaskedPa0) {
     805           0 :             tmpMaskPA.set(ok);
     806           0 :             outPa0MaskPtr->putSlice(tmpMaskPA, wherePA);
     807             :         }
     808           0 :         if (isMaskedPa0Err) {
     809           0 :             tmpMaskPA.set(ok);
     810           0 :             outPa0ErrMaskPtr->putSlice(tmpMaskPA, wherePA);
     811             :         }
     812           0 :         if (isMaskedNTurns) {
     813           0 :             tmpMaskNTurns.set(ok);
     814           0 :             outNTurnsMaskPtr->putSlice(tmpMaskNTurns, whereNTurns);
     815             :         }
     816           0 :         if (isMaskedChiSq) {
     817           0 :             tmpMaskChiSq.set(ok);
     818           0 :             outChiSqMaskPtr->putSlice(tmpMaskChiSq, whereChiSq);
     819             :         }
     820             :         // If the output value is masked, the value itself is 0
     821           0 :         if (rmOutPtr) {
     822           0 :             tmpValueRM.set(rm);
     823           0 :             rmOutPtr->putSlice(tmpValueRM, whereRM);
     824             :         }
     825           0 :         if (rmOutErrorPtr) {
     826           0 :             tmpValueRM.set(rmErr);
     827           0 :             rmOutErrorPtr->putSlice(tmpValueRM, whereRM);
     828             :         }
     829             :         // Position angles in degrees
     830           0 :         if (pa0OutPtr) {
     831           0 :             tmpValuePA.set(pa0*degPerRad);
     832           0 :             pa0OutPtr->putSlice(tmpValuePA, wherePA);
     833             :         }
     834           0 :         if (pa0OutErrorPtr) {
     835           0 :             tmpValuePA.set(pa0Err*degPerRad);
     836           0 :             pa0OutErrorPtr->putSlice(tmpValuePA, wherePA);
     837             :         }
     838             :         // Number of turns and chi sq
     839           0 :         if (nTurnsOutPtr) {
     840           0 :             tmpValueNTurns.set(nTurns);
     841           0 :             nTurnsOutPtr->putSlice(tmpValueNTurns, whereNTurns);
     842             :         }
     843           0 :         if (chiSqOutPtr) {
     844           0 :             tmpValueChiSq.set(rChiSq);
     845           0 :             chiSqOutPtr->putSlice(tmpValueChiSq, whereChiSq);
     846             :         }
     847           0 :         if (showProgress) {
     848           0 :             pProgressMeter->update(Double(it.nsteps()));
     849             :         }
     850             :     }
     851             :     // Clear the cache of the main image again.
     852           0 :     mainImagePtr->clearCache();
     853           0 : }
     854             : 
     855           0 : IPosition ImagePolarimetry::rotationMeasureShape(
     856             :     CoordinateSystem& cSys, Int& fAxis, Int& sAxis, LogIO&, Int spectralAxis
     857             : ) const {
     858           0 :     const auto cSys0 = coordinates();
     859             :     Int spectralCoord;
     860           0 :     _findFrequencyAxis(spectralCoord, fAxis, cSys0, spectralAxis);
     861           0 :     Int afterCoord = -1;
     862           0 :     auto stokesCoord = cSys0.findCoordinate(Coordinate::STOKES, afterCoord);
     863           0 :     auto pixelAxes = cSys0.pixelAxes(stokesCoord);
     864           0 :     sAxis = pixelAxes(0);
     865             :     // What shape should the image be ?  Frequency and stokes axes should be gone.
     866           0 :     const auto shape0 = shape();
     867           0 :     IPosition shape(shape0.size()-2);
     868           0 :     Int j = 0;
     869           0 :     for (Int i=0; i<Int(shape0.size()); ++i) {
     870           0 :         if (i != fAxis && i != sAxis) {
     871           0 :             shape[j] = shape0[i];
     872           0 :             ++j;
     873             :         }
     874             :     }
     875           0 :     CoordinateSystem tmp;
     876           0 :     cSys = tmp;
     877           0 :     for (Int i=0; i<Int(cSys0.nCoordinates()); ++i) {
     878           0 :         if (i != spectralCoord && i != stokesCoord) {
     879           0 :             cSys.addCoordinate(cSys0.coordinate(i));
     880             :         }
     881             :     }
     882           0 :     return shape;
     883           0 : }
     884             : 
     885           0 : IPosition ImagePolarimetry::positionAngleShape(
     886             :     CoordinateSystem& cSys,  Int& fAxis, Int& sAxis, LogIO&, Int spectralAxis
     887             : ) const {
     888           0 :     CoordinateSystem cSys0 = coordinates();
     889           0 :     Int spectralCoord = -1;
     890           0 :     _findFrequencyAxis (spectralCoord, fAxis, cSys0, spectralAxis);
     891           0 :     Int afterCoord = -1;
     892           0 :     Int stokesCoord = cSys0.findCoordinate(Coordinate::STOKES, afterCoord);
     893           0 :     Vector<Int> pixelAxes = cSys0.pixelAxes(stokesCoord);
     894           0 :     sAxis = pixelAxes(0);
     895           0 :     _fiddleStokesCoordinate(cSys0, Stokes::Pangle);
     896           0 :     CoordinateSystem tmp;
     897           0 :     cSys = tmp;
     898           0 :     for (Int i=0; i<Int(cSys0.nCoordinates()); ++i) {
     899           0 :        if (i != spectralCoord) {
     900           0 :            cSys.addCoordinate(cSys0.coordinate(i));
     901             :        }
     902             :     }
     903             :     // What shape should the image be ?  Frequency axis should be gone.
     904             :     // and Stokes length 1
     905           0 :     const auto shape0 = ImagePolarimetry::shape();
     906           0 :     IPosition shape(shape0.size()-1);
     907           0 :     Int j = 0;
     908           0 :     for (Int i=0; i<Int(shape0.size()); ++i) {
     909           0 :         if (i == sAxis) {
     910           0 :             shape[j] = 1;
     911           0 :             ++j;
     912             :         }
     913             :         else {
     914           0 :             if (i != fAxis) {
     915           0 :                 shape[j] = shape0[i];
     916           0 :                 ++j;
     917             :             }
     918             :         }
     919             :     }
     920           0 :     return shape;
     921           0 : }
     922             : 
     923           0 : ImageExpr<Float> ImagePolarimetry::stokesI() const {
     924             :    return _makeStokesExpr(
     925           0 :        _stokes[ImagePolarimetry::I], Stokes::I, "StokesI"
     926           0 :    );
     927             : }
     928             : 
     929           0 : Float ImagePolarimetry::sigmaStokesI(Float clip) {
     930           0 :    return _sigma(ImagePolarimetry::I, clip);
     931             : }
     932             : 
     933           0 : ImageExpr<Float> ImagePolarimetry::stokesQ() const {
     934           0 :    return _makeStokesExpr(_stokes[ImagePolarimetry::Q], Stokes::Q, "StokesQ");
     935             : }
     936             : 
     937           0 : Float ImagePolarimetry::sigmaStokesQ(Float clip) {
     938           0 :    return _sigma(ImagePolarimetry::Q, clip);
     939             : }
     940             : 
     941           0 : ImageExpr<Float> ImagePolarimetry::stokesU() const {
     942           0 :    return _makeStokesExpr(_stokes[ImagePolarimetry::U], Stokes::U, "StokesU");
     943             : }
     944             : 
     945           0 : Float ImagePolarimetry::sigmaStokesU(Float clip) {
     946           0 :    return _sigma(ImagePolarimetry::U, clip);
     947             : }
     948             : 
     949           0 : ImageExpr<Float> ImagePolarimetry::stokesV() const {
     950           0 :    return _makeStokesExpr(_stokes[ImagePolarimetry::V], Stokes::V, "StokesV");
     951             : }
     952             : 
     953           0 : Float ImagePolarimetry::sigmaStokesV(Float clip) {
     954           0 :    return _sigma(ImagePolarimetry::V, clip);
     955             : }
     956             : 
     957           0 : ImageExpr<Float> ImagePolarimetry::stokes(
     958             :     ImagePolarimetry::StokesTypes stokes
     959             : ) const {
     960           0 :    const auto type = _stokesType(stokes);
     961           0 :    return _makeStokesExpr(_stokes[stokes], type, _stokesName(stokes));
     962             : }
     963             : 
     964           0 : Float ImagePolarimetry::sigmaStokes(
     965             :     ImagePolarimetry::StokesTypes stokes, Float clip
     966             : ) {
     967           0 :    return _sigma(stokes, clip);
     968             : }
     969             : 
     970           0 : void ImagePolarimetry::summary(LogIO& os) const {
     971           0 :    ImageSummary<Float> s(*_image);
     972           0 :    s.list(os);
     973           0 : }
     974             : 
     975           0 : ImageExpr<Float> ImagePolarimetry::totPolInt(
     976             :     Bool debias, Float clip, Float sigma
     977             : ) {
     978           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     979             :     Bool doLin, doCirc;
     980           0 :     _setDoLinDoCirc(doLin, doCirc);
     981           0 :     auto node = _makePolIntNode(os, debias, clip, sigma, doLin, doCirc);
     982           0 :     LatticeExpr<Float> le(node);
     983           0 :     ImageExpr<Float> ie(le, String("totalPolarizedIntensity"));
     984             :     // Dodgy. The beam is now rectified
     985           0 :     ie.setUnits(_image->units());
     986           0 :     StokesTypes stokes = _stokes[Q] ? Q : _stokes[U] ? U : V;
     987           0 :     _setInfo(ie, stokes);
     988           0 :     _fiddleStokesCoordinate(ie, Stokes::Ptotal);
     989           0 :     return ie;
     990           0 : }
     991             : 
     992           0 : Float ImagePolarimetry::sigmaTotPolInt(Float clip, Float sigma) {
     993             :     // sigma_P = sigma_QUV
     994           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
     995             :     Bool doLin, doCirc;
     996           0 :     _setDoLinDoCirc(doLin, doCirc);
     997           0 :     Float sigma2 = sigma > 0 ? sigma : this->sigma(clip);
     998           0 :     return sigma2;
     999           0 : }
    1000             : 
    1001             : 
    1002           0 : IPosition ImagePolarimetry::singleStokesShape(
    1003             :     CoordinateSystem& cSys, Stokes::StokesTypes type
    1004             : ) const {
    1005             :     // We know the image has a Stokes coordinate or it
    1006             :     // would have failed at construction
    1007           0 :     auto cSys0 = _image->coordinates();
    1008           0 :     _fiddleStokesCoordinate(cSys0, type);
    1009           0 :     cSys = cSys0;
    1010           0 :     Int afterCoord = -1;
    1011           0 :     const auto iStokes = cSys0.findCoordinate(Coordinate::STOKES, afterCoord);
    1012           0 :     const auto pixelAxes = cSys0.pixelAxes(iStokes);
    1013           0 :     auto shape = _image->shape();
    1014           0 :     shape[pixelAxes[0]] = 1;
    1015           0 :     return shape;
    1016           0 : }
    1017             : 
    1018           0 : ImageExpr<Float> ImagePolarimetry::depolarizationRatio(
    1019             :     const ImageInterface<Float>& im1, const ImageInterface<Float>& im2,
    1020             :     Bool debias, Float clip, Float sigma
    1021             : ) {
    1022           0 :     ImagePolarimetry p1(im1);
    1023           0 :     ImagePolarimetry p2(im2);
    1024           0 :     ImageExpr<Float> m1(p1.fracLinPol(debias, clip, sigma));
    1025           0 :     ImageExpr<Float> m2(p2.fracLinPol(debias, clip, sigma));
    1026           0 :     LatticeExprNode n1(m1/m2);
    1027           0 :     LatticeExpr<Float> le(n1);
    1028           0 :     ImageExpr<Float> depol(le, "DepolarizationRatio");
    1029           0 :     return depol;
    1030           0 : }
    1031             : 
    1032           0 : ImageExpr<Float> ImagePolarimetry::sigmaDepolarizationRatio(
    1033             :     const ImageInterface<Float>& im1, const ImageInterface<Float>& im2,
    1034             :     Bool debias, Float clip, Float sigma
    1035             : ) {
    1036           0 :     Vector<StokesTypes> types(3);
    1037           0 :     types[0] = I;
    1038           0 :     types[1] = Q;
    1039           0 :     types[2] = U;
    1040           0 :     _checkBeams(im1, im2, types);
    1041           0 :     ImagePolarimetry p1(im1);
    1042           0 :     ImagePolarimetry p2(im2);
    1043           0 :     ImageExpr<Float> m1 = p1.fracLinPol(debias, clip, sigma);
    1044           0 :     ImageExpr<Float> sm1 = p1.sigmaFracLinPol(clip, sigma);
    1045           0 :     ImageExpr<Float> m2 = p2.fracLinPol(debias, clip, sigma);
    1046           0 :     ImageExpr<Float> sm2 = p2.sigmaFracLinPol(clip, sigma);
    1047           0 :     LatticeExprNode n0(m1/m2);
    1048           0 :     LatticeExprNode n1(sm1*sm1/m1/m1);
    1049           0 :     LatticeExprNode n2(sm2*sm2/m2/m2);
    1050           0 :     LatticeExprNode n3(n0 * sqrt(n1+n2));
    1051           0 :     LatticeExpr<Float> le(n3);
    1052           0 :     ImageExpr<Float> sigmaDepol(le, "DepolarizationRatioError");
    1053           0 :      return sigmaDepol;
    1054           0 : }
    1055             : 
    1056           0 : void ImagePolarimetry::_cleanup() {
    1057           0 :     _image.reset();
    1058           0 :     for (uInt i=0; i<4; ++i) {
    1059           0 :         delete _stokes[i];
    1060           0 :         _stokes[i] = nullptr;
    1061           0 :         delete _stokesStats[i];
    1062           0 :         _stokesStats[i] = nullptr;
    1063             :     }
    1064           0 :     delete _fitter;
    1065           0 :     _fitter = nullptr;
    1066           0 : }
    1067             : 
    1068           0 : void ImagePolarimetry::_findFrequencyAxis(
    1069             :     Int& spectralCoord, Int& fAxis, const CoordinateSystem& cSys,
    1070             :     Int spectralAxis
    1071             : ) const {
    1072           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
    1073           0 :     spectralCoord = -1;
    1074           0 :     fAxis = -1;
    1075           0 :     if (spectralAxis >= 0) {
    1076           0 :         ThrowIf(
    1077             :             spectralAxis >= Int(cSys.nPixelAxes()),
    1078             :             "Illegal spectral axis " + String::toString(spectralAxis) +" given"
    1079             :         );
    1080           0 :         fAxis = spectralAxis;
    1081             :         Int axisInCoordinate;
    1082           0 :         cSys.findPixelAxis(spectralCoord, axisInCoordinate, fAxis);
    1083             :         // Check coordinate type is one of expected types
    1084           0 :         ThrowIf(
    1085             :             ! (
    1086             :                 cSys.type(spectralCoord)==Coordinate::TABULAR
    1087             :                 || cSys.type(spectralCoord)==Coordinate::LINEAR
    1088             :                 || cSys.type(spectralCoord)==Coordinate::SPECTRAL
    1089             :             ),
    1090             :             "The specified axis of type " + cSys.showType(spectralCoord)
    1091             :             + " cannot be a frequency axis"
    1092             :         );
    1093             :     }
    1094             :     else {
    1095           0 :         spectralCoord = _findSpectralCoordinate(cSys, os, false);
    1096           0 :         if (spectralCoord < 0) {
    1097           0 :             for (uInt i=0; i<cSys.nCoordinates(); ++i) {
    1098           0 :                 if (
    1099           0 :                     cSys.type(i)==Coordinate::TABULAR
    1100           0 :                     || cSys.type(i)==Coordinate::LINEAR
    1101             :                 ) {
    1102           0 :                     const auto axisNames = cSys.coordinate(i).worldAxisNames();
    1103           0 :                     String tmp = axisNames[0];
    1104           0 :                     tmp.upcase();
    1105           0 :                     if (tmp.contains(String("FREQ"))) {
    1106           0 :                         spectralCoord = i;
    1107           0 :                         break;
    1108             :                     }
    1109           0 :                 }
    1110             :             }
    1111             :         }
    1112           0 :         ThrowIf(
    1113             :             spectralCoord < 0,
    1114             :             "Cannot find SpectralCoordinate in this image"
    1115             :         );
    1116           0 :         fAxis = cSys.pixelAxes(spectralCoord)[0];
    1117             :     }
    1118           0 : }
    1119             : 
    1120           0 : void ImagePolarimetry::_findStokes() {
    1121           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
    1122           0 :     const CoordinateSystem& cSys = _image->coordinates();
    1123           0 :     Int polAxisNum = cSys.polarizationAxisNumber();
    1124           0 :     ThrowIf(
    1125             :         polAxisNum < 0, "There is no Stokes Coordinate in this image"
    1126             :     );
    1127           0 :     const uInt ndim = _image->ndim();
    1128           0 :     auto shape = _image->shape();
    1129           0 :     IPosition blc(ndim,0);
    1130           0 :     auto trc = shape - 1;
    1131           0 :     for (const auto& kv : polMap) {
    1132           0 :         const auto pix = cSys.stokesPixelNumber(kv.second);
    1133           0 :         if (pix >= 0) {
    1134           0 :             _stokes[kv.first] = _makeSubImage(blc, trc, polAxisNum, pix);
    1135             :         }
    1136             :     }
    1137           0 :     if((_stokes[Q] && ! _stokes[U]) || (! _stokes[Q] && _stokes[U])) {
    1138           0 :         _cleanup();
    1139           0 :         ThrowCc(
    1140             :             "This Stokes coordinate has only one of Q and U. This is not useful"
    1141             :         );
    1142             :     }
    1143           0 :     if (! (_stokes[Q] || _stokes[U] || _stokes[V])) {
    1144           0 :        _cleanup();
    1145           0 :        ThrowCc("This image has no Stokes Q, U, nor V.  This is not useful");
    1146             :     }
    1147           0 : }
    1148             : 
    1149           0 : void ImagePolarimetry::_fiddleStokesCoordinate(
    1150             :     ImageInterface<Float>& im, Stokes::StokesTypes type
    1151             : ) const {
    1152           0 :     CoordinateSystem cSys = im.coordinates();
    1153           0 :     _fiddleStokesCoordinate(cSys, type);
    1154           0 :     im.setCoordinateInfo(cSys);
    1155           0 : }
    1156             : 
    1157           0 : void ImagePolarimetry::_fiddleStokesCoordinate(
    1158             :     CoordinateSystem& cSys, Stokes::StokesTypes type
    1159             : ) const {
    1160           0 :     Int afterCoord = -1;
    1161           0 :     Int iStokes = cSys.findCoordinate(Coordinate::STOKES, afterCoord);
    1162           0 :     const Vector<Int> which(1, Int(type));
    1163           0 :     StokesCoordinate stokes(which);
    1164           0 :     cSys.replaceCoordinate(stokes, iStokes);
    1165           0 : }
    1166             : 
    1167           0 : void ImagePolarimetry::_fiddleStokesCoordinate(
    1168             :     ImageInterface<Complex>& ie, Stokes::StokesTypes type
    1169             : ) const {
    1170           0 :     CoordinateSystem cSys = ie.coordinates();
    1171           0 :     _fiddleStokesCoordinate(cSys, type);
    1172           0 :     ie.setCoordinateInfo(cSys);
    1173           0 : }
    1174             : 
    1175           0 : void ImagePolarimetry::_fiddleTimeCoordinate(
    1176             :     ImageInterface<Complex>& ie, const Quantum<Double>& f, Int coord
    1177             : ) const {
    1178           0 :     LogIO os(LogOrigin("ImagePolarimetry", __func__, WHERE));
    1179           0 :     CoordinateSystem cSys = ie.coordinates();
    1180           0 :     unique_ptr<Coordinate> pC(cSys.coordinate(coord).clone());
    1181           0 :     AlwaysAssert(pC->nPixelAxes()==1,AipsError);
    1182           0 :     AlwaysAssert(pC->type()==Coordinate::LINEAR,AipsError);
    1183           0 :     auto axisUnits = pC->worldAxisUnits();
    1184           0 :     axisUnits = String("s");
    1185           0 :     ThrowIf(
    1186             :         ! pC->setWorldAxisUnits(axisUnits),
    1187             :         "Failed to set TimeCoordinate units to seconds because "
    1188             :         + pC->errorMessage()
    1189             :     );
    1190             :     // Find factor to convert from time (s) to rad/m/m
    1191           0 :     auto inc = pC->increment();
    1192           0 :     const auto ff = f.getValue(Unit("Hz"));
    1193           0 :     const auto lambda = QC::c( ).getValue(Unit("m/s")) / ff;
    1194           0 :     const auto fac = -C::pi * ff / 2.0 / lambda / lambda;
    1195           0 :     inc *= fac;
    1196           0 :     Vector<String> axisNames(1);
    1197           0 :     axisNames = String("RotationMeasure");
    1198           0 :     axisUnits = String("rad/m/m");
    1199           0 :     Vector<Double> refVal(1,0.0);
    1200             :     LinearCoordinate lC(
    1201             :         axisNames, axisUnits, refVal, inc,
    1202           0 :         pC->linearTransform().copy(), pC->referencePixel().copy()
    1203           0 :     );
    1204           0 :     cSys.replaceCoordinate(lC, coord);
    1205           0 :     ie.setCoordinateInfo(cSys);
    1206           0 : }
    1207             : 
    1208           0 : Quantum<Double> ImagePolarimetry::_findCentralFrequency(
    1209             :     const Coordinate& coord, Int shape
    1210             : ) const {
    1211           0 :     AlwaysAssert(coord.nPixelAxes()==1,AipsError);
    1212           0 :     Vector<Double> pixel(1);
    1213           0 :     Vector<Double> world;
    1214           0 :     pixel(0) = Double(shape - 1) / 2.0;
    1215           0 :     ThrowIf(
    1216             :         ! coord.toWorld(world, pixel),
    1217             :         "Failed to convert pixel to world for SpectralCoordinate because "
    1218             :         + coord.errorMessage()
    1219             :     );
    1220           0 :     const auto units = coord.worldAxisUnits();
    1221           0 :     return Quantum<Double>(world(0), units(0));
    1222           0 : }
    1223             : 
    1224           0 : Int ImagePolarimetry::_findSpectralCoordinate(
    1225             :     const CoordinateSystem& cSys, LogIO& os, Bool fail
    1226             : ) const {
    1227           0 :     Int afterCoord = -1;
    1228           0 :     Int coord = cSys.findCoordinate(Coordinate::SPECTRAL, afterCoord);
    1229           0 :     ThrowIf(coord < 0 && fail, "No spectral coordinate in this image");
    1230           0 :     if (afterCoord>0) {
    1231             :         os << LogIO::WARN << "This image has more than one spectral "
    1232           0 :             << "coordinate; only first used" << LogIO::POST;
    1233             :     }
    1234           0 :     return coord;
    1235             : }
    1236             : 
    1237           0 : Bool ImagePolarimetry::_findRotationMeasure(
    1238             :     Float& rmFitted, Float& rmErrFitted, Float& pa0Fitted, Float& pa0ErrFitted,
    1239             :     Float& rChiSqFitted, Float& nTurns, const Vector<uInt>& sortidx,
    1240             :     const Vector<Float>& wsq2, const Vector<Float>& pa2,
    1241             :     const Array<Bool>& paMask2, const Array<Float>& paerr2, Float rmFg,
    1242             :     Float rmMax, Float maxPaErr, const String& posString
    1243             : ) {
    1244             :     // wsq is lambda squared in m**2 in increasing wavelength order
    1245             :     // pa is position angle in radians
    1246             :     // paerr is pa error in radians
    1247             :     // maxPaErr is maximum tolerated error in position angle
    1248             :     // rmfg is a user specified foreground RM rad/m/m
    1249             :     // rmmax is a user specified maximum RM
    1250           0 :     static Vector<Float> paerr;
    1251           0 :     static Vector<Float> pa;
    1252           0 :     static Vector<Float> wsq;
    1253             :     // Abandon if less than 2 points
    1254           0 :     uInt n = sortidx.size();
    1255           0 :     if (n<2) {
    1256           0 :         return false;
    1257             :     }
    1258           0 :     rmFitted = rmErrFitted = pa0Fitted = pa0ErrFitted = rChiSqFitted = 0.0;
    1259             :     // Sort into decreasing frequency order and correct for foreground rotation
    1260             :     // Remember wsq already sorted.  Discard points that are too noisy or masked
    1261           0 :     const Vector<Float>& paerr1(paerr2.nonDegenerate(0));
    1262           0 :     const Vector<Bool>& paMask1(paMask2.nonDegenerate(0));
    1263           0 :     paerr.resize(n);
    1264           0 :     pa.resize(n);
    1265           0 :     wsq.resize(n);
    1266           0 :     uInt j = 0;
    1267           0 :     for (uInt i=0; i<n; ++i) {
    1268           0 :         if (abs(paerr1(sortidx(i))) < maxPaErr && paMask1(sortidx(i))) {
    1269           0 :             pa(j) = pa2(sortidx(i)) - rmFg*wsq2(i);
    1270           0 :             paerr(j) = paerr1(sortidx(i));
    1271           0 :             wsq(j) = wsq2(i);
    1272           0 :             ++j;
    1273             :         }
    1274             :     }
    1275           0 :     n = j;
    1276           0 :     if (n<=1) {
    1277           0 :         return false;
    1278             :     }
    1279           0 :     pa.resize(n, true);
    1280           0 :     paerr.resize(n, true);
    1281           0 :     wsq.resize(n, true);
    1282             :     // Treat supplementary and primary points separately
    1283             :     Bool ok = n == 2
    1284           0 :         ? _rmSupplementaryFit(
    1285             :             nTurns, rmFitted, rmErrFitted, pa0Fitted, pa0ErrFitted,
    1286             :             rChiSqFitted, wsq, pa, paerr
    1287             :         )
    1288           0 :         : _rmPrimaryFit(
    1289             :             nTurns, rmFitted, rmErrFitted, pa0Fitted, pa0ErrFitted,
    1290             :             rChiSqFitted, wsq, pa, paerr, rmMax, /*plotter,*/ posString
    1291           0 :         );
    1292             :     // Put position angle into the range 0->pi
    1293           0 :     static MVAngle tmpMVA1;
    1294           0 :     if (ok) {
    1295           0 :         MVAngle tmpMVA0(pa0Fitted);
    1296           0 :         tmpMVA1 = tmpMVA0.binorm(0.0);
    1297           0 :         pa0Fitted = tmpMVA1.radian();
    1298             :         // Add foreground back on
    1299           0 :         rmFitted += rmFg;
    1300           0 :     }
    1301           0 :     return ok;
    1302           0 : }
    1303             : 
    1304           0 : void ImagePolarimetry::_hasQU () const {
    1305           0 :    ThrowIf(
    1306             :        ! (_stokes[Q] && _stokes[U]),
    1307             :        "This image does not have Stokes Q and U which are "
    1308             :        "required for this function"
    1309             :    );
    1310           0 : }
    1311             : 
    1312           0 : ImageExpr<Float> ImagePolarimetry::_makeStokesExpr(
    1313             :     ImageInterface<Float>* imPtr, Stokes::StokesTypes type, const String& name
    1314             : ) const {
    1315           0 :     ThrowIf(! imPtr, "This image does not have Stokes " + Stokes::name(type));
    1316           0 :     LatticeExprNode node(*imPtr);
    1317           0 :     LatticeExpr<Float> le(node);
    1318           0 :     ImageExpr<Float> ie(le, name);
    1319           0 :     ie.setUnits(_image->units());
    1320           0 :     _fiddleStokesCoordinate(ie, type);
    1321           0 :     return ie;
    1322           0 : }
    1323             : 
    1324           0 : ImageInterface<Float>* ImagePolarimetry::_makeSubImage(
    1325             :     IPosition& blc, IPosition& trc, Int axis, Int pix
    1326             : ) const {
    1327           0 :     blc[axis] = pix;
    1328           0 :     trc[axis] = pix;
    1329           0 :     LCSlicer slicer(blc, trc, RegionType::Abs);
    1330           0 :     ImageRegion region(slicer);
    1331           0 :     return new SubImage<Float>(*_image, region);
    1332           0 : }
    1333             : 
    1334           0 : LatticeExprNode ImagePolarimetry::_makePolIntNode(
    1335             :     LogIO& os, Bool debias, Float clip, Float sigma, Bool doLin, Bool doCirc
    1336             : ) {
    1337           0 :     LatticeExprNode linNode, circNode, node;
    1338           0 :     Float sigma2 = debias ? (sigma > 0.0 ? sigma : this->sigma(clip)) : 0.0;
    1339           0 :     if (doLin) {
    1340           0 :         linNode = LatticeExprNode(pow(*_stokes[U], 2) + pow(*_stokes[Q], 2));
    1341             :     }
    1342           0 :     if (doCirc) {
    1343           0 :         circNode = LatticeExprNode(pow(*_stokes[V], 2));
    1344             :     }
    1345           0 :     Float sigmasq = sigma2 * sigma2;
    1346           0 :     if (doLin && doCirc) {
    1347           0 :         node = linNode + circNode;
    1348           0 :         if (debias) {
    1349           0 :             node = node - LatticeExprNode(sigmasq);
    1350           0 :             os << LogIO::NORMAL << "Debiasing with sigma = " << sqrt(sigmasq)
    1351           0 :                 << LogIO::POST;
    1352             :         }
    1353             :     }
    1354           0 :     else if (doLin) {
    1355           0 :         node = linNode;
    1356           0 :         if (debias) {
    1357           0 :             node = node - LatticeExprNode(sigmasq);
    1358           0 :             os << LogIO::NORMAL << "Debiasing with sigma  = " << sqrt(sigmasq)
    1359           0 :                 << LogIO::POST;
    1360             :         }
    1361             :     }
    1362           0 :     else if (doCirc) {
    1363           0 :         node = circNode;
    1364           0 :         if (debias) {
    1365           0 :             node = node - LatticeExprNode(sigmasq);
    1366           0 :             os << LogIO::NORMAL << "Debiasing with sigma = " << sqrt(sigmasq)
    1367           0 :                 << LogIO::POST;
    1368             :         }
    1369             :     }
    1370           0 :     return LatticeExprNode(sqrt(node));
    1371           0 : }
    1372             : 
    1373           0 : Bool ImagePolarimetry::_rmPrimaryFit(
    1374             :     Float& nTurns, Float& rmFitted, Float& rmErrFitted, Float& pa0Fitted,
    1375             :     Float& pa0ErrFitted, Float& rChiSqFitted, const Vector<Float>& wsq,
    1376             :     const Vector<Float>& pa, const Vector<Float>& paerr, Float rmMax,
    1377             :     const String&
    1378             : ) {
    1379           0 :     static Vector<Float> plotPA;
    1380           0 :     static Vector<Float> plotPAErr;
    1381           0 :     static Vector<Float> plotPAErrY1;
    1382           0 :     static Vector<Float> plotPAErrY2;
    1383           0 :     static Vector<Float> plotPAFit;
    1384             :     // Assign position angle to longest wavelength consistent with RM < RMMax
    1385           0 :     const uInt n = wsq.size();
    1386           0 :     Double dwsq = wsq(n-1) - wsq(0);
    1387           0 :     Float ppa = abs(rmMax)*dwsq + pa(0);
    1388           0 :     Float diff = ppa - pa(n-1);
    1389           0 :     Float t = diff >= 0 ? 0.5 : -0.5;
    1390           0 :     Int maxnpi = Int(diff/C::pi + t);
    1391           0 :     ppa = -abs(rmMax)*dwsq + pa(0);
    1392           0 :     diff = ppa - pa(n-1);
    1393           0 :     t = diff >= 0 ? 0.5 : -0.5;
    1394           0 :     Int minnpi = Int(diff/C::pi + t);
    1395             :     // Loop over range of n*pi ambiguity
    1396           0 :     Vector<Float> fitpa(n);
    1397           0 :     Vector<Float> pars;
    1398           0 :     Float chiSq = 1e30;
    1399           0 :     for (Int h=minnpi; h<=maxnpi; ++h) {
    1400           0 :         fitpa[n-1] = pa[n-1] + C::pi*h;
    1401           0 :         Float rm0 = (fitpa(n-1) - pa(0))/dwsq;
    1402             :         // Assign position angles to remaining wavelengths
    1403           0 :         for (uInt k=1; k<n-1; ++k) {
    1404           0 :             ppa = pa[0] + rm0*(wsq[k]-wsq[0]);
    1405           0 :             diff = ppa - pa[k];
    1406           0 :             t = diff >= 0 ? 0.5 : -0.5;
    1407           0 :             Int npi = Int(diff/C::pi + t);
    1408           0 :             fitpa[k] = pa[k] + npi*C::pi;
    1409             :         }
    1410           0 :         fitpa[0] = pa[0];
    1411             :         // Do least squares fit
    1412           0 :         if (!_rmLsqFit (pars, wsq, fitpa, paerr)) {
    1413           0 :             return false;
    1414             :         }
    1415           0 :         if (pars[4] < chiSq) {
    1416           0 :             chiSq = pars[4];
    1417           0 :             nTurns = h;                   // Number of turns
    1418           0 :             rmFitted = pars[0];           // Fitted RM
    1419           0 :             rmErrFitted = pars[1];        // Error in RM
    1420           0 :             pa0Fitted = pars[2];          // Fitted intrinsic angle
    1421           0 :             pa0ErrFitted = pars[3];       // Error in angle
    1422           0 :             rChiSqFitted = pars[4];       // Recued chi squared
    1423           0 :             if (n > 2) {
    1424           0 :                 rChiSqFitted /= Float(n - 2);
    1425             :             }
    1426             :         }
    1427             :     }
    1428           0 :     return true;
    1429           0 : }
    1430             : 
    1431           0 : Bool ImagePolarimetry::_rmSupplementaryFit(
    1432             :     Float& nTurns, Float& rmFitted, Float& rmErrFitted, Float& pa0Fitted,
    1433             :     Float& pa0ErrFitted, Float& rChiSqFitted,  const Vector<Float>& wsq,
    1434             :     const Vector<Float>& pa, const Vector<Float>& paerr
    1435             : ) {
    1436             :     // For supplementary points find lowest residual RM
    1437           0 :     const uInt n = wsq.size();
    1438           0 :     Float absRM = 1e30;
    1439           0 :     Vector<Float> fitpa(pa.copy());
    1440           0 :     Vector<Float> pars;
    1441           0 :     for (Int i=-2; i<3; ++i) {
    1442           0 :         fitpa[n-1] = pa[n-1] + C::pi*i;
    1443             :         // Do least squares fit
    1444           0 :         if (! _rmLsqFit (pars, wsq, fitpa, paerr)) {
    1445           0 :             return false;
    1446             :         }
    1447             :         // Save solution  with lowest absolute RM
    1448           0 :         if (abs(pars[0]) < absRM) {
    1449           0 :             absRM = abs(pars[0]);
    1450           0 :             nTurns = i;                        // nTurns
    1451           0 :             rmFitted = pars(0);                // Fitted RM
    1452           0 :             rmErrFitted = pars[1];             // Error in RM
    1453           0 :             pa0Fitted = pars[2];               // Fitted intrinsic angle
    1454           0 :             pa0ErrFitted = pars[3];            // Error in angle
    1455           0 :             rChiSqFitted = pars[4];            // Reduced chi squared
    1456           0 :             if (n > 2) {
    1457           0 :                 rChiSqFitted /= Float(n - 2);
    1458             :             }
    1459             :         }
    1460             :     }
    1461           0 :     return true;
    1462           0 : }
    1463             : 
    1464           0 : Bool ImagePolarimetry::_rmLsqFit(
    1465             :     Vector<Float>& pars, const Vector<Float>& wsq, const Vector<Float> pa,
    1466             :     const Vector<Float>& paerr
    1467             : ) const {
    1468             :     // Perform fit on unmasked data
    1469           0 :     static Vector<Float> solution;
    1470             :     try {
    1471           0 :         solution = _fitter->fit(wsq, pa, paerr);
    1472           0 :     } catch (AipsError x) {
    1473           0 :         return false;
    1474           0 :     }
    1475           0 :     const Vector<Double>& cv = _fitter->compuCovariance().diagonal();
    1476           0 :     pars.resize(5);
    1477           0 :     pars[0] = solution[1];
    1478           0 :     pars[1] = sqrt(cv[1]);
    1479           0 :     pars[2] = solution[0];
    1480           0 :     pars[3] = sqrt(cv[0]);
    1481           0 :     pars[4] = _fitter->chiSquare();
    1482           0 :     return true;
    1483           0 : }
    1484             : 
    1485           0 : String ImagePolarimetry::_stokesName(
    1486             :     ImagePolarimetry::StokesTypes index
    1487             : ) const {
    1488           0 :     const auto iter = polMap.find(index);
    1489           0 :     return (iter == polMap.end()) ? "??" : iter->second;
    1490             : }
    1491             : 
    1492           0 : Stokes::StokesTypes ImagePolarimetry::_stokesType (ImagePolarimetry::StokesTypes index) const
    1493             : {
    1494           0 :    if (index==ImagePolarimetry::I) {
    1495           0 :       return Stokes::I;
    1496           0 :    } else if (index==ImagePolarimetry::Q) {
    1497           0 :       return Stokes::Q;
    1498           0 :    } else if (index==ImagePolarimetry::U) {
    1499           0 :       return Stokes::U;
    1500           0 :    } else if (index==ImagePolarimetry::V) {
    1501           0 :       return Stokes::V;
    1502             :    } else {
    1503           0 :       return Stokes::Undefined;
    1504             :    }
    1505             : }
    1506             : 
    1507             : 
    1508           0 : Float ImagePolarimetry::_sigma(
    1509             :     ImagePolarimetry::StokesTypes index, Float clip
    1510             : ) {
    1511           0 :     Float clip2 = clip == 0 ? 10.0 : abs(clip);
    1512           0 :     if (clip2 != _oldClip && _stokesStats[index]) {
    1513           0 :         delete _stokesStats[index];
    1514           0 :         _stokesStats[index] = 0;
    1515             :     }
    1516           0 :     if (! _stokesStats[index]) {
    1517             :         // Find sigma for all points inside +/- clip-sigma of the mean
    1518             :         // More joys of LEL
    1519           0 :         const ImageInterface<Float>* p = _stokes[index];
    1520           0 :         LatticeExprNode n1 (*p);
    1521           0 :         LatticeExprNode n2 (n1[abs(n1-mean(n1)) < clip2*stddev(n1)]);
    1522           0 :         LatticeExpr<Float> le(n2);
    1523           0 :         _stokesStats[index] = new LatticeStatistics<Float>(le, false, false);
    1524           0 :     }
    1525           0 :     Array<Float> sigmaA;
    1526           0 :     _stokesStats[index]->getConvertedStatistic(sigmaA, LatticeStatsBase::SIGMA);
    1527           0 :     ThrowIf(
    1528             :         sigmaA.empty(),
    1529             :         "No good points in clipped determination of the noise for the Stokes "
    1530             :         + _stokesName(index) + " image"
    1531             :     );
    1532           0 :     _oldClip = clip2;
    1533           0 :     return sigmaA(IPosition(1,0));
    1534           0 : }
    1535             : 
    1536           0 : void ImagePolarimetry::_subtractProfileMean(
    1537             :     ImageInterface<Float>& im, uInt axis
    1538             : ) const {
    1539           0 :     const IPosition tileShape = im.niceCursorShape();
    1540           0 :     TiledLineStepper ts(im.shape(), tileShape, axis);
    1541           0 :     LatticeIterator<Float> it(im, ts);
    1542             :     Float dMean;
    1543           0 :     if (im.isMasked()) {
    1544           0 :         const Lattice<Bool>& mask = im.pixelMask();
    1545           0 :         for (it.reset(); !it.atEnd(); it++) {
    1546           0 :             const auto& p = it.cursor();
    1547           0 :             const auto& m = mask.getSlice(it.position(), it.cursorShape());
    1548           0 :             const MaskedArray<Float> ma(p, m, true);
    1549           0 :             dMean = mean(ma);
    1550           0 :             it.rwVectorCursor() -= dMean;
    1551           0 :         }
    1552             :     }
    1553             :     else {
    1554           0 :         for (it.reset(); !it.atEnd(); it++) {
    1555           0 :             dMean = mean(it.vectorCursor());
    1556           0 :             it.rwVectorCursor() -= dMean;
    1557             :         }
    1558             :     }
    1559           0 : }
    1560             : 
    1561           0 : Bool ImagePolarimetry::_dealWithMask(
    1562             :     Lattice<Bool>*& pMask, ImageInterface<Float>*& pIm, LogIO& os,
    1563             :     const String& type
    1564             : ) const {
    1565           0 :     auto isMasked = pIm->isMasked();
    1566           0 :     if (! isMasked) {
    1567           0 :         if (pIm->canDefineRegion()) {
    1568           0 :             pIm->makeMask("mask0", true, true, true, true);
    1569           0 :             isMasked = true;
    1570             :         }
    1571             :         else {
    1572             :             os << LogIO::WARN << "Could not create a mask for the output "
    1573           0 :                 << type << " image" << LogIO::POST;
    1574             :         }
    1575             :     }
    1576           0 :     if (isMasked) {
    1577           0 :         pMask = &(pIm->pixelMask());
    1578           0 :         if (! pMask->isWritable()) {
    1579           0 :             isMasked = false;
    1580             :             os << LogIO::WARN << "The output " << type
    1581           0 :                 << " image has a mask but it's not writable" << LogIO::POST;
    1582             :         }
    1583             :     }
    1584           0 :     return isMasked;
    1585             : }
    1586             : 
    1587           0 : void ImagePolarimetry::_createBeamsEqMat() {
    1588           0 :         _beamsEqMat.assign(Matrix<Bool>(4, 4, false));
    1589           0 :         Bool hasMultiBeams = _image->imageInfo().hasMultipleBeams();
    1590           0 :         for (uInt i=0; i<4; ++i) {
    1591           0 :                 for (uInt j=i; j<4; ++j) {
    1592           0 :                         if (! (_stokes[i] &&  _stokes[j])) {
    1593           0 :                                 _beamsEqMat(i, j) = false;
    1594             :                         }
    1595           0 :                         else if (i == j) {
    1596           0 :                                 _beamsEqMat(i, j) = true;
    1597             :                         }
    1598           0 :                         else if (hasMultiBeams) {
    1599           0 :                                 _beamsEqMat(i, j) = (
    1600           0 :                                         _stokes[i]->imageInfo().getBeamSet()
    1601           0 :                                         == _stokes[j]->imageInfo().getBeamSet()
    1602             :                                 );
    1603             :                         }
    1604             :                         else {
    1605           0 :                                 _beamsEqMat(i, j) = true;
    1606             :                         }
    1607           0 :                         _beamsEqMat(j, i) = _beamsEqMat(i, j);
    1608             : 
    1609             :                 }
    1610             :         }
    1611           0 : }
    1612             : 
    1613           0 : Bool ImagePolarimetry::_checkBeams(
    1614             :     const vector<StokesTypes>& stokes, Bool requireChannelEquality, Bool throws
    1615             : ) const {
    1616           0 :         for (
    1617           0 :                 auto iter = stokes.cbegin(); iter != stokes.cend(); ++iter
    1618             :         ) {
    1619           0 :                 for (
    1620           0 :                         auto jiter=iter; jiter!=stokes.cend(); ++jiter
    1621             :                 ) {
    1622           0 :                         if (iter == jiter) {
    1623           0 :                                 continue;
    1624             :                         }
    1625           0 :                         if (! _beamsEqMat(*iter, *jiter)) {
    1626           0 :                                 ThrowIf(
    1627             :                                     throws,
    1628             :                                     "Input image has multiple beams and the corresponding "
    1629             :                                     "beams for the stokes planes necessary for this "
    1630             :                                     "computation are not equal."
    1631             :                                 );
    1632           0 :                                 return False;
    1633             :                         }
    1634             :                 }
    1635             :         }
    1636           0 :         if (
    1637             :                 requireChannelEquality
    1638           0 :                 && _stokes[stokes[0]]->coordinates().hasSpectralAxis()
    1639           0 :                 && _stokes[stokes[0]]->imageInfo().hasMultipleBeams()
    1640             :         ) {
    1641             :                 const auto& beamSet
    1642           0 :                     = _stokes[stokes[0]]->imageInfo().getBeamSet().getBeams();
    1643           0 :                 auto start = beamSet.cbegin();
    1644           0 :                 ++start;
    1645           0 :                 for (auto iter=start; iter!=beamSet.cend(); ++iter) {
    1646           0 :                         if (*iter != *(beamSet.begin())) {
    1647           0 :                                 ThrowIf(
    1648             :                                     throws,
    1649             :                                         "At least one beam in this image is not equal to all the "
    1650             :                                     "others along its spectral axis so this computation cannot "
    1651             :                                     "be performed"
    1652             :                                 );
    1653           0 :                                 return False;
    1654             :                         }
    1655             :                 }
    1656             :         }
    1657           0 :         return true;
    1658             : }
    1659             : 
    1660           0 : Bool ImagePolarimetry::_checkIQUBeams(
    1661             :     Bool requireChannelEquality, Bool throws
    1662             : ) const {
    1663           0 :         static const vector<StokesTypes> types = {I, Q, U};
    1664           0 :         return _checkBeams(types, requireChannelEquality, throws);
    1665             : }
    1666             : 
    1667           0 : Bool ImagePolarimetry::_checkIVBeams(
    1668             :     Bool requireChannelEquality, Bool throws
    1669             : ) const {
    1670           0 :         static const vector<StokesTypes> types = {I, V};
    1671           0 :         return _checkBeams(types, requireChannelEquality, throws);
    1672             : }
    1673             : 
    1674           0 : Bool ImagePolarimetry::_checkQUBeams(
    1675             :     Bool requireChannelEquality, Bool throws
    1676             : ) const {
    1677           0 :         static const vector<StokesTypes> types = {Q, U};
    1678           0 :         return _checkBeams(types, requireChannelEquality, throws);
    1679             : }
    1680             : 
    1681           0 : void ImagePolarimetry::_checkBeams(
    1682             :         const ImagePolarimetry& im1, const ImagePolarimetry& im2,
    1683             :         const Vector<ImagePolarimetry::StokesTypes>& stokes
    1684             : ) {
    1685           0 :         for (auto iter=stokes.cbegin(); iter!=stokes.cend(); iter++) {
    1686           0 :                 ThrowIf(
    1687             :                         im1.stokes(*iter).imageInfo().getBeamSet()
    1688             :                         != im2.stokes(*iter).imageInfo().getBeamSet(),
    1689             :                         "Beams or beamsets are not equal between the two images, caonnot "
    1690             :                         "perform calculation"
    1691             :                 );
    1692             :         }
    1693           0 : }
    1694             : 
    1695             : }

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