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Current view: top level - msvis/MSVis - VisIterator.cc (source / functions) Hit Total Coverage
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Date: 2024-10-10 15:00:01 Functions: 0 106 0.0 %

          Line data    Source code
       1             : //# VisibilityIterator.cc: Step through MeasurementEquation by visibility
       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: VisIterator.cc,v 19.15 2006/02/01 01:25:14 kgolap Exp $
      27             : 
      28             : #include <msvis/MSVis/VisIterator.h>
      29             : #include <msvis/MSVis/VisBuffer.h>
      30             : #include <stdcasa/UtilJ.h>
      31             : #include <casacore/scimath/Mathematics/InterpolateArray1D.h>
      32             : #include <casacore/casa/Arrays/ArrayLogical.h>
      33             : #include <casacore/casa/Arrays/ArrayMath.h>
      34             : #include <casacore/casa/Arrays/MaskedArray.h>
      35             : #include <casacore/casa/Exceptions/Error.h>
      36             : #include <casacore/casa/Utilities/Assert.h>
      37             : #include <casacore/casa/Utilities/Sort.h>
      38             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      39             : #include <casacore/casa/Quanta/MVTime.h>
      40             : #include <casacore/tables/Tables/TableDesc.h>
      41             : #include <casacore/tables/Tables/ColDescSet.h>
      42             : #include <casacore/tables/Tables/TableRecord.h>
      43             : #include <casacore/tables/DataMan/TiledColumnStMan.h>
      44             : #include <casacore/tables/DataMan/TiledStManAccessor.h>
      45             : #include <msvis/MSVis/VisibilityIteratorImpl.h>
      46             : #include <cmath>
      47             : 
      48             : using std::ceil;
      49             : 
      50             : using namespace casacore;
      51             : namespace casa { //# NAMESPACE CASA - BEGIN
      52             : 
      53             : class ROVisIteratorImpl : public VisibilityIteratorReadImpl {
      54             : 
      55             :     friend class ROVisIterator;
      56             :     friend class VisIterator;
      57             : 
      58             : public:
      59             : 
      60             :   // Default constructor - useful only to assign another iterator later
      61             :   ROVisIteratorImpl();
      62             : 
      63             :   // Construct from MS and a Block of MS column enums specifying the iteration
      64             :   // order, if none are specified, time iteration is implicit.  An optional
      65             :   // timeInterval can be given to iterate through chunks of time.  The default
      66             :   // interval of 0 groups all times together.  Every 'chunk' of data contains
      67             :   // all data within a certain time interval (in seconds) and with identical
      68             :   // values of the other iteration columns (e.g.  DATA_DESC_ID and FIELD_ID).
      69             :   // Using selectChannel(), a number of groups of channels can be requested.
      70             :   // At present the channel group iteration will always occur before the
      71             :   // interval iteration.
      72             :   ROVisIteratorImpl(ROVisIterator * rovi,
      73             :                     const MeasurementSet& ms,
      74             :                     const Block<Int>& sortColumns,
      75             :                     Double timeInterval=0);
      76             : 
      77             :   // Copy construct. This calls the assignment operator.
      78             :   ROVisIteratorImpl(const ROVisIteratorImpl & other);
      79             : 
      80             :   // Destructor
      81             :   virtual ~ROVisIteratorImpl();
      82             : 
      83             :   // Assignment. Any attached VisBuffers are lost in the assign.
      84             :   ROVisIteratorImpl & operator=(const ROVisIteratorImpl &other);
      85             : 
      86             :   // Members
      87             : 
      88             :   // Advance iterator through data
      89             :   ROVisIteratorImpl & operator++(int);
      90             :   ROVisIteratorImpl & operator++();
      91             : 
      92             :   // Selected spws and channel counts
      93             :   virtual void allSelectedSpectralWindows (Vector<Int> & spws, Vector<Int> & nvischan);
      94             : 
      95             :   // 
      96             :   virtual void lsrFrequency(const Int& spw, Vector<Double>& freq, Bool& convert, const  Bool ignoreconv=false);
      97             : 
      98             : 
      99             :   // The following throws an exception, because this isn't the
     100             :   // language of channel selection in VisIterator
     101           0 :   virtual void getChannelSelection(Block< Vector<Int> >&,
     102             :                                    Block< Vector<Int> >&,
     103             :                                    Block< Vector<Int> >&,
     104             :                                    Block< Vector<Int> >&,
     105             :                                    Block< Vector<Int> >&)
     106           0 :   { throw(AipsError("ROVisIteratorImpl::getChannelSelection: you can't do that!")); };
     107             : 
     108             :   // Return channel numbers in selected VisSet spectrum
     109             :   // (i.e. disregarding possible selection on the iterator, but
     110             :   //  including the selection set when creating the VisSet)
     111             :   Vector<Int>& channel(Vector<Int>& chan) const;
     112             :   Vector<Int>& chanIds(Vector<Int>& chanids) const;
     113             :   Vector<Int>& chanIds(Vector<Int>& chanids,Int spw) const;
     114             : 
     115             :   // Return selected correlation indices
     116             :   Vector<Int>& corrIds(Vector<Int>& corrids) const;
     117             : 
     118             :   // Return flag for each polarization, channel and row
     119             :   Cube<Bool>& flag(Cube<Bool>& flags) const;
     120             : 
     121             :   // Return current frequencies
     122             :   Vector<Double>& frequency(Vector<Double>& freq) const;
     123             : 
     124             :   // Return the correlation type (returns Stokes enums)
     125             :   Vector<Int>& corrType(Vector<Int>& corrTypes) const;
     126             : 
     127             :   // Return sigma matrix (pol-dep)
     128             :   Matrix<Float>& sigmaMat(Matrix<Float>& sigmat) const;
     129             : 
     130             :   // Return the visibilities as found in the MS, Cube(npol,nchan,nrow).
     131             :   Cube<Complex>& visibility(Cube<Complex>& vis,
     132             :                             DataColumn whichOne) const;
     133             :   // Return weight matrix
     134             :   Matrix<Float>& weightMat(Matrix<Float>& wtmat) const;
     135             : 
     136             :   // Return weightspectrum (a weight for each corr & channel)
     137             :   Cube<Float>& weightSpectrum(Cube<Float>& wtsp) const;
     138             : 
     139             :   // Set up new chan/corr selection via Vector<Slice>
     140             :   void selectChannel(const Vector<Vector<Slice> >& chansel);
     141             :   void selectCorrelation(const Vector<Vector<Slice> >& corrsel);
     142             : 
     143             :   // Set up/return channel averaging bounds
     144             :   Vector<Matrix<Int> >& setChanAveBounds(Float factor, Vector<Matrix<Int> >& bounds);
     145             : 
     146             :   // Return number of chans/corrs per spw/pol
     147             :   Int numberChan(Int spw) const;
     148             :   Int numberCorr(Int pol) const;
     149             : 
     150             :   // Return the row ids as from the original root table. This is useful
     151             :   // to find correspondance between a given row in this iteration to the
     152             :   // original ms row
     153             :   Vector<rownr_t>& rowIds(Vector<rownr_t>& rowids) const;
     154             : 
     155             :   // Need to override this and not use getColArray
     156             :   Vector<RigidVector<Double,3> >& uvw(Vector<RigidVector<Double,3> >& uvwvec) const;
     157             : 
     158             : protected:
     159             : 
     160             :   void setSelTable();
     161             : 
     162             :   virtual const Table attachTable() const;
     163             : 
     164             :   // update the DATA slicer
     165             :   void updateSlicer();
     166             :   // attach the column objects to the currently selected table
     167             : 
     168             :   // The ROVisibilityIterator version of this function sets the tile cache to 1
     169             :   // because of a feature in sliced data access that grows memory dramatically in
     170             :   // some cases.  However, ROVisibilityIterator, because it uses
     171             :   // ArrayColumn::getColumn(Vector<Vector<Slice> >&), is (1/28/2011) incredibly
     172             :   // slow if the tile cache does not span all the selected channels, and it will
     173             :   // read orders of magnitude more data than it needs to.  This sets the tile
     174             :   // cache to the minimum number of tiles required to span the selected channels.
     175             :   // Unlike ROVisibilityIterator, it does it for each hypercube, not just the
     176             :   // first one, and it does its work when the DDID has changed.
     177             :   void setTileCache();
     178             : 
     179             :   void getDataColumn(DataColumn whichOne, const Vector<Vector<Slice> >& slices,
     180             :                              Cube<Complex>& data) const;
     181             : 
     182             :   // Column access functions
     183             :   void getCol(const ScalarColumn<Bool> &column, Vector<Bool> &array, Bool resize = false) const;
     184             :   void getCol(const ScalarColumn<Int> &column, Vector<Int> &array, Bool resize = false) const;
     185             :   void getCol(const ScalarColumn<Double> &column, Vector<Double> &array, Bool resize = false) const;
     186             : 
     187             :   void getCol(const ArrayColumn<Bool> &column, Array<Bool> &array, Bool resize = false) const;
     188             :   void getCol(const ArrayColumn<Float> &column, Array<Float> &array, Bool resize = false) const;
     189             :   void getCol(const ArrayColumn<Double> &column, Array<Double> &array, Bool resize = false) const;
     190             :   void getCol(const ArrayColumn<Complex> &column, Array<Complex> &array, Bool resize = false) const;
     191             : 
     192             :   void getCol(const ArrayColumn<Bool> &column, const Slicer &slicer, Array<Bool> &array, Bool resize = false) const;
     193             :   void getCol(const ArrayColumn<Float> &column, const Slicer &slicer, Array<Float> &array, Bool resize = false) const;
     194             :   void getCol(const ArrayColumn<Complex> &column, const Slicer &slicer, Array<Complex> &array, Bool resize = false) const;
     195             : 
     196             : 
     197             :   // New slicer supports multiple Slices in channel and correlation
     198             : 
     199             :   Vector<Matrix<Int> >   chanAveBounds_p;
     200             :   Vector<Vector<Slice> > chanSlices_p;
     201             :   Vector<Vector<Slice> > corrSlices_p;
     202             :   Vector<Vector<Slice> > newSlicer_p;
     203             :   Vector<Vector<Slice> > newWtSlicer_p;
     204             :   Table                  selTable_p;
     205             :   Bool                   useNewSlicer_p;
     206             : 
     207             : };
     208             : 
     209             : class VisIteratorImpl : public ROVisIteratorImpl {
     210             : 
     211             :     friend class ROVisIterator;
     212             :     friend class VisIterator;
     213             : 
     214             : public:
     215             : 
     216             :   // Default constructor - useful only to assign another iterator later
     217             :   VisIteratorImpl();
     218             : 
     219             :   // Construct from MS and a Block of MS column enums specifying the iteration
     220             :   // order, if none are specified, time iteration is implicit.  An optional
     221             :   // timeInterval can be given to iterate through chunks of time.  The default
     222             :   // interval of 0 groups all times together.  Every 'chunk' of data contains
     223             :   // all data within a certain time interval (in seconds) and with identical
     224             :   // values of the other iteration columns (e.g.  DATA_DESC_ID and FIELD_ID).
     225             :   // Using selectChannel(), a number of groups of channels can be requested.
     226             :   // At present the channel group iteration will always occur before the
     227             :   // interval iteration.
     228             :   VisIteratorImpl(ROVisIterator * rovi,
     229             :                     const MeasurementSet& ms,
     230             :                     const Block<Int>& sortColumns,
     231             :                     Double timeInterval=0);
     232             : 
     233             :   // Copy construct. This calls the assignment operator.
     234             :   VisIteratorImpl(const ROVisIteratorImpl & other);
     235             : 
     236             :   // Destructor
     237             :   ~VisIteratorImpl();
     238             : 
     239             :   // Assignment. Any attached VisBuffers are lost in the assign.
     240             :   VisIteratorImpl & operator=(const VisIteratorImpl &other);
     241             : 
     242             :   // Members
     243             : 
     244             :   // Advance iterator through data
     245             :   VisIteratorImpl & operator++(int);
     246             :   VisIteratorImpl & operator++();
     247             : 
     248             :   // Return channel numbers in selected VisSet spectrum
     249             :   // (i.e. disregarding possible selection on the iterator, but
     250             :   //  including the selection set when creating the VisSet)
     251             :   //Vector<Int>& channel(Vector<Int>& chan) const;
     252             :   //Vector<Int>& chanIds(Vector<Int>& chanids) const;
     253             :   //Vector<Int>& chanIds(Vector<Int>& chanids,Int spw) const;
     254             : 
     255             :   // Return selected correlation indices
     256             :   //Vector<Int>& corrIds(Vector<Int>& corrids) const;
     257             : 
     258             :   // Return flag for each polarization, channel and row
     259             :   //Cube<Bool>& flag(Cube<Bool>& flags) const;
     260             : 
     261             :   // Return current frequencies
     262             :   //Vector<Double>& frequency(Vector<Double>& freq) const;
     263             : 
     264             :   // Return the correlation type (returns Stokes enums)
     265             :   //Vector<Int>& corrType(Vector<Int>& corrTypes) const;
     266             : 
     267             :   // Return sigma matrix (pol-dep)
     268             :   //Matrix<Float>& sigmaMat(Matrix<Float>& sigmat) const;
     269             : 
     270             :   // Return the visibilities as found in the MS, Cube(npol,nchan,nrow).
     271             :   //Cube<Complex>& visibility(Cube<Complex>& vis,
     272             :                             //DataColumn whichOne) const;
     273             :   // Return weight matrix
     274             :   //Matrix<Float>& weightMat(Matrix<Float>& wtmat) const;
     275             : 
     276             :   // Return weightspectrum (a weight for each corr & channel)
     277             :   //Cube<Float>& weightSpectrum(Cube<Float>& wtsp) const;
     278             : 
     279             :   // Set up new chan/corr selection via Vector<Slice>
     280             :   //void selectChannel(const Vector<Vector<Slice> >& chansel);
     281             :   //void selectCorrelation(const Vector<Vector<Slice> >& corrsel);
     282             : 
     283             :   // Set up/return channel averaging bounds
     284             :   //Vector<Matrix<Int> >& setChanAveBounds(Float factor, Vector<Matrix<Int> >& bounds);
     285             : 
     286             :   // Return number of chans/corrs per spw/pol
     287             :   //Int numberChan(Int spw) const;
     288             :   //Int numberCorr(Int pol) const;
     289             : 
     290             :   // Return the row ids as from the original root table. This is useful
     291             :   // to find correspondance between a given row in this iteration to the
     292             :   // original ms row
     293             :   //Vector<uInt>& rowIds(Vector<uInt>& rowids) const;
     294             : 
     295             :   // Need to override this and not use getColArray
     296             :   //Vector<RigidVector<Double,3> >& uvw(Vector<RigidVector<Double,3> >& uvwvec) const;
     297             : 
     298             :   // Set/modify the flag row column; dimension Vector(nrow)
     299             :   void setFlagRow(const Vector<Bool>& rowflags);
     300             : 
     301             :   // Set/modify the flags in the data.
     302             :   // This sets the flags as found in the MS, Cube(npol,nchan,nrow),
     303             :   // where nrow is the number of rows in the current iteration (given by
     304             :   // nRow()).
     305             :   void setFlag(const Cube<Bool>& flag);
     306             : 
     307             :   // Set/modify the visibilities
     308             :   // This sets the data as found in the MS, Cube(npol,nchan,nrow).
     309             :   void setVis(const Cube<Complex>& vis, DataColumn whichOne);
     310             : 
     311             :   // Set the visibility and flags, and interpolate from velocities if needed
     312             :   void setVisAndFlag(const Cube<Complex>& vis, const Cube<Bool>& flag,
     313             :                      DataColumn whichOne);
     314             : 
     315             :   // Set/modify the weightMat
     316             :   void setWeightMat(const Matrix<Float>& wtmat);
     317             : 
     318             :   // Set/modify the weightSpectrum
     319             :   void setWeightSpectrum(const Cube<Float>& wtsp);
     320             : 
     321             : protected:
     322             : 
     323             :   //void setSelTable();
     324             : 
     325             :   void attachColumns (const Table & t);
     326             : 
     327             :   // update the DATA slicer
     328             :   //void updateSlicer();
     329             :   // attach the column objects to the currently selected table
     330             : 
     331             :   // The ROVisibilityIterator version of this function sets the tile cache to 1
     332             :   // because of a feature in sliced data access that grows memory dramatically in
     333             :   // some cases.  However, ROVisibilityIterator, because it uses
     334             :   // ArrayColumn::getColumn(Vector<Vector<Slice> >&), is (1/28/2011) incredibly
     335             :   // slow if the tile cache does not span all the selected channels, and it will
     336             :   // read orders of magnitude more data than it needs to.  This sets the tile
     337             :   // cache to the minimum number of tiles required to span the selected channels.
     338             :   // Unlike ROVisibilityIterator, it does it for each hypercube, not just the
     339             :   // first one, and it does its work when the DDID has changed.
     340             : 
     341             :   void getDataColumn(DataColumn whichOne, const Vector<Vector<Slice> >& slices,
     342             :                              Cube<Complex>& data) const;
     343             : 
     344             :   // Column access functions
     345             : //  void getCol(const ScalarColumn<Bool> &column, Vector<Bool> &array, Bool resize = false) const;
     346             : //  void getCol(const ScalarColumn<Int> &column, Vector<Int> &array, Bool resize = false) const;
     347             : //  void getCol(const ScalarColumn<Double> &column, Vector<Double> &array, Bool resize = false) const;
     348             : //
     349             : //  void getCol(const ArrayColumn<Bool> &column, Array<Bool> &array, Bool resize = false) const;
     350             : //  void getCol(const ArrayColumn<Float> &column, Array<Float> &array, Bool resize = false) const;
     351             : //  void getCol(const ArrayColumn<Double> &column, Array<Double> &array, Bool resize = false) const;
     352             : //  void getCol(const ArrayColumn<Complex> &column, Array<Complex> &array, Bool resize = false) const;
     353             : //
     354             : //  void getCol(const ArrayColumn<Bool> &column, const Slicer &slicer, Array<Bool> &array, Bool resize = false) const;
     355             : //  void getCol(const ArrayColumn<Float> &column, const Slicer &slicer, Array<Float> &array, Bool resize = false) const;
     356             : //  void getCol(const ArrayColumn<Complex> &column, const Slicer &slicer, Array<Complex> &array, Bool resize = false) const;
     357             : 
     358             :   void putDataColumn(DataColumn whichOne,
     359             :                      const Cube<Complex>& data);
     360             : 
     361             :   void putDataColumn(DataColumn whichOne,
     362             :                      const Vector<Vector<Slice> >& slices,
     363             :                      const Cube<Complex>& data);
     364             : 
     365             :   // New slicer supports multiple Slices in channel and correlation
     366             : 
     367             : //  Vector<Matrix<Int> >   chanAveBounds_p;
     368             : //  Vector<Vector<Slice> > chanSlices_p;
     369             : //  Vector<Vector<Slice> > corrSlices_p;
     370             : //  Vector<Vector<Slice> > newSlicer_p;
     371             : //  Vector<Vector<Slice> > newWtSlicer_p;
     372             : //  Table                  selTable_p;
     373             : //  Bool                   useNewSlicer_p;
     374             : 
     375             :   ArrayColumn<Complex> rwColVis_p;
     376             :   ArrayColumn<Float> rwColFloatVis_p;
     377             :   ArrayColumn<Complex> rwColModelVis_p;
     378             :   ArrayColumn<Complex> rwColCorrVis_p;
     379             :   ArrayColumn<Float> rwColWeight_p;
     380             :   ArrayColumn<Float> rwColWeightSpectrum_p;
     381             :   ArrayColumn<Float> rwColSigma_p;
     382             :   ArrayColumn<Bool> rwColFlag_p;
     383             :   ScalarColumn<Bool> rwColFlagRow_p;
     384             : };
     385             : 
     386             : //     ********************
     387             : //     ********************
     388             : //     **                **
     389             : //     **  ROVisIterator **
     390             : //     **                **
     391             : //     ********************
     392             : //     ********************
     393             : 
     394           0 : ROVisIterator::ROVisIterator()
     395             : {
     396           0 : }
     397             : 
     398           0 : ROVisIterator::ROVisIterator(const MeasurementSet & ms, const Block<Int>& sortColumns, Double timeInterval)
     399           0 : : ROVisibilityIterator (ms, sortColumns, timeInterval, Factory (this))
     400           0 : {}
     401             : 
     402           0 : ROVisIterator::ROVisIterator(const MeasurementSet & ms, const Block<Int>& sortColumns,
     403           0 :                              Double timeInterval, const ROVisibilityIterator::Factory & factory)
     404           0 : : ROVisibilityIterator (ms, sortColumns, timeInterval, factory)
     405           0 : {}
     406             : 
     407             : 
     408           0 : ROVisIterator::ROVisIterator(const ROVisIterator & other)
     409           0 : : ROVisibilityIterator (other)
     410           0 : {}
     411             : 
     412           0 : ROVisIterator::~ROVisIterator()
     413           0 : {}
     414             : 
     415             : ROVisIterator &
     416           0 : ROVisIterator::operator=(const ROVisIterator & other)
     417             : {
     418           0 :     ROVisibilityIterator::operator= (other);
     419             : 
     420           0 :     return * this;
     421             : }
     422             : 
     423             : ROVisIterator &
     424           0 : ROVisIterator::operator++(int)
     425             : {
     426           0 :     advance();
     427           0 :     return * this;
     428             : }
     429             : 
     430             : ROVisIterator &
     431           0 : ROVisIterator::operator++()
     432             : {
     433           0 :     advance();
     434           0 :     return * this;
     435             : }
     436             : 
     437             : Vector<Int>&
     438           0 : ROVisIterator::chanIds(Vector<Int>& chanids) const
     439             : {
     440           0 :     return getReadImpl()->chanIds(chanids);
     441             : }
     442             : 
     443             : Vector<Int>&
     444           0 : ROVisIterator::chanIds(Vector<Int>& chanids, Int spw) const
     445             : {
     446           0 :     return getReadImpl()->chanIds(chanids, spw);
     447             : }
     448             : 
     449             : Vector<Int>&
     450           0 : ROVisIterator::corrIds(Vector<Int>& corrids) const
     451             : {
     452           0 :     return getReadImpl()->corrIds(corrids);
     453             : }
     454             : 
     455             : 
     456             : Vector<Int>&
     457           0 : ROVisIterator::corrType(Vector<Int>& corrTypes) const
     458             : {
     459           0 :     return getReadImpl()->corrType(corrTypes);
     460             : }
     461             : 
     462             : ROVisIteratorImpl *
     463           0 : ROVisIterator::getReadImpl () const
     464             : {
     465           0 :     ROVisIteratorImpl * impl = dynamic_cast<ROVisIteratorImpl *> (ROVisibilityIterator::getReadImpl ());
     466             : 
     467           0 :     Assert (impl != NULL);
     468             : 
     469           0 :     return impl;
     470             : }
     471             : 
     472             : void
     473           0 : ROVisIterator::selectChannel(const Vector<Vector<Slice> >& chansel)
     474             : {
     475           0 :     return getReadImpl()->selectChannel(chansel);
     476             : }
     477             : 
     478             : void
     479           0 : ROVisIterator::selectCorrelation(const Vector<Vector<Slice> >& corrsel)
     480             : {
     481           0 :     return getReadImpl()->selectCorrelation(corrsel);
     482             : }
     483             : 
     484             : Vector<Matrix<Int> >&
     485           0 : ROVisIterator::setChanAveBounds(Float factor, Vector<Matrix<Int> >& bounds)
     486             : {
     487           0 :     return getReadImpl()->setChanAveBounds(factor, bounds);
     488             : }
     489             : 
     490             : void
     491           0 : ROVisIteratorImpl::setTileCache()
     492             : {
     493             :   // Set the cache size when the DDID changes (as opposed to MS) to avoid
     494             :   // overreading in a case like:
     495             :   // hcubes: [2, 256], [4, 64]
     496             :   // tileshape: [4, 64]
     497             :   // spws (ddids): [4,64], [2, 256], [2, 256], [4,64], [2, 256], [4,64]
     498             :   // and spw = '0:1~7,1:1~7,2:100~200,3:20~40,4:200~230,5:40~50'
     499             :   //
     500             :   // For hypercube 0, spw 2 needs 3 tiles, but spw 4 only needs 1, AND the last
     501             :   // tile at that.  So if hypercube 0 used a cache of 3 tiles throughout, every
     502             :   // read of 4:200~230 would likely also read the unwanted channels 0~127 of
     503             :   // the next row.
     504             :   //
     505           0 :   if (curStartRow_p != 0 && ! msIter_p.newDataDescriptionId()){
     506           0 :     return;
     507             :   }
     508             : 
     509           0 :   const MeasurementSet& thems = msIter_p.ms();
     510             : 
     511           0 :   if(thems.tableType() == Table::Memory){
     512           0 :     return;
     513             :   }
     514             : 
     515           0 :   const ColumnDescSet& cds=thems.tableDesc().columnDescSet();
     516             : 
     517             :   // Get the first row number for this DDID.
     518           0 :   Vector<rownr_t> rownums;
     519           0 :   rowIds(rownums);
     520           0 :   uInt startrow = rownums[0];
     521             : 
     522           0 :   Vector<String> columns(8);
     523             :   // complex
     524           0 :   columns(0)=MS::columnName(MS::DATA);
     525           0 :   columns(1)=MS::columnName(MS::CORRECTED_DATA);
     526           0 :   columns(2)=MS::columnName(MS::MODEL_DATA);
     527             :   // boolean
     528           0 :   columns(3)=MS::columnName(MS::FLAG);
     529             :   // float
     530           0 :   columns(4)=MS::columnName(MS::WEIGHT_SPECTRUM);
     531           0 :   columns(5)=MS::columnName(MS::WEIGHT);
     532           0 :   columns(6)=MS::columnName(MS::SIGMA);
     533             :   // double
     534           0 :   columns(7)=MS::columnName(MS::UVW);
     535             :   //
     536           0 :   for(uInt k = 0; k < columns.nelements(); ++k){
     537           0 :     if(cds.isDefined(columns(k))){
     538           0 :       const ColumnDesc& cdesc = cds[columns(k)];
     539           0 :       String dataManType="";
     540             : 
     541           0 :       dataManType = cdesc.dataManagerType();
     542             :       // We have to check WEIGHT_SPECTRUM as it tends to exist but not have
     543             :       // valid data.
     544           0 :       if(columns[k] == MS::columnName(MS::WEIGHT_SPECTRUM) &&
     545           0 :          !existsWeightSpectrum())
     546           0 :         dataManType="";
     547             : 
     548             :       // Sometimes columns may not contain anything yet
     549           0 :       if((columns[k]==MS::columnName(MS::DATA) && (columns_p.vis_p.isNull() ||
     550           0 :                                                    !columns_p.vis_p.isDefined(0))) ||
     551           0 :          (columns[k]==MS::columnName(MS::MODEL_DATA) && (columns_p.modelVis_p.isNull() ||
     552           0 :                                                          !columns_p.modelVis_p.isDefined(0))) ||
     553           0 :          (columns[k]==MS::columnName(MS::CORRECTED_DATA) && (columns_p.corrVis_p.isNull() ||
     554           0 :                                                              !columns_p.corrVis_p.isDefined(0))) ||
     555           0 :          (columns[k]==MS::columnName(MS::FLAG) && (columns_p.flag_p.isNull() ||
     556           0 :                                                    !columns_p.flag_p.isDefined(0))) ||
     557           0 :          (columns[k]==MS::columnName(MS::WEIGHT) && (columns_p.weight_p.isNull() ||
     558           0 :                                                      !columns_p.weight_p.isDefined(0))) ||
     559           0 :          (columns[k]==MS::columnName(MS::SIGMA) && (columns_p.sigma_p.isNull() ||
     560           0 :                                                     !columns_p.sigma_p.isDefined(0))) ||
     561           0 :          (columns[k]==MS::columnName(MS::UVW) && (columns_p.uvw_p.isNull() ||
     562           0 :                                                   !columns_p.uvw_p.isDefined(0))) ){
     563           0 :         dataManType="";
     564             :       }
     565             : 
     566           0 :       if(dataManType.contains("Tiled") &&
     567           0 :          !String(cdesc.dataManagerGroup()).empty()){
     568             :         try {
     569             :           ROTiledStManAccessor tacc=ROTiledStManAccessor(thems,
     570           0 :                                                          cdesc.dataManagerGroup());
     571             : 
     572             :           // This is for the data columns, WEIGHT_SPECTRUM and FLAG only.
     573           0 :           if((columns[k] != MS::columnName(MS::WEIGHT)) &&
     574           0 :              (columns[k] != MS::columnName(MS::UVW))){
     575             :             // Figure out how many tiles are needed to span the selected channels.
     576           0 :             const IPosition tileShape(tacc.tileShape(startrow));
     577           0 :             Vector<Int> ids;
     578           0 :             chanIds(ids);
     579           0 :             uInt startTile = ids[0] / tileShape[1];
     580           0 :             uInt endTile = ids[ids.nelements() - 1] / tileShape[1];
     581           0 :             uInt cachesize = endTile - startTile + 1;
     582             : 
     583             :             // and the selected correlations.
     584           0 :             corrIds(ids);
     585           0 :             startTile = ids[0] / tileShape[0];
     586           0 :             endTile = ids[ids.nelements() - 1] / tileShape[0];
     587           0 :             cachesize *= endTile - startTile + 1;
     588             : 
     589             :             // The cache needs to hold enough tiles to provide the data
     590             :             // for a single row for all channels and all correlations.
     591             :             // Determine the number of tiles in the 0 and 1 directions,
     592             :             // round them up to the nearest integer and take the product
     593             :             // of the two to yield the number of tiles needed.
     594             :             //
     595             :             // This could be reduced a little bit if necessary by using the
     596             :             // actual frequency selection since the current calculation uses
     597             :             // all of the channels in the row, thus reserves space in the cache
     598             :             // for tiles which contain no selected data (however the logic doesn't
     599             :             // appear to read those into the cache so there is no performance
     600             :             // penalty).
     601             : 
     602           0 :             const IPosition hShape(tacc.hypercubeShape(startrow));
     603             : 
     604           0 :             float nTiles0 = hShape [0] / (float) (tileShape [0]);
     605           0 :             float nTiles1 = hShape [1] / (float) (tileShape [1]);
     606             : 
     607           0 :             cachesize = (uInt) (ceil (nTiles0) * ceil (nTiles1));
     608             : 
     609           0 :             tacc.setCacheSize(startrow, cachesize);
     610           0 :           }
     611             :           else
     612           0 :             tacc.setCacheSize(startrow, 1);
     613           0 :         }
     614           0 :         catch (AipsError x) {
     615             :           //It failed so leave the caching as is.
     616           0 :           continue;
     617           0 :         }
     618             :       }
     619           0 :     }
     620             :   }
     621           0 : }
     622             : 
     623             : 
     624             : // Selected spws and channel counts
     625           0 : void ROVisIterator::allSelectedSpectralWindows (Vector<Int> & spws, Vector<Int> & nvischan)
     626             : {
     627           0 :   getReadImpl()->allSelectedSpectralWindows(spws,nvischan);
     628           0 : }
     629             : 
     630           0 : void ROVisIterator::lsrFrequency(const Int& spw, Vector<Double>& freq, Bool& convert, const  Bool ignoreconv)
     631             : {
     632           0 :   getReadImpl()->lsrFrequency(spw,freq,convert,ignoreconv);
     633           0 : }
     634             : 
     635             : 
     636             : Int
     637           0 : ROVisIterator::numberChan(Int spw) const
     638             : {
     639           0 :     return getReadImpl()->numberChan(spw);
     640             : }
     641             : 
     642             : Int
     643           0 : ROVisIterator::numberCorr(Int pol) const
     644             : {
     645           0 :     return getReadImpl()->numberCorr(pol);
     646             : }
     647             : 
     648             : void
     649           0 : ROVisIterator::getDataColumn(DataColumn whichOne, const Vector<Vector<Slice> >& slices, Cube<Complex>& data) const
     650             : {
     651           0 :     getReadImpl()->getDataColumn(whichOne, slices, data);
     652           0 : }
     653             : 
     654             : VisibilityIteratorReadImpl *
     655           0 : ROVisIterator::Factory::operator() (const asyncio::PrefetchColumns * /*prefetchColumns*/,
     656             :                                     const Block<MeasurementSet>& mss,
     657             :                                     const Block<Int>& sortColumns,
     658             :                                     const Bool /*addDefaultSortCols*/,
     659             :                                     Double timeInterval) const
     660             : {
     661           0 :     return new ROVisIteratorImpl (vi_p, mss[0], sortColumns, timeInterval);
     662             : }
     663             : 
     664             : //     *************************
     665             : //     *************************
     666             : //     **                     **
     667             : //     **  ROVisIteratorImpl  **
     668             : //     **                     **
     669             : //     *************************
     670             : //     *************************
     671             : 
     672           0 : ROVisIteratorImpl::ROVisIteratorImpl() {}
     673             : 
     674           0 : ROVisIteratorImpl::ROVisIteratorImpl(ROVisIterator * rovi,
     675             :                                      const MeasurementSet &ms,
     676             :                                      const Block<Int>& sortColumns,
     677           0 :                                      Double timeInterval)
     678           0 : : VisibilityIteratorReadImpl(rovi, Block<MeasurementSet> (1, ms), sortColumns, true, timeInterval),
     679           0 :   useNewSlicer_p(false)
     680             : {
     681             : 
     682             :     // Initialize multi-slicers with empty slices
     683           0 :     chanSlices_p.resize(numberSpw());
     684           0 :     chanSlices_p.set(Vector<Slice>());
     685           0 :     corrSlices_p.resize(numberPol());
     686           0 :     corrSlices_p.set(Vector<Slice>());
     687             : 
     688           0 : }
     689             : 
     690           0 : ROVisIteratorImpl::ROVisIteratorImpl(const ROVisIteratorImpl& other)
     691           0 : : VisibilityIteratorReadImpl (other)
     692             : {
     693           0 :     operator=(other);
     694           0 : }
     695             : 
     696           0 : ROVisIteratorImpl::~ROVisIteratorImpl() {}
     697             : 
     698             : ROVisIteratorImpl&
     699           0 : ROVisIteratorImpl::operator=(const ROVisIteratorImpl& other)
     700             : {
     701           0 :   if (this!=&other) {
     702             : 
     703           0 :     VisibilityIteratorReadImpl::operator=(other);
     704             : 
     705           0 :     chanAveBounds_p = other.chanAveBounds_p;
     706           0 :     chanSlices_p = other.chanSlices_p;
     707           0 :     corrSlices_p = other.corrSlices_p;
     708           0 :     newSlicer_p = other.newSlicer_p;
     709           0 :     newWtSlicer_p = other.newWtSlicer_p;
     710           0 :     selTable_p = other.selTable_p;
     711           0 :     useNewSlicer_p = other.useNewSlicer_p;
     712             : 
     713             :   }
     714             : 
     715           0 :   return *this;
     716             : }
     717             : 
     718           0 : ROVisIteratorImpl & ROVisIteratorImpl::operator++(int)
     719             : {
     720           0 :   if (! more ()){
     721           0 :       advance();
     722             :   }
     723           0 :   return *this;
     724             : }
     725             : 
     726           0 : ROVisIteratorImpl & ROVisIteratorImpl::operator++()
     727             : {
     728           0 :   if (! more ()){
     729           0 :       advance();
     730             :   }
     731           0 :   return *this;
     732             : }
     733             : 
     734             : 
     735             : 
     736           0 : void ROVisIteratorImpl::updateSlicer()
     737             : {
     738           0 :   useNewSlicer_p=true;
     739             : 
     740             :   //    cout << "Using new slicer!..." << flush;
     741             :   
     742           0 :   newSlicer_p.resize(2);
     743           0 :   newWtSlicer_p.resize(1);
     744             :   
     745             :   //    cout << "newSlicer_p.shape() = " << newSlicer_p.shape() << endl;
     746             :   
     747           0 :   useSlicer_p=false;
     748             :   
     749             :   // Refer to correct slices for the current spwid/polid
     750           0 :   newSlicer_p(0).reference(corrSlices_p(this->polarizationId()));
     751           0 :   newSlicer_p(1).reference(chanSlices_p(this->spectralWindow()));
     752             :   
     753           0 :   newWtSlicer_p(0).reference(corrSlices_p(this->polarizationId()));
     754             : 
     755           0 :   setTileCache();
     756           0 : }
     757             : 
     758             : // 
     759             : 
     760             : // Selected spws and channel counts
     761           0 : void ROVisIteratorImpl::allSelectedSpectralWindows (Vector<Int> & spws, Vector<Int> & nvischan) {
     762             : 
     763           0 :   Vector<Int> ddids;
     764           0 :   msColumns().dataDescId().getColumn(ddids);
     765           0 :   Int ndd=genSort(ddids, Sort::Ascending, (Sort::QuickSort | Sort::NoDuplicates));
     766           0 :   ddids.resize(ndd,true);
     767             :   //  cout << "ddids = " << ddids << endl;
     768           0 :   Vector<Int> spwperdd;
     769           0 :   msColumns().dataDescription().spectralWindowId().getColumn(spwperdd);
     770             :   //  cout << "spwperdd = " << spwperdd << endl;
     771           0 :   spws.resize(ndd);
     772           0 :   nvischan.resize(numberSpw());
     773           0 :   nvischan.set(-1);
     774           0 :   for (Int idd=0;idd<ndd;++idd) {
     775           0 :     spws(idd)=spwperdd(ddids(idd));
     776           0 :     nvischan(spws(idd))=this->numberChan(spws(idd));
     777             :   }
     778             : 
     779           0 : }
     780             : 
     781           0 : void ROVisIteratorImpl::lsrFrequency(const Int& spw, Vector<Double>& freq, 
     782             :                                      Bool& convert, const  Bool ignoreconv) {
     783             : 
     784             : 
     785           0 :   MFrequency::Types obsMFreqType = (MFrequency::Types) msIter_p.msColumns ().spectralWindow ().measFreqRef ()(spw);
     786           0 :   convert = obsMFreqType != MFrequency::LSRK; // make this parameter write-only
     787           0 :   if (ignoreconv) convert=false;  // override if user says so
     788             : 
     789             :   // Set up the frequency converter
     790           0 :   MEpoch ep;
     791           0 :   ROScalarMeasColumn<MEpoch>(msIter_p.table (), MS::columnName (MS::TIME)).get (curStartRow_p, ep); // Setting epoch to iteration's first one
     792           0 :   MPosition obsPos = msIter_p.telescopePosition ();
     793           0 :   MDirection dir = msIter_p.phaseCenter ();
     794           0 :   MeasFrame frame (ep, obsPos, dir);
     795             :   MFrequency::Convert tolsr (obsMFreqType,
     796           0 :                              MFrequency::Ref (MFrequency::LSRK, frame));
     797             : 
     798             : 
     799             :   // Get the requested spw's nominal frequencies (all of them)
     800             :   //  (we will index these with channel ids later)
     801           0 :   Vector<Double> chanFreq(0);
     802           0 :   chanFreq = msIter_p.msColumns ().spectralWindow ().chanFreq ()(spw);
     803             : 
     804             :   // The selected channel ids for the requested spw
     805           0 :   Vector<Int> chans(0);
     806           0 :   this->chanIds(chans,spw);
     807           0 :   Int nchan=chans.nelements();
     808             : 
     809             :   // Create output frequencies
     810           0 :   freq.resize(nchan);
     811           0 :   for (Int ich=0;ich<nchan;++ich) {
     812           0 :     if (convert)
     813           0 :       freq[ich]=tolsr(chanFreq(chans(ich))).getValue().getValue();
     814             :     else
     815           0 :       freq[ich]=chanFreq(chans(ich));
     816             : 
     817             :   }
     818             : 
     819           0 : }
     820             : 
     821             : 
     822             : // (Alternative syntax for ROVisIter::chanIds)
     823           0 : Vector<Int>& ROVisIteratorImpl::channel(Vector<Int>& chan) const
     824           0 : { return this->chanIds(chan); }
     825             : 
     826             : 
     827           0 : Vector<Int>& ROVisIteratorImpl::chanIds(Vector<Int>& chanids) const
     828             : {
     829           0 :   return chanIds(chanids,msIter_p.spectralWindowId());
     830             : }
     831             : 
     832           0 : Vector<Int>& ROVisIteratorImpl::chanIds(Vector<Int>& chanids, Int spw) const
     833             : {
     834             : 
     835           0 :   chanids.resize(this->numberChan(spw));
     836             : 
     837             :   // if non-trivial slices available
     838           0 :   if (chanSlices_p(spw).nelements() > 0 ) {
     839             :     
     840           0 :     Vector<Slice> slices(chanSlices_p(spw));
     841           0 :     Int nslices=slices.nelements();
     842             :     
     843           0 :     Int ich0=0;
     844           0 :     for (Int i=0;i<nslices;++i) {
     845           0 :       Int nchan=slices(i).length();
     846           0 :       Int start=slices(i).start();
     847           0 :       for (Int ich=0;ich<nchan;++ich,++ich0) 
     848           0 :         chanids(ich0)=start+ich;
     849             :     }
     850           0 :   }
     851             :   else {
     852             :     // all channels selected...
     853           0 :     indgen(chanids);
     854             :   }
     855           0 :   return chanids;
     856             : }
     857             : 
     858           0 : void ROVisIteratorImpl::setSelTable()
     859             : {
     860           0 :     VisibilityIteratorReadImpl::setSelTable();
     861             : 
     862             :     // The following code (which uses Table::operator() to create
     863             :     // a new RefTable) is computationally expensive. This could
     864             :     // be optimized by using the same method as in the
     865             :     // VisibilityIterator base class (which is to not create
     866             :     // RefTables but instead access the table column directly in
     867             :     // getReadImpl()->msIter_p.table() using VisibilityIterator::getReadImpl()->selRows_p).
     868             : 
     869             :     // Doing so would mean replacing calls like
     870             :     //     colSigma.getColumn(newWtSlicer_p,sigmat,true);
     871             :     // with
     872             :     //     colSigma.getColumnCells(getReadImpl()->selRows_p,newWtSlicer_p,sigmat,true);
     873             :     //
     874             :     // However the ArrayColumn class does allow passing both a 
     875             :     // Vector<Vector<Slice> > and a RefRows parameter to get-/putColumn.
     876             :     // Such put/get functions must be first implemented.
     877             : 
     878           0 :     Vector<rownr_t> rows(curNumRow_p);
     879           0 :     indgen(rows,curStartRow_p);
     880           0 :     selTable_p=msIter_p.table()(rows);
     881           0 :     attachColumns(attachTable());
     882           0 : }
     883             : 
     884             : // Return native correlation _indices_
     885           0 : Vector<Int>& ROVisIteratorImpl::corrIds(Vector<Int>& corrids) const
     886             : {
     887           0 :   Int pol = msIter_p.polarizationId();
     888             : 
     889           0 :   corrids.resize(this->numberCorr(pol));
     890             : 
     891           0 :   Vector<Slice> slices(corrSlices_p(pol));
     892           0 :   Int nslices=slices.nelements();
     893             :   
     894             :   // if non-trivial slices available
     895           0 :   if (nslices > 0 ) {
     896             :     
     897           0 :     Int icor0=0;
     898           0 :     for (Int i=0;i<nslices;++i) {
     899           0 :       Int ncorr=slices(i).length();
     900           0 :       Int start=slices(i).start();
     901           0 :       for (Int icor=0;icor<ncorr;++icor,++icor0) 
     902           0 :         corrids(icor0)=start+icor;
     903             :     }
     904             :   }
     905             :   else {
     906             :     // all corrs selected...
     907           0 :     indgen(corrids);
     908             :   }
     909             : 
     910           0 :   return corrids;
     911           0 : }
     912             : 
     913             : Vector<Int>&
     914           0 : ROVisIteratorImpl::corrType(Vector<Int>& corrTypes) const
     915             : {
     916             : 
     917             :   // Get the nominal corrType list
     918           0 :   Int polId = msIter_p.polarizationId();
     919           0 :   Vector<Int> nomCorrTypes;
     920           0 :   msIter_p.msColumns().polarization().corrType().get(polId,nomCorrTypes,true);
     921             : 
     922             :   // Get the 0-based corr indices
     923           0 :   Vector<Int> corrids;
     924           0 :   corrIds(corrids);
     925             : 
     926             :   // Set the corrType values by the corrids
     927           0 :   Int nCor=corrids.nelements();
     928           0 :   corrTypes.resize(nCor);
     929           0 :   for (Int icor=0;icor<nCor;++icor)
     930           0 :     corrTypes[icor]=nomCorrTypes[corrids[icor]];
     931             : 
     932           0 :   return corrTypes;
     933           0 : }
     934             : 
     935           0 : Cube<Bool>& ROVisIteratorImpl::flag(Cube<Bool>& flags) const
     936             : {
     937           0 :   if (useNewSlicer_p){
     938           0 :       columns_p.flag_p.getColumn(newSlicer_p,flags,true);
     939             :   }
     940             :   else {
     941           0 :       columns_p.flag_p.getColumn(flags,true);
     942             :   }
     943           0 :   return flags;
     944             : }
     945             : 
     946           0 : Vector<Double>& ROVisIteratorImpl::frequency(Vector<Double>& freq) const
     947             : {
     948             :   
     949             :   // We need to change some internals transparently
     950             :   //ROVisIteratorImpl* self = const_cast<ROVisIteratorImpl*>(this);
     951             : 
     952           0 :   if (! cache_p.freqCacheOK_p) {
     953           0 :     cache_p.freqCacheOK_p=true;
     954           0 :     const Vector<Double>& chanFreq=msIter_p.frequency();
     955           0 :     Vector<Int> chan;
     956           0 :     channel(chan);
     957           0 :     Int nch=chan.nelements();
     958           0 :     cache_p.frequency_p.resize(nch);
     959             : 
     960           0 :     for (Int i=0;i<nch;++i){
     961           0 :       cache_p.frequency_p(i)=chanFreq(chan(i));
     962             :     }
     963           0 :   }
     964             :   // Always copy to output
     965           0 :   freq.resize(cache_p.frequency_p.nelements());
     966           0 :   freq=cache_p.frequency_p;
     967             : 
     968           0 :   return freq;
     969             : }
     970             : 
     971             : Cube<Complex>& 
     972           0 : ROVisIteratorImpl::visibility(Cube<Complex>& vis, DataColumn whichOne) const
     973             : {
     974           0 :   if (useNewSlicer_p){
     975           0 :       getDataColumn(whichOne,newSlicer_p,vis);
     976             :   }
     977             :   else {
     978           0 :       VisibilityIteratorReadImpl::getDataColumn(whichOne,vis);
     979             :   }
     980           0 :   return vis;
     981             : }
     982             : 
     983           0 : void ROVisIteratorImpl::getDataColumn(DataColumn whichOne,
     984             :                                   const Vector<Vector<Slice> >& slices,
     985             :                                   Cube<Complex>& data) const
     986             : { 
     987             :   // Return the visibility (observed, model or corrected);
     988             :   // deal with DATA and FLOAT_DATA seamlessly for observed data.
     989           0 :   switch (whichOne) {
     990           0 :   case ROVisIterator::Observed:
     991           0 :     if (floatDataFound_p) {
     992           0 :       Cube<Float> dataFloat;
     993           0 :       columns_p.floatVis_p.getColumn(slices,dataFloat,true);
     994           0 :       data.resize(dataFloat.shape());
     995           0 :       convertArray(data,dataFloat);
     996           0 :     } else {
     997           0 :       columns_p.vis_p.getColumn(slices,data,true);
     998             :     };
     999           0 :     break;
    1000           0 :   case ROVisIterator::Corrected:
    1001           0 :     columns_p.corrVis_p.getColumn(slices,data,true);
    1002           0 :     break;
    1003           0 :   case ROVisIterator::Model:
    1004           0 :     columns_p.modelVis_p.getColumn(slices,data,true);
    1005           0 :     break;
    1006             :   };
    1007             :  
    1008           0 : };
    1009             : 
    1010           0 : Matrix<Float>& ROVisIteratorImpl::sigmaMat(Matrix<Float>& sigmat) const
    1011             : {
    1012           0 :   if (useNewSlicer_p) columns_p.sigma_p.getColumn(newWtSlicer_p,sigmat,true);
    1013             :   else {
    1014           0 :     sigmat.resize(nPol_p,curNumRow_p);
    1015           0 :     columns_p.sigma_p.getColumn(sigmat);
    1016             :   }
    1017           0 :   return sigmat;
    1018             : }
    1019             : 
    1020           0 : Matrix<Float>& ROVisIteratorImpl::weightMat(Matrix<Float>& wtmat) const
    1021             : {
    1022           0 :   if (useNewSlicer_p) columns_p.weight_p.getColumn(newWtSlicer_p,wtmat,true);
    1023             :   else {
    1024           0 :     wtmat.resize(nPol_p,curNumRow_p);
    1025           0 :     columns_p.weight_p.getColumn(wtmat);
    1026             :   }
    1027           0 :   return wtmat;
    1028             : }
    1029             : 
    1030           0 : Cube<Float>& ROVisIteratorImpl::weightSpectrum(Cube<Float>& wtsp) const
    1031             : {
    1032           0 :   if (this->existsWeightSpectrum()) {
    1033           0 :     if (useNewSlicer_p) columns_p.weightSpectrum_p.getColumn(newSlicer_p,wtsp,true);
    1034             :     else {
    1035           0 :       wtsp.resize(nPol_p,nChan_p,curNumRow_p);
    1036           0 :       columns_p.weightSpectrum_p.getColumn(wtsp);
    1037             :     }
    1038             :   } else {
    1039           0 :     wtsp.resize(0,0,0);
    1040             :   }
    1041           0 :   return wtsp;
    1042             : }
    1043             : 
    1044           0 : void ROVisIteratorImpl::selectChannel(const Vector<Vector<Slice> >& chansel) {
    1045             :   //  cout << "selectChannel!...vss..." << flush;
    1046             : 
    1047           0 :   if (chansel.nelements() != uInt(numberSpw()))
    1048           0 :     throw(AipsError("Specified channel slices has incorrect number of spws."));
    1049             :   
    1050           0 :   chanSlices_p.resize(numberSpw(),false);
    1051           0 :   chanSlices_p=chansel;
    1052             : 
    1053             :   // Enforce use of the new slicer downstream
    1054           0 :   useNewSlicer_p=true;
    1055             :     
    1056             :   //  cout << "done." << endl;
    1057             : 
    1058           0 : }
    1059             : 
    1060           0 : void ROVisIteratorImpl::selectCorrelation(const Vector<Vector<Slice> >& corrsel) {
    1061             : 
    1062             :   //  cout << "selectCorrelation!...vvs..." << flush;
    1063             : 
    1064           0 :   if (corrsel.nelements() != uInt(numberPol()))
    1065           0 :     throw(AipsError("Specified correlation slices has incorrect number of polIds."));
    1066             :   
    1067           0 :   corrSlices_p.resize(numberPol(),false);
    1068           0 :   corrSlices_p=corrsel;
    1069             : 
    1070             :   // Enforce use of the new slicer downstream
    1071           0 :   useNewSlicer_p=true;
    1072             :     
    1073             :   //  cout << "done." << endl;
    1074             : 
    1075           0 : }
    1076             : 
    1077           0 : Vector<Matrix<Int> >& ROVisIteratorImpl::setChanAveBounds(Float factor,
    1078             :                                                       Vector<Matrix<Int> >& bounds)
    1079             : {
    1080           0 :   if(!useNewSlicer_p)
    1081           0 :     throw(AipsError("Help!"));
    1082             : 
    1083             :   // For every spw...
    1084           0 :   bounds.resize(numberSpw());
    1085             : 
    1086             :   // If factor greater than zero, fill the bounds non-trivially
    1087           0 :   if (factor > 0) {
    1088             :  
    1089             :     // Decipher averaging factor
    1090           0 :     Int width = 1;
    1091           0 :     if(factor > 1.0)
    1092           0 :       width = Int(factor); // factor supplied in channel units
    1093             :  
    1094             :     // Calculate bounds for each spw
    1095           0 :     for(Int ispw = 0; ispw < numberSpw(); ++ispw){
    1096             :    
    1097             :       // Number of SELECTED channels PRIOR to averaging
    1098           0 :       Int nChan0 = numberChan(ispw);
    1099             :    
    1100             :       // factor might have been supplied as a fraction;
    1101             :       //  width is then potentially spw-dependent
    1102           0 :       if(factor <= 1.0)
    1103           0 :         width = Int(factor * Float(nChan0));
    1104             :    
    1105             :       // Get the selected channel list
    1106           0 :       Vector<Int> chans;
    1107           0 :       chanIds(chans, ispw);
    1108             : 
    1109             :       // The nominal number of output channels depends on the full
    1110             :       // range of channels selected (not the number of them)
    1111             :       //  (will be revised later, if nec.)
    1112           0 :       Int nChanOut0 = 1 + (chans[nChan0 - 1] - chans[0]) / width;
    1113             :    
    1114             :       // Initialize the bounds container for this spw
    1115           0 :       Matrix<Int>& currBounds(bounds[ispw]);
    1116           0 :       currBounds.resize(nChanOut0, 4);
    1117             :       //currBounds.set(0);
    1118             :    
    1119           0 :       Int outChan = 0;
    1120           0 :       Int firstchan = chans[0];
    1121           0 :       Int lastchan = chans[nChan0 - 1];
    1122             : 
    1123             :       // Index of input channel in SELECTED list, i.e.
    1124             :       // ich = vi.chanIds(chanids, spw)[selchanind].
    1125           0 :       uInt selchanind = 0;
    1126             : 
    1127           0 :       for(Int ich = firstchan; ich <= lastchan; ich += width){
    1128           0 :         Int w = width;
    1129             : 
    1130             :         // Use a clamped width in case (lastchan - firstchan + 1) % width != 0.
    1131           0 :         if(ich + w - 1 > lastchan)
    1132           0 :           w = lastchan + 1 - ich;
    1133             : 
    1134             :         // The start and end in MS channel #s.
    1135           0 :         currBounds(outChan, 0) = ich;
    1136           0 :         currBounds(outChan, 1) = ich + w - 1;
    1137             : 
    1138             :         // The start and end in selected reckoning.
    1139           0 :         currBounds(outChan, 2) = selchanind;
    1140           0 :         selchanind += w;
    1141           0 :         currBounds(outChan, 3) = selchanind - 1;
    1142             : 
    1143             :         // for(uInt ii = 0; ii < 4; ++ii)
    1144             :         //   cerr << "currBounds(" << outChan << ", " << ii << ") = "
    1145             :         //        << currBounds(outChan, ii) << endl;
    1146           0 :         ++outChan;
    1147             :       }
    1148           0 :     } // ispw
    1149             : 
    1150             :   } // factor > 0
    1151             : 
    1152             :   // Internal reference  (needed?)
    1153           0 :   chanAveBounds_p.reference(bounds);
    1154             : 
    1155             :   // Return the bounds Vector reference
    1156           0 :   return bounds;
    1157             : }
    1158             : 
    1159             : // Vector<Matrix<Int> >& ROVisIteratorImpl::setChanAveBounds(Float factor,
    1160             : //                                                    Vector<Matrix<Int> >& bounds) {
    1161             : 
    1162             : //   if (!useNewSlicer_p) throw(AipsError("Help!"));
    1163             : 
    1164             : //   // For every spw...
    1165             : //   bounds.resize(numberSpw());
    1166             : 
    1167             : //   // If factor greater than zero, fill the bounds non-trivially
    1168             : //   if (factor>0) {
    1169             :     
    1170             : //     // Decipher averaging factor
    1171             : //     Int width(1);
    1172             : //     if (factor>1.0) width=Int(factor); // factor supplied in channel units
    1173             :     
    1174             : //     // Calculate bounds for each spw
    1175             : //     for (Int ispw=0;ispw<numberSpw();++ispw) {
    1176             :       
    1177             : //       // Number of SELECTED channels PRIOR to averaging
    1178             : //       Int nChan0=numberChan(ispw);
    1179             :       
    1180             : //       // factor might have been supplied in factional units;
    1181             : //       //  width is then potentially spw-dependent
    1182             : //       if (factor<=1.0)
    1183             : //      width=Int(factor*Float(nChan0));
    1184             :       
    1185             : //       // Get the selected channel list
    1186             : //       Vector<Int> chans;
    1187             : //       chanIds(chans,ispw);
    1188             : 
    1189             : //       // The nominal number of output channels depends on the full
    1190             : //       // range of channels selected (not the number of them)
    1191             : //       //  (will be revised later, if nec.)
    1192             : //       Int nChanOut0((chans(nChan0-1)-chans(0)+1+width)/width);
    1193             :       
    1194             : //       // Initialize the bounds container for this spw
    1195             : //       Matrix<Int>& currBounds(bounds(ispw));
    1196             : //       currBounds.resize(nChanOut0,4);
    1197             : //       currBounds.set(0);
    1198             :       
    1199             : //       // Actual output channel count; initialization
    1200             : //       Int nChanOut=1;
    1201             : //       Int lo(chans(0));
    1202             : //       currBounds(0,0)=lo;
    1203             : //       currBounds(0,2)=0;
    1204             : //       for (Int ich=0;ich<nChan0;++ich) 
    1205             : //      if ( (chans(ich)-lo+1)>width ) {
    1206             : //        currBounds(nChanOut-1,1)=chans(ich-1);   // end of previous
    1207             : //        currBounds(nChanOut-1,3)=ich-1;
    1208             : //        lo=currBounds(nChanOut,0)=chans(ich);    // start of next
    1209             : //        currBounds(nChanOut,2)=ich;    // start of next
    1210             : //        ++nChanOut;
    1211             : //      }
    1212             : //       currBounds(nChanOut-1,1)=chans(nChan0-1);    // end of final set
    1213             : //       currBounds(nChanOut-1,3)=(nChan0-1);    // end of final set
    1214             :       
    1215             : // //       for(uInt ii = 0; ii < 4; ++ii)
    1216             : // //         cerr << "currBounds(" << nChanOut - 1 << ", " << ii << ") = "
    1217             : // //              << currBounds(nChanOut - 1, ii) << endl;
    1218             : 
    1219             : //       // contract bounds container, if necessary
    1220             : //       if (nChanOut<nChanOut0)
    1221             : //      currBounds.resize(nChanOut,4,true);
    1222             :       
    1223             : //     } // ispw
    1224             : 
    1225             : 
    1226             : //   } // factor > 0
    1227             : 
    1228             : //   // Internal reference  (needed?)
    1229             : //   chanAveBounds_p.reference(bounds);
    1230             : 
    1231             : //   // Return the bounds Vector reference
    1232             : //   return bounds;
    1233             : 
    1234             : // }
    1235             : 
    1236           0 : Int ROVisIteratorImpl::numberChan(Int spw) const {
    1237             : 
    1238             :   // Nominally all channels this spw
    1239           0 :   Int nchan=msColumns().spectralWindow().numChan()(spw);
    1240             : 
    1241           0 :   if (useNewSlicer_p) {
    1242           0 :     Int nslices=chanSlices_p(spw).nelements();
    1243           0 :     if (nslices > 0 ) {
    1244           0 :       nchan=0;
    1245           0 :       for (Int isl=0;isl<nslices;++isl) 
    1246           0 :         nchan+=chanSlices_p(spw)(isl).length();
    1247             :     }
    1248             :   }
    1249             : 
    1250           0 :   return nchan;
    1251             : 
    1252             : }
    1253             : 
    1254             : 
    1255           0 : Int ROVisIteratorImpl::numberCorr(Int pol) const {
    1256             : 
    1257             :   // Nominally all correlations this pol
    1258           0 :   Int ncorr=msColumns().polarization().numCorr()(pol);
    1259             : 
    1260           0 :   if (useNewSlicer_p) {
    1261           0 :     Int nslices=corrSlices_p(pol).nelements();
    1262           0 :     if (nslices > 0 ) {
    1263             :       // Accumulate from slice lengths
    1264           0 :       ncorr=0;
    1265           0 :       for (Int isl=0;isl<nslices;++isl) 
    1266           0 :         ncorr+=corrSlices_p(pol)(isl).length();
    1267             :     }
    1268             :   }
    1269             : 
    1270           0 :   return ncorr;
    1271             : 
    1272             : }
    1273             : 
    1274           0 : void ROVisIteratorImpl::getCol(const ScalarColumn<Bool> &column, Vector<Bool> &array, Bool resize) const
    1275             : {
    1276           0 :     column.getColumn(array, resize);
    1277           0 : }
    1278             : 
    1279           0 : void ROVisIteratorImpl::getCol(const ScalarColumn<Int> &column, Vector<Int> &array, Bool resize) const
    1280             : {
    1281           0 :     column.getColumn(array, resize);
    1282           0 : }
    1283             : 
    1284           0 : void ROVisIteratorImpl::getCol(const ScalarColumn<Double> &column, Vector<Double> &array, Bool resize) const
    1285             : {
    1286           0 :     column.getColumn(array, resize);
    1287           0 : }
    1288             : 
    1289           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Bool> &column, Array<Bool> &array, Bool resize) const
    1290             : {
    1291           0 :     column.getColumn(array, resize);
    1292           0 : }
    1293             : 
    1294           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Float> &column, Array<Float> &array, Bool resize) const
    1295             : {
    1296           0 :     column.getColumn(array, resize);
    1297           0 : }
    1298             : 
    1299           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Double> &column, Array<Double> &array, Bool resize) const
    1300             : {
    1301           0 :     column.getColumn(array, resize);
    1302           0 : }
    1303             : 
    1304           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Complex> &column, Array<Complex> &array, Bool resize) const
    1305             : {
    1306           0 :     column.getColumn(array, resize);
    1307           0 : }
    1308             : 
    1309           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Bool> &column, const Slicer &slicer, Array<Bool> &array, Bool resize) const
    1310             : {
    1311           0 :     column.getColumn(slicer, array, resize);
    1312           0 : }
    1313             : 
    1314           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Float> &column, const Slicer &slicer, Array<Float> &array, Bool resize) const
    1315             : {
    1316           0 :     column.getColumn(slicer, array, resize);
    1317           0 : }
    1318             : 
    1319           0 : void ROVisIteratorImpl::getCol(const ArrayColumn<Complex> &column, const Slicer &slicer, Array<Complex> &array, Bool resize) const
    1320             : {
    1321           0 :     column.getColumn(slicer, array, resize);
    1322           0 : }
    1323             : 
    1324             : 
    1325             : Vector<RigidVector<Double,3> >& 
    1326           0 : ROVisIteratorImpl::uvw(Vector<RigidVector<Double,3> >& uvwvec) const
    1327             : {
    1328           0 :     uvwvec.resize(curNumRow_p);
    1329           0 :     getCol(columns_p.uvw_p, cache_p.uvwMat_p,true);
    1330             :     // get a pointer to the raw storage for quick access
    1331             :     Bool deleteIt;
    1332           0 :     Double* pmat = cache_p.uvwMat_p.getStorage(deleteIt);
    1333           0 :     for (uInt row=0; row<curNumRow_p; row++, pmat+=3) uvwvec(row)=pmat;
    1334           0 :     return uvwvec;
    1335             : }
    1336             : 
    1337             : 
    1338             : const Table
    1339           0 : ROVisIteratorImpl::attachTable() const
    1340             : {
    1341           0 :     return selTable_p;
    1342             : }
    1343             : 
    1344             : //     ******************
    1345             : //     ******************
    1346             : //     **              **
    1347             : //     **  VisIterator **
    1348             : //     **              **
    1349             : //     ******************
    1350             : //     ******************
    1351             : 
    1352             : 
    1353           0 : VisIterator::VisIterator() {}
    1354             : 
    1355           0 : VisIterator::VisIterator(MeasurementSet &MS, 
    1356             :                          const Block<Int>& sortColumns, 
    1357           0 :                          Double timeInterval)
    1358           0 :   : ROVisIterator (MS, sortColumns, timeInterval, Factory (this))
    1359           0 : {}
    1360             : 
    1361           0 : VisIterator::VisIterator(const VisIterator & other)
    1362           0 : : ROVisIterator (other)
    1363             : {
    1364           0 :     operator=(other);
    1365           0 : }
    1366             : 
    1367           0 : VisIterator::~VisIterator() {}
    1368             : 
    1369             : VisIterator& 
    1370           0 : VisIterator::operator=(const VisIterator& other)
    1371             : {
    1372           0 :     if (this!=&other) {
    1373             : 
    1374           0 :         ROVisIterator::operator= (other);
    1375             :     }
    1376             : 
    1377           0 :         return * this;
    1378             : }
    1379             : 
    1380             : VisIterator &
    1381           0 : VisIterator::operator++(int)
    1382             : {
    1383           0 :   advance();
    1384             : 
    1385           0 :   return *this;
    1386             : }
    1387             : 
    1388             : VisIterator &
    1389           0 : VisIterator::operator++()
    1390             : {
    1391           0 :   advance();
    1392             : 
    1393           0 :   return *this;
    1394             : }
    1395             : 
    1396             : void
    1397           0 : VisIterator::attachColumns(const Table &table)
    1398             : {
    1399           0 :     getImpl() -> attachColumns (table);
    1400           0 : }
    1401             : 
    1402             : VisIteratorImpl *
    1403           0 : VisIterator::getImpl () const
    1404             : {
    1405           0 :     VisIteratorImpl * impl = dynamic_cast<VisIteratorImpl *> (ROVisibilityIterator::getReadImpl ());
    1406             : 
    1407           0 :     Assert (impl != NULL);
    1408             : 
    1409           0 :     return impl;
    1410             : }
    1411             : 
    1412           0 : void VisIterator::setFlagRow(const Vector<Bool>& rowflags)
    1413             : {
    1414           0 :     getImpl() -> setFlagRow (rowflags);
    1415           0 : };
    1416             : 
    1417           0 : void VisIterator::setVis(const Cube<Complex>& vis, DataColumn whichOne)
    1418             : {
    1419           0 :     getImpl () -> setVis (vis, whichOne);
    1420           0 : }
    1421             : 
    1422           0 : void VisIterator::setFlag(const Cube<Bool>& flags)
    1423             : {
    1424           0 :     getImpl () -> setFlag (flags);
    1425           0 : }
    1426             : 
    1427           0 : void VisIterator::setVisAndFlag(const Cube<Complex>& vis,
    1428             :                                        const Cube<Bool>& flag,
    1429             :                                        DataColumn whichOne)
    1430             : {
    1431           0 :     getImpl () -> setVisAndFlag (vis, flag, whichOne);
    1432           0 : }
    1433             : 
    1434           0 : void VisIterator::setWeightMat(const Matrix<Float>& weightMat)
    1435             : {
    1436           0 :     getImpl () -> setWeightMat (weightMat);
    1437           0 : }
    1438             : 
    1439           0 : void VisIterator::setWeightSpectrum(const Cube<Float>& weightSpectrum)
    1440             : {
    1441           0 :     getImpl () -> setWeightSpectrum (weightSpectrum);
    1442           0 : }
    1443             : 
    1444           0 : void VisIterator::putDataColumn(DataColumn whichOne,
    1445             :                                 const Vector<Vector<Slice> >& slices,
    1446             :                                 const Cube<Complex>& data)
    1447             : {
    1448           0 :     getImpl () -> putDataColumn (whichOne, slices, data);
    1449           0 : };  
    1450             : 
    1451           0 : void VisIterator::putDataColumn(DataColumn whichOne,
    1452             :                                 const Cube<Complex>& data)
    1453             : {
    1454           0 :     getImpl () -> putDataColumn (whichOne, data);
    1455           0 : };  
    1456             : 
    1457           0 : Vector<rownr_t>& ROVisIteratorImpl::rowIds(Vector<rownr_t>& rowids) const
    1458             : {
    1459           0 :   rowids.resize(curNumRow_p);
    1460           0 :   rowids=selTable_p.rowNumbers();
    1461           0 :   return rowids;
    1462             : }
    1463             : 
    1464             : 
    1465           0 : void VisIterator::putCol(ScalarColumn<Bool> &column, const Vector<Bool> &array)
    1466             : {
    1467           0 :     column.putColumn(array);
    1468           0 : }
    1469             : 
    1470           0 : void VisIterator::putCol(ArrayColumn<Bool> &column, const Array<Bool> &array)
    1471             : {
    1472           0 :     column.putColumn(array);
    1473           0 : }
    1474             : 
    1475           0 : void VisIterator::putCol(ArrayColumn<Float> &column, const Array<Float> &array)
    1476             : {
    1477           0 :     column.putColumn(array);
    1478           0 : }
    1479             : 
    1480           0 : void VisIterator::putCol(ArrayColumn<Complex> &column, const Array<Complex> &array)
    1481             : {
    1482           0 :     column.putColumn(array);
    1483           0 : }
    1484             : 
    1485           0 : void VisIterator::putCol(ArrayColumn<Bool> &column, const Slicer &slicer, const Array<Bool> &array)
    1486             : {
    1487           0 :     column.putColumn(slicer, array);
    1488           0 : }
    1489             : 
    1490           0 : void VisIterator::putCol(ArrayColumn<Float> &column, const Slicer &slicer, const Array<Float> &array)
    1491             : {
    1492           0 :     column.putColumn(slicer, array);
    1493           0 : }
    1494             : 
    1495           0 : void VisIterator::putCol(ArrayColumn<Complex> &column, const Slicer &slicer, const Array<Complex> &array)
    1496             : {
    1497           0 :     column.putColumn(slicer, array);
    1498           0 : }
    1499             : 
    1500             : VisibilityIteratorReadImpl *
    1501           0 : VisIterator::Factory::operator() (const asyncio::PrefetchColumns * /*prefetchColumns*/,
    1502             :                                   const Block<MeasurementSet>& mss,
    1503             :                                   const Block<Int>& sortColumns,
    1504             :                                   const Bool /*addDefaultSortCols*/,
    1505             :                                   Double timeInterval) const
    1506             : {
    1507           0 :     return new VisIteratorImpl (vi_p, mss[0], sortColumns, timeInterval);
    1508             : }
    1509             : 
    1510             : //     ***********************
    1511             : //     ***********************
    1512             : //     **                   **
    1513             : //     **  VisIteratorImpl  **
    1514             : //     **                   **
    1515             : //     ***********************
    1516             : //     ***********************
    1517             : 
    1518           0 : VisIteratorImpl::VisIteratorImpl(ROVisIterator * rovi,
    1519             :                                  const MeasurementSet& ms,
    1520             :                                  const Block<Int>& sortColumns,
    1521           0 :                                  Double timeInterval)
    1522           0 : : ROVisIteratorImpl (rovi, ms, sortColumns, timeInterval)
    1523             : {
    1524           0 : }
    1525             : 
    1526           0 : VisIteratorImpl::~VisIteratorImpl()
    1527           0 : {}
    1528             : 
    1529             : VisIteratorImpl &
    1530           0 : VisIteratorImpl::operator=(const VisIteratorImpl &other){
    1531             : 
    1532           0 :     if (this != & other){
    1533             : 
    1534           0 :         ROVisIteratorImpl::operator=(other);
    1535             : 
    1536           0 :         rwColFlag_p.reference(other.rwColFlag_p);
    1537           0 :         rwColFlagRow_p.reference(other.rwColFlagRow_p);
    1538           0 :         rwColVis_p.reference(other.rwColVis_p);
    1539           0 :         rwColFloatVis_p.reference(other.rwColFloatVis_p);
    1540           0 :         rwColModelVis_p.reference(other.rwColModelVis_p);
    1541           0 :         rwColCorrVis_p.reference(other.rwColCorrVis_p);
    1542           0 :         rwColWeight_p.reference(other.rwColWeight_p);
    1543           0 :         rwColWeightSpectrum_p.reference(other.rwColWeightSpectrum_p);
    1544           0 :         rwColSigma_p.reference(other.rwColSigma_p);
    1545             : 
    1546             :     }
    1547             : 
    1548           0 :     return * this;
    1549             : }
    1550             : 
    1551             : 
    1552             : void
    1553           0 : VisIteratorImpl::attachColumns(const Table &table)
    1554             : {
    1555             : 
    1556           0 :     ROVisIteratorImpl::attachColumns(table);
    1557             : 
    1558           0 :     const ColumnDescSet& cds = table.tableDesc().columnDescSet();
    1559             : 
    1560           0 :     if (cds.isDefined("CORRECTED_DATA")){
    1561           0 :         rwColCorrVis_p.attach(table,"CORRECTED_DATA");
    1562             :     }
    1563             : 
    1564           0 :     if (cds.isDefined(MS::columnName(MS::DATA))) {
    1565           0 :         rwColVis_p.attach(table,MS::columnName(MS::DATA));
    1566             :     }
    1567             : 
    1568           0 :     rwColFlag_p.attach(table,MS::columnName(MS::FLAG));
    1569             : 
    1570           0 :     rwColFlagRow_p.attach(table,MS::columnName(MS::FLAG_ROW));
    1571             : 
    1572           0 :     if (cds.isDefined(MS::columnName(MS::FLOAT_DATA))) {
    1573           0 :         floatDataFound_p=true;
    1574           0 :         rwColFloatVis_p.attach(table,MS::columnName(MS::FLOAT_DATA));
    1575             :     }
    1576             :     else {
    1577           0 :         floatDataFound_p=false;
    1578             :     }
    1579             : 
    1580           0 :     if (cds.isDefined("MODEL_DATA")){
    1581           0 :         rwColModelVis_p.attach(table,"MODEL_DATA");
    1582             :     }
    1583             : 
    1584           0 :     rwColSigma_p.attach(table,MS::columnName(MS::SIGMA));
    1585             : 
    1586           0 :     rwColWeight_p.attach(table,MS::columnName(MS::WEIGHT));
    1587             : 
    1588           0 :     if (cds.isDefined("WEIGHT_SPECTRUM")){
    1589           0 :         rwColWeightSpectrum_p.attach(table,"WEIGHT_SPECTRUM");
    1590             :     }
    1591           0 : }
    1592             : void
    1593           0 : VisIteratorImpl::putDataColumn(DataColumn whichOne,
    1594             :                                const Vector<Vector<Slice> >& slices,
    1595             :                                const Cube<Complex>& data)
    1596             : {
    1597             :     // Set the visibility (observed, model or corrected);
    1598             :     // deal with DATA and FLOAT_DATA seamlessly for observed data.
    1599             : 
    1600           0 :     switch (whichOne) {
    1601             : 
    1602           0 :     case VisibilityIterator::Observed:
    1603             : 
    1604           0 :         if (floatDataFound_p) {
    1605           0 :             Cube<Float> dataFloat=real(data);
    1606           0 :             rwColFloatVis_p.putColumn(slices,dataFloat);
    1607           0 :         } else {
    1608           0 :             rwColVis_p.putColumn(slices,data);
    1609             :         };
    1610           0 :         break;
    1611             : 
    1612           0 :     case VisibilityIterator::Corrected:
    1613             : 
    1614           0 :         rwColCorrVis_p.putColumn(slices,data);
    1615           0 :         break;
    1616             : 
    1617           0 :     case VisibilityIterator::Model:
    1618             : 
    1619           0 :         rwColModelVis_p.putColumn(slices,data);
    1620           0 :         break;
    1621             :     };
    1622           0 : };
    1623             : 
    1624             : void
    1625           0 : VisIteratorImpl::putDataColumn(DataColumn whichOne,
    1626             :                                const Cube<Complex>& data)
    1627             : {
    1628             :     // Set the visibility (observed, model or corrected);
    1629             :     // deal with DATA and FLOAT_DATA seamlessly for observed data.
    1630             : 
    1631           0 :     switch (whichOne) {
    1632             : 
    1633           0 :     case VisibilityIterator::Observed:
    1634             : 
    1635           0 :         if (floatDataFound_p) {
    1636           0 :             Cube<Float> dataFloat=real(data);
    1637           0 :             rwColFloatVis_p.putColumn(dataFloat);
    1638           0 :         } else {
    1639           0 :             rwColVis_p.putColumn(data);
    1640             :         };
    1641           0 :         break;
    1642             : 
    1643           0 :     case VisibilityIterator::Corrected:
    1644             : 
    1645           0 :         rwColCorrVis_p.putColumn(data);
    1646           0 :         break;
    1647             : 
    1648           0 :     case VisibilityIterator::Model:
    1649             : 
    1650           0 :         rwColModelVis_p.putColumn(data);
    1651           0 :         break;
    1652             :     };
    1653           0 : };
    1654             : 
    1655             : 
    1656             : void
    1657           0 : VisIteratorImpl::setFlag(const Cube<Bool>& flags)
    1658             : {
    1659           0 :     if (useNewSlicer_p){
    1660           0 :         rwColFlag_p.putColumn (newSlicer_p, flags);
    1661             :     }
    1662             :     else{
    1663           0 :         rwColFlag_p.putColumn(flags);
    1664             :     }
    1665           0 : }
    1666             : 
    1667             : void
    1668           0 : VisIteratorImpl::setFlagRow(const Vector<Bool>& rowflags)
    1669             : {
    1670           0 :     rwColFlagRow_p.putColumn(rowflags);
    1671           0 : };
    1672             : 
    1673             : void
    1674           0 : VisIteratorImpl::setVis(const Cube<Complex>& vis, DataColumn whichOne)
    1675             : {
    1676             : 
    1677           0 :     if (useNewSlicer_p){
    1678           0 :         putDataColumn (whichOne, newSlicer_p, vis);
    1679             :     }
    1680             :     else {
    1681           0 :         putDataColumn (whichOne, vis);
    1682             :     }
    1683             : 
    1684           0 : }
    1685             : 
    1686             : void
    1687           0 : VisIteratorImpl::setVisAndFlag(const Cube<Complex>& vis,
    1688             :                                const Cube<Bool>& flag,
    1689             :                                DataColumn whichOne)
    1690             : {
    1691           0 :     this->setFlag(flag);
    1692           0 :     this->setVis(vis,whichOne);
    1693           0 : }
    1694             : 
    1695             : void
    1696           0 : VisIteratorImpl::setWeightMat(const Matrix<Float>& weightMat)
    1697             : {
    1698           0 :     if (useNewSlicer_p){
    1699           0 :         rwColWeight_p.putColumn (newWtSlicer_p, weightMat);
    1700             :     }
    1701             :     else{
    1702           0 :         rwColWeight_p.putColumn (weightMat);
    1703             :     }
    1704           0 : }
    1705             : 
    1706             : void
    1707           0 : VisIteratorImpl::setWeightSpectrum(const Cube<Float>& weightSpectrum)
    1708             : {
    1709           0 :     if (existsWeightSpectrum()) {
    1710             : 
    1711           0 :         if (useNewSlicer_p){
    1712           0 :             rwColWeightSpectrum_p.putColumn(newSlicer_p,weightSpectrum);
    1713             :         }
    1714             :         else{
    1715           0 :             rwColWeightSpectrum_p.putColumn(weightSpectrum);
    1716             :         }
    1717             :     }
    1718             :     else {
    1719           0 :         throw(AipsError("Can't set WEIGHT_SPECTRUM -- it doesn't exist!"));
    1720             :     }
    1721           0 : }
    1722             : 
    1723             : } //# NAMESPACE CASA - END
    1724             : 

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