LCOV - code coverage report
Current view: top level - synthesis/TransformMachines2 - WProjectFT.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 378 695 54.4 %
Date: 2024-10-28 15:53:10 Functions: 11 29 37.9 %

          Line data    Source code
       1             : //# WProjectFT.cc: Implementation of WProjectFT class
       2             : //# Copyright (C) 2003-2016
       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 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 General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU 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             : //# $Id$
      27             : 
      28             : #include <msvis/MSVis/VisibilityIterator2.h>
      29             : #include <casacore/casa/Quanta/UnitMap.h>
      30             : #include <casacore/casa/Quanta/MVTime.h>
      31             : #include <casacore/casa/Quanta/UnitVal.h>
      32             : #include <casacore/casa/Utilities/CountedPtr.h>
      33             : #include <casacore/measures/Measures/Stokes.h>
      34             : #include <casacore/coordinates/Coordinates/CoordinateSystem.h>
      35             : #include <casacore/coordinates/Coordinates/DirectionCoordinate.h>
      36             : #include <casacore/coordinates/Coordinates/SpectralCoordinate.h>
      37             : #include <casacore/coordinates/Coordinates/StokesCoordinate.h>
      38             : #include <casacore/coordinates/Coordinates/Projection.h>
      39             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      40             : #include <casacore/casa/BasicSL/Constants.h>
      41             : #include <casacore/scimath/Mathematics/FFTServer.h>
      42             : #include <synthesis/TransformMachines2/WProjectFT.h>
      43             : #include <synthesis/TransformMachines2/WPConvFunc.h>
      44             : #include <casacore/scimath/Mathematics/RigidVector.h>
      45             : #include <msvis/MSVis/StokesVector.h>
      46             : #include <synthesis/TransformMachines/StokesImageUtil.h>
      47             : #include <casacore/images/Images/ImageInterface.h>
      48             : #include <casacore/images/Images/PagedImage.h>
      49             : #include <casacore/casa/Containers/Block.h>
      50             : #include <casacore/casa/Containers/Record.h>
      51             : #include <casacore/casa/Arrays/ArrayLogical.h>
      52             : #include <casacore/casa/Arrays/ArrayMath.h>
      53             : #include <casacore/casa/Arrays/Array.h>
      54             : #include <casacore/casa/Arrays/MaskedArray.h>
      55             : #include <casacore/casa/Arrays/Vector.h>
      56             : #include <casacore/casa/Arrays/Slice.h>
      57             : #include <casacore/casa/Arrays/Matrix.h>
      58             : #include <casacore/casa/Arrays/Cube.h>
      59             : #include <casacore/casa/Arrays/MatrixIter.h>
      60             : #include <casacore/casa/BasicSL/String.h>
      61             : #include <casacore/casa/Utilities/Assert.h>
      62             : #include <casacore/casa/Exceptions/Error.h>
      63             : #include <iostream>
      64             : #include <iomanip>
      65             : #include <casacore/lattices/Lattices/ArrayLattice.h>
      66             : #include <casacore/lattices/Lattices/SubLattice.h>
      67             : #include <casacore/lattices/LRegions/LCBox.h>
      68             : #include <casacore/lattices/LEL/LatticeExpr.h>
      69             : #include <casacore/lattices/Lattices/LatticeCache.h>
      70             : #include <casacore/lattices/LatticeMath/LatticeFFT.h>
      71             : #include <casacore/lattices/Lattices/LatticeIterator.h>
      72             : #include <casacore/lattices/Lattices/LatticeStepper.h>
      73             : #include <casacore/casa/Utilities/CompositeNumber.h>
      74             : #include <casacore/casa/OS/Timer.h>
      75             : #include <casacore/casa/OS/HostInfo.h>
      76             : #include <sstream>
      77             : #ifdef _OPENMP
      78             : #include <omp.h>
      79             : #endif
      80             : using namespace casacore;
      81             : namespace casa { //# NAMESPACE CASA - BEGIN
      82             : namespace refim { //#namespace for imaging refactoring
      83             : 
      84             : using namespace casacore;
      85             : using namespace casa;
      86             : using namespace casacore;
      87             : using namespace casa::vi;
      88             : using namespace casacore;
      89             : using namespace casa::refim;
      90             : 
      91           0 : WProjectFT::WProjectFT( Int nWPlanes, Long icachesize, Int itilesize, 
      92           0 :                         Bool usezero, Bool useDoublePrec, const Double minW, const Double maxW, const Double rmsW)
      93           0 :   : FTMachine(), padding_p(1.0), nWPlanes_p(nWPlanes),
      94           0 :     imageCache(0), cachesize(icachesize), tilesize(itilesize),
      95           0 :     gridder(0), isTiled(false), 
      96           0 :     maxAbsData(0.0), centerLoc(IPosition(4,0)), offsetLoc(IPosition(4,0)), usezero_p(usezero), 
      97           0 :     machineName_p("WProjectFT"), timemass_p(0.0), timegrid_p(0.0), timedegrid_p(0.0), minW_p(minW), maxW_p(maxW), rmsW_p(rmsW)
      98             : {
      99           0 :   convSize=0;
     100           0 :   tangentSpecified_p=false;
     101           0 :   lastIndex_p=0;
     102           0 :   useDoubleGrid_p=useDoublePrec;
     103           0 :   wpConvFunc_p=new WPConvFunc(minW, maxW, rmsW);
     104             : 
     105           0 : }
     106           1 : WProjectFT::WProjectFT(Int nWPlanes, 
     107             :                        MPosition mLocation, 
     108             :                        Long icachesize, Int itilesize, 
     109           1 :                        Bool usezero, Float padding, Bool useDoublePrec, const Double minW, const Double maxW, const Double rmsW)
     110           1 :   : FTMachine(), padding_p(padding), nWPlanes_p(nWPlanes),
     111           1 :     imageCache(0), cachesize(icachesize), tilesize(itilesize),
     112           1 :     gridder(0), isTiled(false),  
     113           1 :     maxAbsData(0.0), centerLoc(IPosition(4,0)), offsetLoc(IPosition(4,0)),
     114           1 :     usezero_p(usezero),  
     115           2 :     machineName_p("WProjectFT"), timemass_p(0.0), timegrid_p(0.0), timedegrid_p(0.0), minW_p(minW), maxW_p(maxW), rmsW_p(rmsW)
     116             : 
     117             : {
     118           1 :   convSize=0;
     119           1 :   savedWScale_p=0.0;
     120           1 :   tangentSpecified_p=false;
     121           1 :   mLocation_p=mLocation;
     122           1 :   lastIndex_p=0;
     123           1 :   wpConvFunc_p=new WPConvFunc(minW, maxW, rmsW);
     124           1 :   useDoubleGrid_p=useDoublePrec;
     125           1 : }
     126           0 : WProjectFT::WProjectFT(
     127             :                        Int nWPlanes, MDirection mTangent, 
     128             :                        MPosition mLocation, 
     129             :                        Long icachesize, Int itilesize, 
     130           0 :                        Bool usezero, Float padding, Bool useDoublePrec, const Double minW, const Double maxW, const Double rmsW)
     131           0 :   : FTMachine(), padding_p(padding), nWPlanes_p(nWPlanes),
     132           0 :     imageCache(0), cachesize(icachesize), tilesize(itilesize),
     133           0 :     gridder(0), isTiled(false),  
     134           0 :     maxAbsData(0.0), centerLoc(IPosition(4,0)), offsetLoc(IPosition(4,0)),
     135           0 :     usezero_p(usezero), 
     136           0 :     machineName_p("WProjectFT"), timemass_p(0.0), timegrid_p(0.0), timedegrid_p(0.0), minW_p(minW), maxW_p(maxW), rmsW_p(rmsW)
     137             : {
     138           0 :   convSize=0;
     139           0 :   savedWScale_p=0.0;
     140           0 :   mTangent_p=mTangent;
     141           0 :   tangentSpecified_p=true;
     142           0 :   mLocation_p=mLocation;
     143           0 :   lastIndex_p=0;
     144           0 :   wpConvFunc_p=new WPConvFunc(minW, maxW, rmsW);
     145           0 :   useDoubleGrid_p=useDoublePrec;
     146           0 : }
     147             : 
     148           0 : WProjectFT::WProjectFT(const RecordInterface& stateRec)
     149           0 :   : FTMachine(),machineName_p("WProjectFT"), timemass_p(0.0), timegrid_p(0.0), timedegrid_p(0.0)
     150             : {
     151             :   // Construct from the input state record
     152           0 :   String error;
     153           0 :   if (!fromRecord(error, stateRec)) {
     154           0 :     throw (AipsError("Failed to create WProjectFT: " + error));
     155             :   };
     156           0 : }
     157             : //---------------------------------------------------------------------- 
     158           0 : WProjectFT& WProjectFT::operator=(const WProjectFT& other)
     159             : {
     160           0 :   if(this!=&other) {
     161             :     //Do the base parameters
     162           0 :     FTMachine::operator=(other);
     163             :     
     164             :     
     165           0 :     padding_p=other.padding_p;
     166           0 :     nWPlanes_p=other.nWPlanes_p;
     167           0 :     imageCache=other.imageCache;
     168           0 :     cachesize=other.cachesize;
     169           0 :     tilesize=other.tilesize;
     170           0 :     if(other.gridder==0)
     171           0 :       gridder=0;
     172             :     else{
     173           0 :       uvScale.resize();
     174           0 :       uvOffset.resize();
     175           0 :       uvScale=other.uvScale;
     176           0 :       uvOffset=other.uvOffset;
     177           0 :       gridder = new ConvolveGridder<Double, Complex>(IPosition(2, nx, ny),
     178           0 :                                                      uvScale, uvOffset,
     179           0 :                                                      "SF");
     180             :     }
     181             : 
     182           0 :     isTiled=other.isTiled;
     183             :     //lattice=other.lattice;
     184             :     //arrayLattice=other.arrayLattice;
     185           0 :     lattice=0;
     186           0 :     arrayLattice=0;
     187             : 
     188           0 :     maxAbsData=other.maxAbsData;
     189           0 :     centerLoc=other.centerLoc;
     190           0 :     offsetLoc=other.offsetLoc;
     191           0 :     usezero_p=other.usezero_p;
     192           0 :     machineName_p=other.machineName_p;
     193           0 :     wpConvFunc_p=other.wpConvFunc_p;
     194           0 :     timemass_p=0.0;
     195           0 :     timegrid_p=0.0;
     196           0 :     timedegrid_p=0.0;
     197           0 :     minW_p=other.minW_p;
     198           0 :     maxW_p=other.maxW_p;
     199           0 :     rmsW_p=other.rmsW_p;
     200             :   };
     201           0 :   return *this;
     202             : };
     203             : 
     204             : //----------------------------------------------------------------------
     205           0 :   WProjectFT::WProjectFT(const WProjectFT& other) :FTMachine(), machineName_p("WProjectFT"),timemass_p(0.0), timegrid_p(0.0), timedegrid_p(0.0)
     206             : {
     207           0 :   operator=(other);
     208           0 : }
     209             : 
     210           0 : FTMachine* WProjectFT::cloneFTM(){
     211           0 :   return new WProjectFT(*this);
     212             : }
     213             : 
     214             : //----------------------------------------------------------------------
     215           2 : void WProjectFT::init() {
     216             :   /*  if((padding_p*padding_p*image->shape().product())>cachesize) {
     217             :     isTiled=true;
     218             :     nx    = image->shape()(0);
     219             :     ny    = image->shape()(1);
     220             :     npol  = image->shape()(2);
     221             :     nchan = image->shape()(3);
     222             :   }
     223             :   else {*/
     224             :     // We are padding.
     225           2 :     isTiled=false;
     226           2 :     CompositeNumber cn(uInt(image->shape()(0)*2));    
     227           2 :     nx    = cn.nextLargerEven(Int(padding_p*Float(image->shape()(0))-0.5));
     228           2 :     ny    = cn.nextLargerEven(Int(padding_p*Float(image->shape()(1))-0.5));   
     229           2 :     npol  = image->shape()(2);
     230           2 :     nchan = image->shape()(3);
     231             :     //}
     232             :   
     233             :   //  if(image->shape().product()>cachesize) {
     234             :   //   isTiled=true;
     235             :   // }
     236             :   // else {
     237             :   // isTiled=false;
     238             :   // }
     239             :   //The Tiled version need some fixing: sof or now
     240           2 :   isTiled=false;
     241             : 
     242             :  
     243           2 :   sumWeight.resize(npol, nchan);
     244             :   
     245           2 :   wConvSize=max(0, nWPlanes_p);
     246           2 :   convSupport.resize(wConvSize);
     247           2 :   convSupport=0;
     248             : 
     249           2 :   uvScale.resize(3);
     250           2 :   uvScale=0.0;
     251           2 :   uvScale(0)=Float(nx)*image->coordinates().increment()(0); 
     252           2 :   uvScale(1)=Float(ny)*image->coordinates().increment()(1); 
     253           2 :   if(savedWScale_p==0.0){
     254           1 :     uvScale(2)=Float(wConvSize)*abs(image->coordinates().increment()(0));
     255             :   }
     256             :   else{
     257           1 :     uvScale(2)=savedWScale_p;
     258             :   }
     259           2 :   uvOffset.resize(3);
     260           2 :   uvOffset(0)=nx/2;
     261           2 :   uvOffset(1)=ny/2;
     262           2 :   uvOffset(2)=0;
     263             :   
     264             :   
     265             : 
     266           2 :   if(gridder) delete gridder; gridder=0;
     267           4 :   gridder = new ConvolveGridder<Double, Complex>(IPosition(2, nx, ny),
     268           2 :                                                  uvScale, uvOffset,
     269           2 :                                                  "SF");
     270             : 
     271             :   // Set up image cache needed for gridding. 
     272           2 :   if(imageCache) delete imageCache; imageCache=0;
     273             :   
     274             :   // The tile size should be large enough that the
     275             :   // extended convolution function can fit easily
     276           2 :   if(isTiled) {
     277           0 :     Float tileOverlap=0.5;
     278           0 :     tilesize=min(256,tilesize);
     279           0 :     IPosition tileShape=IPosition(4,tilesize,tilesize,npol,nchan);
     280           0 :     Vector<Float> tileOverlapVec(4);
     281           0 :     tileOverlapVec=0.0;
     282           0 :     tileOverlapVec(0)=tileOverlap;
     283           0 :     tileOverlapVec(1)=tileOverlap;
     284           0 :     Int tmpCacheVal=static_cast<Int>(cachesize);
     285           0 :     imageCache=new LatticeCache <Complex> (*image, tmpCacheVal, tileShape, 
     286             :                                            tileOverlapVec,
     287           0 :                                            (tileOverlap>0.0));
     288             :     
     289           0 :   }
     290           2 : }
     291             : 
     292             : // This is nasty, we should use CountedPointers here.
     293           0 : WProjectFT::~WProjectFT() {
     294           0 :   if(imageCache) delete imageCache; imageCache=0;
     295           0 :   if(gridder) delete gridder; gridder=0;
     296             :   /*
     297             :   if(arrayLattice) delete arrayLattice; arrayLattice=0;
     298             :   
     299             :   Int numofmodels=convFunctions_p.nelements();
     300             :   for (Int k=0; k< numofmodels; ++k){
     301             :     delete convFunctions_p[k];
     302             :     delete convSupportBlock_p[k];
     303             : 
     304             :   }
     305             :   */
     306             :   // convFuctions_p.resize();
     307             :   //  convSupportBlock_p.resize();
     308             : 
     309           0 : }
     310             : 
     311             : 
     312           0 : void WProjectFT::setConvFunc(CountedPtr<WPConvFunc>& pbconvFunc){
     313             : 
     314           0 :   wpConvFunc_p=pbconvFunc;
     315           0 : }
     316           0 : CountedPtr<WPConvFunc>& WProjectFT::getConvFunc(){
     317             : 
     318           0 :   return wpConvFunc_p;
     319             : }
     320             : 
     321         202 : void WProjectFT::findConvFunction(const ImageInterface<Complex>& image,
     322             :                                 const VisBuffer2& vb) {
     323             :   
     324             : 
     325             : 
     326             : 
     327             : 
     328         202 :   wpConvFunc_p->findConvFunction(image, vb, wConvSize, uvScale, uvOffset,
     329         202 :                                  padding_p,
     330         202 :                                  convSampling, 
     331         202 :                                  convFunc, convSize, convSupport, 
     332         202 :                                  savedWScale_p); 
     333             : 
     334         202 :   nWPlanes_p=convSupport.nelements();
     335         202 :   wConvSize=max(1,nWPlanes_p);
     336         202 :   uvScale(2)=savedWScale_p;
     337             : 
     338             :   
     339             :   
     340         202 : }
     341             : 
     342           1 : void WProjectFT::initializeToVis(ImageInterface<Complex>& iimage,
     343             :                                const VisBuffer2& vb)
     344             : {
     345           1 :   image=&iimage;
     346           1 :   toVis_p=true;
     347           1 :   ok();
     348             :   
     349             :   //   if(convSize==0) {
     350           1 :   init();
     351             :   // }
     352           1 :   findConvFunction(*image, vb);
     353             : 
     354             :   
     355             :   // Initialize the maps for polarization and channel. These maps
     356             :   // translate visibility indices into image indices
     357           1 :   initMaps(vb);
     358             :   
     359             :   //  nx    = image->shape()(0);
     360             :   //  ny    = image->shape()(1);
     361             :   //  npol  = image->shape()(2);
     362             :   //  nchan = image->shape()(3);
     363             : 
     364             : 
     365           1 :   isTiled=false;
     366             :   // If we are memory-based then read the image in and create an
     367             :   // ArrayLattice otherwise just use the PagedImage
     368             :   /*if(isTiled) {
     369             :     lattice=CountedPtr<Lattice<Complex> > (image, false);
     370             :   }
     371             :   else {
     372             :    }
     373             :   */
     374             :   //AlwaysAssert(lattice, AipsError);
     375             :   
     376           1 :   prepGridForDegrid();
     377           1 : }
     378             : 
     379           1 : void WProjectFT::prepGridForDegrid(){
     380           1 :   IPosition gridShape(4, nx, ny, npol, nchan);
     381           1 :   griddedData.resize(gridShape);
     382           1 :   griddedData=Complex(0.0);
     383             :   
     384             : 
     385           1 :   IPosition stride(4, 1);
     386           2 :   IPosition blc(4, (nx-image->shape()(0)+(nx%2==0))/2,
     387           2 :                 (ny-image->shape()(1)+(ny%2==0))/2, 0, 0);
     388           2 :   IPosition trc(blc+image->shape()-stride);
     389             :   
     390           1 :   IPosition start(4, 0);
     391           1 :   griddedData(blc, trc) = image->getSlice(start, image->shape());
     392             :   
     393             :   //if(arrayLattice) delete arrayLattice; arrayLattice=0;
     394           1 :   arrayLattice = new ArrayLattice<Complex>(griddedData);
     395           1 :   lattice=arrayLattice;
     396             : 
     397           1 :   logIO() << LogIO::DEBUGGING << "Starting FFT of image" << LogIO::POST;
     398             :   
     399             :   
     400           1 : Vector<Float> sincConvX(nx);
     401         101 :   for (Int ix=0;ix<nx;ix++) {
     402         100 :     Float x=C::pi*Float(ix-nx/2)/(Float(nx)*Float(convSampling));
     403         100 :     if(ix==nx/2) {
     404           1 :       sincConvX(ix)=1.0;
     405             :     }
     406             :     else {
     407          99 :       sincConvX(ix)=sin(x)/x;
     408             :     }
     409             :   }
     410           1 :   Vector<Float> sincConvY(ny);
     411         101 :   for (Int ix=0;ix<ny;ix++) {
     412         100 :     Float x=C::pi*Float(ix-ny/2)/(Float(ny)*Float(convSampling));
     413         100 :     if(ix==ny/2) {
     414           1 :       sincConvY(ix)=1.0;
     415             :     }
     416             :     else {
     417          99 :       sincConvY(ix)=sin(x)/x;
     418             :     }
     419             :   }
     420             : 
     421           1 :   Vector<Complex> correction(nx);
     422           1 :   correction=Complex(1.0, 0.0);
     423             :   // Do the Grid-correction
     424           1 :   IPosition cursorShape(4, nx, 1, 1, 1);
     425           1 :   IPosition axisPath(4, 0, 1, 2, 3);
     426           1 :   LatticeStepper lsx(lattice->shape(), cursorShape, axisPath);
     427           1 :   LatticeIterator<Complex> lix(*lattice, lsx);
     428         101 :   for(lix.reset();!lix.atEnd();lix++) {
     429         100 :     Int iy=lix.position()(1);
     430         100 :     gridder->correctX1D(correction,iy);
     431       10100 :     for (Int ix=0;ix<nx;ix++) {
     432       10000 :       correction(ix)/=(sincConvX(ix)*sincConvY(iy));
     433             :     }
     434         100 :     lix.rwVectorCursor()/=correction;
     435             :   }
     436             :   
     437             :   // Now do the FFT2D in place
     438           1 :   LatticeFFT::cfft2d(*lattice);
     439             :   
     440           1 :   logIO() << LogIO::DEBUGGING << "Finished FFT" << LogIO::POST;
     441             : 
     442             : 
     443             : 
     444           1 : }
     445             : 
     446             : 
     447           0 : void WProjectFT::finalizeToVis()
     448             : {
     449           0 :   logIO() << LogOrigin("WProjectFT", "finalizeToVis")  << LogIO::NORMAL;
     450           0 :   logIO() <<LogIO::NORMAL2<< "Time to degrid " << timedegrid_p << LogIO::POST ;
     451           0 :   timedegrid_p=0.0;
     452           0 :   if(!arrayLattice.null()) arrayLattice=0;
     453           0 :   if(!lattice.null()) lattice=0;
     454           0 :   griddedData.resize();
     455           0 :   if(isTiled) {
     456             :     
     457             :    
     458             :     
     459           0 :     AlwaysAssert(imageCache, AipsError);
     460           0 :     AlwaysAssert(image, AipsError);
     461           0 :     ostringstream o;
     462           0 :     imageCache->flush();
     463           0 :     imageCache->showCacheStatistics(o);
     464           0 :     logIO() << o.str() << LogIO::POST;
     465           0 :   }
     466           0 : }
     467             : 
     468             : 
     469             : // Initialize the FFT to the Sky. Here we have to setup and initialize the
     470             : // grid. 
     471           1 : void WProjectFT::initializeToSky(ImageInterface<Complex>& iimage,
     472             :                                Matrix<Float>& weight,
     473             :                                const VisBuffer2& vb)
     474             : {
     475             :   // image always points to the image
     476           1 :   image=&iimage;
     477           1 :   toVis_p=false;
     478             :   
     479             :   //  if(convSize==0) {
     480           1 :   init();
     481             :   //  }
     482           1 :   findConvFunction(*image, vb);
     483             :   
     484             :   
     485             :   // Initialize the maps for polarization and channel. These maps
     486             :   // translate visibility indices into image indices
     487           1 :   initMaps(vb);
     488             :   
     489             :   //  nx    = image->shape()(0);
     490             :   //  ny    = image->shape()(1);
     491             :   //  npol  = image->shape()(2);
     492             :   //  nchan = image->shape()(3);
     493             : 
     494             :   //  if(image->shape().product()>cachesize) {
     495             :   //  isTiled=true;
     496             :   // }
     497             :   // else {
     498             :   //  isTiled=false;
     499             :   // }
     500           1 :   isTiled=false;
     501           1 :   sumWeight=0.0;
     502           1 :   weight.resize(sumWeight.shape());
     503           1 :   weight=0.0;
     504             :   
     505             :   // Initialize for in memory or to disk gridding. lattice will
     506             :   // point to the appropriate Lattice, either the ArrayLattice for
     507             :   // in memory gridding or to the image for to disk gridding.
     508           1 :   if(isTiled) {
     509           0 :     imageCache->flush();
     510           0 :     image->set(Complex(0.0));
     511           0 :     lattice=CountedPtr<Lattice<Complex> > (image, false);
     512             :   }
     513             :   else {
     514           1 :     IPosition gridShape(4, nx, ny, npol, nchan);
     515           1 :     if(!useDoubleGrid_p){
     516           1 :       griddedData.resize(gridShape);
     517           1 :       griddedData=Complex(0.0);
     518             :     }
     519             :     else{
     520             :       //griddedData.resize();
     521           0 :       griddedData2.resize(gridShape);
     522           0 :       griddedData2=DComplex(0.0);
     523             :     }
     524             :     //if(arrayLattice) delete arrayLattice; arrayLattice=0;
     525             :    
     526           1 :   }
     527             :   //AlwaysAssert(lattice, AipsError);
     528             :   
     529           1 : }
     530             : 
     531           1 : void WProjectFT::finalizeToSky()
     532             : {
     533           1 :   logIO() << LogOrigin("WProjectFT", "finalizeToSky")  << LogIO::NORMAL;
     534           1 :   logIO() <<LogIO::NORMAL2<< "Time to massage data " << timemass_p << LogIO::POST;
     535           1 :   logIO() << LogIO::NORMAL2 <<"Time to grid data " << timegrid_p << LogIO::POST;
     536           1 :   timemass_p=0.0;
     537           1 :   timegrid_p=0.0;
     538             :   // Now we flush the cache and report statistics
     539             :   // For memory based, we don't write anything out yet.
     540           1 :   if(isTiled) {
     541           0 :     logIO() << LogOrigin("WProjectFT", "finalizeToSky")  << LogIO::NORMAL;
     542             :     
     543           0 :     AlwaysAssert(image, AipsError);
     544           0 :     AlwaysAssert(imageCache, AipsError);
     545           0 :     imageCache->flush();
     546           0 :     ostringstream o;
     547           0 :     imageCache->showCacheStatistics(o);
     548           0 :     logIO() << o.str() << LogIO::POST;
     549           0 :   }
     550           1 : }
     551             : 
     552           0 : Array<Complex>* WProjectFT::getDataPointer(const IPosition& centerLoc2D,
     553             :                                          Bool readonly) {
     554             :   Array<Complex>* result;
     555             :   // Is tiled: get tiles and set up offsets
     556           0 :   centerLoc(0)=centerLoc2D(0);
     557           0 :   centerLoc(1)=centerLoc2D(1);
     558           0 :   result=&imageCache->tile(offsetLoc, centerLoc, readonly);
     559           0 :   gridder->setOffset(IPosition(2, offsetLoc(0), offsetLoc(1)));
     560           0 :   return result;
     561             : }
     562             : 
     563             : #define NEED_UNDERSCORES
     564             : #if defined(NEED_UNDERSCORES)
     565             : #define gwgrid gwgrid_
     566             : #define gwproj gwproj_
     567             : #define dwproj dwproj_
     568             : #define sectgwgridd sectgwgridd_
     569             : #define sectgwgrids sectgwgrids_
     570             : #define sectdwgrid sectdwgrid_
     571             : #define locuvw locuvw_
     572             : #endif
     573             : 
     574             : extern "C" { 
     575             :   void locuvw(const Double*, const Double*, const Double*, const Int*, const Double*, const Double*, const Int*, 
     576             :               Int*, Int*, Complex*, const Int*, const Int*, const Double*);
     577             :   //Double precision gridding
     578             :   void gwgrid(const Double*,
     579             :               Double*,
     580             :               const Complex*,
     581             :               Int*,
     582             :               Int*,
     583             :               Int*,
     584             :               const Int*,
     585             :               const Int*,
     586             :               const Float*,
     587             :               Int*,
     588             :               Int*,
     589             :               Double*,
     590             :               Double*,
     591             :               DComplex*,
     592             :               Int*,
     593             :               Int*,
     594             :               Int *,
     595             :               Int *,
     596             :               const Double*,
     597             :               const Double*,
     598             :               Int*,
     599             :               Int*,
     600             :               Int*,
     601             :               Int*,
     602             :               const Complex*,
     603             :               Int*,
     604             :               Int*,
     605             :               Double*);
     606             : 
     607             :   void sectgwgridd(const Double*,
     608             :                    const Complex*,
     609             :               const Int*,
     610             :               const Int*,
     611             :               const Int*,
     612             :               const Int*,
     613             :               const Int*,
     614             :               const Float*,
     615             :               const Int*,
     616             :               DComplex*,
     617             :               const Int*,
     618             :               const Int*,
     619             :               const Int *,
     620             :               const Int *,
     621             :                    //support
     622             :               const Int*,
     623             :               const Int*,
     624             :               const Int*,
     625             :               const Int*,
     626             :               const Complex*,
     627             :               const Int*,
     628             :               const Int*,
     629             :                    Double*,
     630             :                    //x0
     631             :                    const Int*,
     632             :                    const Int*,
     633             :                    const Int*, 
     634             :                    const Int*, 
     635             :                    const Int*, 
     636             :                    const Int*,
     637             :                    const Int*,
     638             :                    const Int*,
     639             :                    const Complex*
     640             :                    );
     641             : 
     642             :   //Single precision gridding
     643             :     void sectgwgrids(const Double*,
     644             :                    const Complex*,
     645             :               const Int*,
     646             :               const Int*,
     647             :               const Int*,
     648             :               const Int*,
     649             :               const Int*,
     650             :               const Float*,
     651             :               const Int*,
     652             :               Complex*,
     653             :               const Int*,
     654             :               const Int*,
     655             :               const Int *,
     656             :               const Int *,
     657             :                    //support
     658             :               const Int*,
     659             :               const Int*,
     660             :               const Int*,
     661             :               const Int*,
     662             :               const Complex*,
     663             :               const Int*,
     664             :               const Int*,
     665             :                    Double*,
     666             :                    //x0
     667             :                    const Int*,
     668             :                    const Int*,
     669             :                    const Int*, 
     670             :                    const Int*, 
     671             :                    const Int*, 
     672             :                    const Int*,
     673             :                    const Int*,
     674             :                    const Int*,
     675             :                    const Complex*
     676             :                    );
     677             : 
     678             : 
     679             :   void gwproj(const Double*,
     680             :               Double*,
     681             :               const Complex*,
     682             :               Int*,
     683             :               Int*,
     684             :               Int*,
     685             :               const Int*,
     686             :               const Int*,
     687             :               const Float*,
     688             :               Int*,
     689             :               Int*,
     690             :               Double*,
     691             :               Double*,
     692             :               Complex*,
     693             :               Int*,
     694             :               Int*,
     695             :               Int *,
     696             :               Int *,
     697             :               const Double*,
     698             :               const Double*,
     699             :               Int*,
     700             :               Int*,
     701             :               Int*,
     702             :               Int*,
     703             :               const Complex*,
     704             :               Int*,
     705             :               Int*,
     706             :               Double*);
     707             : 
     708             :   void sectdwgrid(const Double*,
     709             :                   Complex*,
     710             :                   const Int*,
     711             :                   const Int*,
     712             :                   const Int*,
     713             :                   const Int*,
     714             :                   const Int*,
     715             :                   const Complex*,
     716             :                   const Int*,
     717             :                   const Int*,
     718             :                   const Int *,
     719             :                   const Int *,
     720             :                   //support
     721             :                   const Int*,
     722             :                   const Int*,
     723             :                   const Int*,
     724             :                   const Int*,
     725             :                   const Complex*,
     726             :                   const Int*,
     727             :                   const Int*,
     728             :                   //rbeg, rend, loc, off, phasor
     729             :                   const Int*,
     730             :                   const Int*,
     731             :                   const Int*,
     732             :                   const Int*,
     733             :                   const Complex*);
     734             :   void dwproj(const Double*,
     735             :               Double*,
     736             :               Complex*,
     737             :               Int*,
     738             :               Int*,
     739             :               const Int*,
     740             :               const Int*,
     741             :               Int*,
     742             :               Int*,
     743             :               Double*,
     744             :               Double*,
     745             :               const Complex*,
     746             :               Int*,
     747             :               Int*,
     748             :               Int *,
     749             :               Int *,
     750             :               const Double*,
     751             :               const Double*,
     752             :               Int*,
     753             :               Int*,
     754             :               Int*,
     755             :               Int*,
     756             :               const Complex*,
     757             :               Int*,
     758             :               Int*);
     759             : }
     760         200 : void WProjectFT::put(const VisBuffer2& vb, Int row, Bool dopsf,
     761             :                      FTMachine::Type type)
     762             : {
     763             :   
     764             : 
     765             :    //Check if ms has changed then cache new spw and chan selection
     766             :   //if(vb.isNewMs())
     767             :   //  matchAllSpwChans(vb);
     768             :   
     769             :   //Here we redo the match or use previous match
     770             :   
     771             :   //Channel matching for the actual spectral window of buffer
     772             :   //if(doConversion_p[vb.spectralWindows()[0]]){
     773         200 :     matchChannel(vb);
     774             :   //}
     775             :   //else{
     776             :   //  chanMap.resize();
     777             :   //  chanMap=multiChanMap_p[vb.spectralWindows()[0]];
     778             :   //}
     779             :   
     780             :   //No point in reading data if its not matching in frequency
     781         200 :   if(max(chanMap)==-1)
     782           0 :     return;
     783         200 :   Timer tim;
     784         200 :    tim.mark();
     785             : 
     786             :    //const Matrix<Float> *imagingweight;
     787             :    //imagingweight=&(vb.imagingWeight());
     788         200 :    Matrix<Float> imagingweight;
     789         200 :    getImagingWeight(imagingweight, vb);
     790         200 :   if(dopsf) type=FTMachine::PSF;
     791             : 
     792         200 :   Cube<Complex> data;
     793             :   //Fortran gridder need the flag as ints 
     794         200 :   Cube<Int> flags;
     795         200 :   Matrix<Float> elWeight;
     796         200 :   interpolateFrequencyTogrid(vb, imagingweight,data, flags, elWeight, type);
     797             :   
     798             :   
     799             :   Bool iswgtCopy;
     800             :   const Float *wgtStorage;
     801         200 :   wgtStorage=elWeight.getStorage(iswgtCopy);
     802             : 
     803             : 
     804             :   Bool isCopy;
     805         200 :   const Complex *datStorage=0;
     806             : 
     807         200 :   if(!dopsf)
     808         200 :     datStorage=data.getStorage(isCopy);
     809             : 
     810             : 
     811             :   // If row is -1 then we pass through all rows
     812             :   Int startRow, endRow, nRow;
     813         200 :   if (row==-1) {
     814         200 :     nRow=vb.nRows();
     815         200 :     startRow=0;
     816         200 :     endRow=nRow-1;
     817             :   } else {
     818           0 :     nRow=1;
     819           0 :     startRow=row;
     820           0 :     endRow=row;
     821             :   }
     822             :   
     823             :   // Get the uvws in a form that Fortran can use and do that
     824             :   // necessary phase rotation. On a Pentium Pro 200 MHz
     825             :   // when null, this step takes about 50us per uvw point. This
     826             :   // is just barely noticeable for Stokes I continuum and
     827             :   // irrelevant for other cases.
     828         200 :   Matrix<Double> uvw(negateUV(vb));
     829         200 :   Vector<Double> dphase(vb.nRows());
     830         200 :   dphase=0.0;
     831             :  
     832         200 :   rotateUVW(uvw, dphase, vb);
     833         200 :   refocus(uvw, vb.antenna1(), vb.antenna2(), dphase, vb);
     834             : 
     835             : 
     836             :   
     837             :   // Take care of translation of Bools to Integer
     838         200 :   Int idopsf=0;
     839         200 :   if(dopsf) idopsf=1;
     840             :   
     841         200 :   Vector<Int> rowFlags(vb.nRows());
     842         200 :   rowFlags=0;
     843         200 :   rowFlags(vb.flagRow())=true;
     844         200 :   if(!usezero_p) {
     845           0 :     for (Int rownr=startRow; rownr<=endRow; rownr++) {
     846           0 :       if(vb.antenna1()(rownr)==vb.antenna2()(rownr)) rowFlags(rownr)=1;
     847             :     }
     848             :   }
     849             :   
     850             :   
     851             :   Bool del;
     852             :   //    IPosition s(flags.shape());
     853         200 :   Vector<Int> s(flags.shape().nelements());
     854         200 :   convertArray(s, flags.shape().asVector());
     855         200 :   Int nvp=s[0];
     856         200 :   Int nvc=s[1];
     857         200 :   Int nvisrow=s[2];
     858             : 
     859         200 :   Int csamp=convSampling;
     860             :   
     861             :   Bool uvwcopy; 
     862         200 :   const Double *uvwstor=uvw.getStorage(uvwcopy);
     863             :   Bool gridcopy;
     864             :   Bool convcopy;
     865         200 :   const Complex *convstor=convFunc.getStorage(convcopy);
     866         200 :   Cube<Int> loc(3, nvc, nRow);
     867         200 :   Cube<Int> off(3, nvc, nRow);
     868         200 :   Matrix<Complex> phasor(nvc, nRow);
     869             :   Bool delphase;
     870         200 :   Complex * phasorstor=phasor.getStorage(delphase);
     871         200 :   const Double * visfreqstor=interpVisFreq_p.getStorage(del);
     872         200 :   const Double * scalestor=uvScale.getStorage(del);
     873         200 :   const Double * offsetstor=uvOffset.getStorage(del);
     874             :   Bool delloc, deloff;
     875         200 :   Int * locstor=loc.getStorage(delloc);
     876         200 :   Int * offstor=off.getStorage(deloff);
     877         200 :   const Double *dpstor=dphase.getStorage(del);
     878         200 :   Double cinv=Double(1.0)/C::c;
     879             :   Int irow;
     880         200 :   Int dow=1;
     881         200 :   Int nth=1;
     882             : #ifdef _OPENMP
     883         200 :   if(numthreads_p >0){
     884           0 :     nth=min(numthreads_p, omp_get_max_threads());
     885             :   }
     886             :   else{   
     887         200 :     nth= omp_get_max_threads();
     888             :   }
     889             :   //nth=min(4,nth);
     890             : #endif
     891             : 
     892             : 
     893         200 : #pragma omp parallel default(none) private(irow) firstprivate(visfreqstor, nvc, scalestor, offsetstor, csamp, phasorstor, uvwstor, locstor, offstor, dpstor, cinv, dow) shared(startRow, endRow) num_threads(nth)
     894             : 
     895             : {
     896             : #pragma omp for schedule(dynamic)
     897             :   for (irow=startRow; irow<=endRow;irow++){
     898             :     //locateuvw(uvwstor,dpstor, visfreqstor, nvc, scalestor, offsetstor, csamp, 
     899             :     //        locstor, 
     900             :     //        offstor, phasorstor, irow, true);
     901             :     locuvw(uvwstor, dpstor, visfreqstor, &nvc, scalestor, offsetstor, &csamp, locstor, offstor, phasorstor, &irow, &dow, &cinv);
     902             :   }  
     903             : 
     904             :  }//end pragma parallel
     905         200 :   Int maxx=0; 
     906         200 :   Int minx=1000000;
     907         200 :   Int maxy=0;
     908         200 :   Int miny=1000000;
     909             :   //Int maxsupp=max(convSupport);
     910         200 :   loc.putStorage(locstor, delloc);
     911         200 :   maxx=max(loc.yzPlane(0));
     912         200 :   maxx=min(nx-1,  maxx-1);
     913         200 :   minx=min(loc.yzPlane(0));
     914         200 :   minx=max(0, minx-1);
     915         200 :   maxy=max(loc.yzPlane(1));
     916         200 :   maxy=min(ny-1, maxy-1);
     917         200 :   miny=min(loc.yzPlane(1));
     918         200 :   miny=max(0,miny-1);
     919         200 :   locstor=loc.getStorage(delloc);
     920             :   //cerr << "dels " << delloc << "  " << deloff << endl;
     921             :   //cerr << "LOC " << min(loc.xzPlane(0)) << "  max " << loc.shape() << endl;
     922         200 :   timemass_p +=tim.real();
     923             :   Int ixsub, iysub, icounter;
     924         200 :   ixsub=1;
     925         200 :   iysub=1;
     926         200 :   if (nth >4){
     927         200 :     ixsub=8;
     928         200 :     iysub=8; 
     929             :   }
     930             :   else {
     931           0 :      ixsub=2;
     932           0 :      iysub=2; 
     933             :   }
     934             :   //nxsub=nx;
     935             :   //nysub=ny;
     936         200 :   Int rbeg=startRow+1;
     937         200 :   Int rend=endRow+1;
     938             :  
     939         200 :   const Int* pmapstor=polMap.getStorage(del);
     940         200 :   const Int *cmapstor=chanMap.getStorage(del);
     941         200 :   Int nc=nchan;
     942         200 :   Int np=npol;
     943             :   // Int nxp=nx;
     944             :   // Int nyp=ny;
     945         200 :   minx=0;
     946         200 :   miny=0;
     947         200 :   Int nxp=nx;
     948         200 :   Int nyp=ny;
     949         200 :   Int nxcopy=nx;
     950         200 :   Int nycopy=ny;
     951             :  
     952         200 :   Int csize=convSize;
     953         200 :    Int wcsize=wConvSize;
     954         200 :   const Int * flagstor=flags.getStorage(del);
     955         200 :   const Int * rowflagstor=rowFlags.getStorage(del);
     956         200 :   const Int * suppstor=convSupport.getStorage(del);
     957         200 :   tim.mark(); 
     958         200 :   Block<Matrix<Double> > sumwgt(ixsub*iysub);
     959       13000 :   for (icounter=0; icounter < ixsub*iysub; ++icounter){
     960       12800 :     sumwgt[icounter].resize(sumWeight.shape());
     961       12800 :     sumwgt[icounter].set(0.0);
     962             :   }
     963         200 :   if(doneThreadPartition_p < 0){
     964           1 :     xsect_p.resize(ixsub*iysub);
     965           1 :     ysect_p.resize(ixsub*iysub);
     966           1 :     nxsect_p.resize(ixsub*iysub);
     967           1 :     nysect_p.resize(ixsub*iysub);
     968          65 :     for (icounter=0; icounter < ixsub*iysub; ++icounter){
     969          64 :       findGridSector(nxp, nyp, ixsub, iysub, minx, miny, icounter, xsect_p(icounter), ysect_p(icounter), nxsect_p(icounter), nysect_p(icounter), true);
     970             :     }
     971             :   }
     972         200 :   Vector<Int> xsect, ysect, nxsect, nysect;
     973         200 :   xsect=xsect_p; ysect=ysect_p; nxsect=nxsect_p; nysect=nysect_p;
     974             : 
     975         200 :   if(!useDoubleGrid_p){
     976         200 :     Complex *gridstor=griddedData.getStorage(gridcopy);
     977         200 : #pragma omp parallel default(none) private(icounter, del) firstprivate(idopsf, uvwstor, datStorage, wgtStorage, flagstor, rowflagstor, convstor, pmapstor, cmapstor, gridstor, suppstor, nxp, nyp, nxcopy, nycopy, np, nc,ixsub, iysub, rend, rbeg, csamp, csize, wcsize, nvp, nvc, nvisrow, phasorstor, locstor, offstor, minx, miny, xsect, ysect, nxsect, nysect) shared(sumwgt) num_threads(nth)
     978             :     {
     979             : 
     980             : #pragma omp for schedule(dynamic) 
     981             :     for(icounter=0; icounter < ixsub*iysub; ++icounter){
     982             :      
     983             :      
     984             :        Int x0=xsect(icounter);
     985             :        Int y0=ysect(icounter);
     986             :        Int nxsub=nxsect(icounter);
     987             :        Int nysub=nysect(icounter);
     988             : 
     989             :       sectgwgrids(uvwstor,
     990             :            datStorage,
     991             :            &nvp,
     992             :            &nvc,
     993             :            &idopsf,
     994             :            flagstor,
     995             :            rowflagstor,
     996             :            wgtStorage,
     997             :            &nvisrow,
     998             :            gridstor,
     999             :            &nxcopy,
    1000             :            &nycopy,
    1001             :            &np,
    1002             :            &nc,
    1003             :            suppstor,
    1004             :            &csize,
    1005             :            &csamp,
    1006             :            &wcsize,
    1007             :            convstor,
    1008             :            cmapstor,
    1009             :            pmapstor,
    1010             :                   (sumwgt[icounter]).getStorage(del), 
    1011             :                   &x0, &y0, &nxsub, &nysub, &rbeg, &rend, locstor, offstor,
    1012             :                  phasorstor);
    1013             :     }
    1014             :     }//end pragma parallel
    1015         200 :     if(dopsf && (nth > 4))
    1016           0 :       tweakGridSector(nx, ny, ixsub, iysub);
    1017         200 :     timegrid_p+=tim.real();
    1018             : 
    1019       13000 :     for (icounter=0; icounter < ixsub*iysub; ++icounter){
    1020       12800 :       sumWeight=sumWeight+sumwgt[icounter];
    1021             :     }    
    1022         200 :     griddedData.putStorage(gridstor, gridcopy);
    1023             :     
    1024             :   }
    1025             :   else{
    1026           0 :     DComplex *gridstor=griddedData2.getStorage(gridcopy);
    1027           0 : #pragma omp parallel default(none) private(icounter,del) firstprivate(idopsf, uvwstor, datStorage, wgtStorage, flagstor, rowflagstor, convstor, pmapstor, cmapstor, gridstor, suppstor, nxp, nyp, nxcopy, nycopy, np, nc,ixsub, iysub, rend, rbeg, csamp, csize, wcsize, nvp, nvc, nvisrow, phasorstor, locstor, offstor,minx,miny, xsect, ysect, nxsect, nysect) shared(sumwgt) num_threads(nth)
    1028             :     {
    1029             : #pragma omp for  schedule(dynamic)    
    1030             :     for(icounter=0; icounter < ixsub*iysub; ++icounter){
    1031             :       
    1032             :       Int x0=xsect(icounter);
    1033             :       Int y0=ysect(icounter);
    1034             :       Int nxsub=nxsect(icounter);
    1035             :       Int nysub=nysect(icounter);
    1036             : 
    1037             :       sectgwgridd(uvwstor,
    1038             :            datStorage,
    1039             :            &nvp,
    1040             :            &nvc,
    1041             :            &idopsf,
    1042             :            flagstor,
    1043             :            rowflagstor,
    1044             :            wgtStorage,
    1045             :            &nvisrow,
    1046             :            gridstor,
    1047             :            &nxcopy,
    1048             :            &nycopy,
    1049             :            &np,
    1050             :            &nc,
    1051             :            suppstor,
    1052             :            &csize,
    1053             :            &csamp,
    1054             :            &wcsize,
    1055             :            convstor,
    1056             :            cmapstor,
    1057             :            pmapstor,
    1058             :                   (sumwgt[icounter]).getStorage(del), 
    1059             :                   &x0, &y0, &nxsub, &nysub, &rbeg, &rend, locstor, offstor,
    1060             :                  phasorstor);
    1061             :     }
    1062             :     }//end pragma parallel
    1063           0 :     if(dopsf && (nth > 4))
    1064           0 :       tweakGridSector(nx, ny, ixsub, iysub);
    1065           0 :     timegrid_p+=tim.real();
    1066             : 
    1067           0 :     for (icounter=0; icounter < ixsub*iysub; ++icounter){
    1068           0 :       sumWeight=sumWeight+sumwgt[icounter];
    1069             :     }
    1070           0 :     griddedData2.putStorage(gridstor, gridcopy);
    1071             :   }
    1072         200 :   uvw.freeStorage(uvwstor, uvwcopy);
    1073         200 :   convFunc.freeStorage(convstor, convcopy);
    1074             :   
    1075         200 :   if(!dopsf)
    1076         200 :     data.freeStorage(datStorage, isCopy);
    1077         200 :   elWeight.freeStorage(wgtStorage,iswgtCopy);
    1078         200 : }
    1079             : 
    1080             : 
    1081             : 
    1082         200 : void WProjectFT::get(VisBuffer2& vb, Int row)
    1083             : {
    1084             :   
    1085             : 
    1086         200 :   findConvFunction(*image, vb);
    1087             :   // If row is -1 then we pass through all rows
    1088             :   Int startRow, endRow, nRow;
    1089         200 :   if (row==-1) {
    1090         200 :     nRow=vb.nRows();
    1091         200 :     startRow=0;
    1092         200 :     endRow=nRow-1;
    1093             :     //vb.modelVisCube()=Complex(0.0,0.0);
    1094             :   } else {
    1095           0 :     nRow=1;
    1096           0 :     startRow=row;
    1097           0 :     endRow=row;
    1098             :     //vb.modelVisCube().xyPlane(row)=Complex(0.0,0.0);
    1099             :   }
    1100             :   
    1101             :   
    1102             : //Channel matching for the actual spectral window of buffer
    1103         200 :     matchChannel(vb);
    1104             :  
    1105             :   //No point in reading data if its not matching in frequency
    1106         200 :   if(max(chanMap)==-1)
    1107           0 :     return;
    1108             : 
    1109             : 
    1110             :   // Get the uvws in a form that Fortran can use
    1111         200 :   Matrix<Double> uvw(negateUV(vb));
    1112         200 :   Vector<Double> dphase(vb.nRows());
    1113         200 :   dphase=0.0;
    1114             :    
    1115         200 :   rotateUVW(uvw, dphase, vb);
    1116         200 :   refocus(uvw, vb.antenna1(), vb.antenna2(), dphase, vb);
    1117             : 
    1118             :   // This is the convention for dphase
    1119             :   // dphase*=-1.0;
    1120             :  
    1121             :   
    1122             :   //Check if ms has changed then cache new spw and chan selection
    1123             :   //if(vb.isNewMs())
    1124             :   //  matchAllSpwChans(vb);
    1125             :   //Here we redo the match or use previous match
    1126             :   
    1127             :   
    1128         200 :   Cube<Complex> data;
    1129         200 :   Cube<Int> flags;
    1130         200 :   getInterpolateArrays(vb, data, flags);
    1131             : 
    1132             : 
    1133             :   
    1134             :   Complex *datStorage;
    1135             :   Bool isCopy;
    1136         200 :   datStorage=data.getStorage(isCopy);
    1137             : 
    1138         200 :   Vector<Int> rowFlags(vb.nRows());
    1139         200 :   rowFlags=0;
    1140         200 :   rowFlags(vb.flagRow())=true;
    1141         200 :   if(!usezero_p) {
    1142           0 :     for (Int rownr=startRow; rownr<=endRow; rownr++) {
    1143           0 :       if(vb.antenna1()(rownr)==vb.antenna2()(rownr)) rowFlags(rownr)=1;
    1144             :     }
    1145             :   }
    1146             :   
    1147         200 :   Int nvp=data.shape()(0);
    1148         200 :   Int nvc=data.shape()(1);
    1149         200 :   Int nvisrow=data.shape()(2);
    1150         200 :   Int nc=nchan;
    1151         200 :   Int np=npol;
    1152         200 :   Int nxp=nx;
    1153         200 :   Int nyp=ny;
    1154         200 :   Cube<Int> loc(3, nvc, nvisrow);
    1155         200 :   Cube<Int> off(3, nvc, nRow);
    1156         200 :   Int csamp=convSampling;
    1157         200 :   Int csize=convSize;
    1158         200 :   Int wcsize=wConvSize;
    1159         200 :   Matrix<Complex> phasor(nvc, nRow);
    1160             :   Bool delphase;
    1161             :   Bool del;
    1162         200 :   Complex * phasorstor=phasor.getStorage(delphase);
    1163         200 :   const Double * visfreqstor=interpVisFreq_p.getStorage(del);
    1164         200 :   const Double * scalestor=uvScale.getStorage(del);
    1165         200 :   const Double * offsetstor=uvOffset.getStorage(del);
    1166         200 :   Int * locstor=loc.getStorage(del);
    1167         200 :   Int * offstor=off.getStorage(del);
    1168         200 :   const Int * flagstor=flags.getStorage(del);
    1169         200 :   const Int * rowflagstor=rowFlags.getStorage(del);
    1170         200 :   const Double *dpstor=dphase.getStorage(del);
    1171             :   Bool uvwcopy; 
    1172         200 :   const Double *uvwstor=uvw.getStorage(uvwcopy);
    1173             :   Bool gridcopy;
    1174         200 :   const Complex *gridstor=griddedData.getStorage(gridcopy);
    1175             :   Bool convcopy;
    1176         200 :   const Complex *convstor=convFunc.getStorage(convcopy);
    1177         200 :   const Int* pmapstor=polMap.getStorage(del);
    1178         200 :   const Int *cmapstor=chanMap.getStorage(del);
    1179         200 :   const Int * suppstor=convSupport.getStorage(del);
    1180             :   Int irow;
    1181         200 :   Int nth=1;
    1182             : #ifdef _OPENMP
    1183         200 :   if(numthreads_p >0){
    1184           0 :     nth=min(numthreads_p, omp_get_max_threads());
    1185             :   }
    1186             :   else{   
    1187         200 :     nth= omp_get_max_threads();
    1188             :   }
    1189             :   // nth=min(4,nth);
    1190             : #endif
    1191         200 :   Int dow=1;
    1192         200 :   Double cinv=Double(1.0)/C::c;
    1193         200 :   #pragma omp parallel default(none) private(irow) firstprivate(visfreqstor, nvc, scalestor, offsetstor, csamp, phasorstor, uvwstor, locstor, offstor, dpstor, dow, cinv) shared(startRow, endRow) num_threads(nth) 
    1194             :   {
    1195             : 
    1196             : #pragma omp for schedule(dynamic)
    1197             :     for (irow=startRow; irow<=endRow; ++irow){
    1198             :       /*locateuvw(uvwstor,dpstor, visfreqstor, nvc, scalestor, offsetstor, csamp, 
    1199             :                 locstor, 
    1200             :                 offstor, phasorstor, irow, true);*/
    1201             :       locuvw(uvwstor, dpstor, visfreqstor, &nvc, scalestor, offsetstor, &csamp, locstor, offstor, phasorstor, &irow, &dow, &cinv);
    1202             :   }  
    1203             : 
    1204             :   }//end pragma parallel
    1205         200 :   Int rbeg=startRow+1;
    1206         200 :   Int rend=endRow+1;
    1207         200 :   Int npart=nth;
    1208         200 :   Timer tim;
    1209         200 :   tim.mark();
    1210             :  
    1211         200 :   Int ix=0;
    1212         200 : #pragma omp parallel default(none) private(ix, rbeg, rend) firstprivate(uvwstor, datStorage, flagstor, rowflagstor, convstor, pmapstor, cmapstor, gridstor, nxp, nyp, np, nc, suppstor, csamp, csize, wcsize, nvp, nvc, nvisrow, phasorstor, locstor, offstor) shared(npart) num_threads(nth)
    1213             :   {
    1214             : 
    1215             : #pragma omp for schedule(dynamic)
    1216             :     for (ix=0; ix< npart; ++ix){
    1217             :       rbeg=ix*(nvisrow/npart)+1;
    1218             :       rend=(ix != (npart-1)) ? (rbeg+(nvisrow/npart)-1) : (rbeg+(nvisrow/npart)+nvisrow%npart-1) ;
    1219             :       // cerr << "rbeg " << rbeg << " rend " << rend << " nRow " << nvisrow << endl;
    1220             :       sectdwgrid(uvwstor,
    1221             :                  datStorage,
    1222             :                  &nvp,
    1223             :                  &nvc,
    1224             :                  flagstor,
    1225             :                  rowflagstor,
    1226             :                  &nvisrow,
    1227             :                  gridstor,
    1228             :                  &nxp,
    1229             :                  &nyp,
    1230             :                  &np,
    1231             :                  &nc,
    1232             :                  suppstor,
    1233             :                  &csize,
    1234             :                  &csamp,
    1235             :                  &wcsize,
    1236             :                  convstor,
    1237             :                  cmapstor,
    1238             :                  pmapstor,
    1239             :                  &rbeg, &rend, locstor, offstor, phasorstor);
    1240             :     }
    1241             : 
    1242             :   }//end pragma parallel
    1243         200 :   data.putStorage(datStorage, isCopy);
    1244         200 :   uvw.freeStorage(uvwstor, uvwcopy);
    1245         200 :   griddedData.freeStorage(gridstor, gridcopy);
    1246         200 :   convFunc.freeStorage(convstor, convcopy);
    1247         200 :    timedegrid_p+=tim.real();
    1248             : 
    1249         200 :   interpolateFrequencyFromgrid(vb, data, FTMachine::MODEL);
    1250         200 : }
    1251             : 
    1252             : 
    1253             : 
    1254             : // Finalize the FFT to the Sky. Here we actually do the FFT and
    1255             : // return the resulting image
    1256           1 : ImageInterface<Complex>& WProjectFT::getImage(Matrix<Float>& weights,
    1257             :                                               Bool normalize) 
    1258             : {
    1259             :   //AlwaysAssert(lattice, AipsError);
    1260           1 :   AlwaysAssert(image, AipsError);
    1261             :   
    1262           1 :   if((griddedData.nelements() ==0) && (griddedData2.nelements()==0)){
    1263           0 :      throw(AipsError("Programmer error ...request for image without right order of calls"));
    1264             :   }
    1265           1 :   logIO() << LogOrigin("WProjectFT", "getImage") << LogIO::NORMAL;
    1266             :   
    1267           1 :   weights.resize(sumWeight.shape());
    1268             :   
    1269           1 :   convertArray(weights, sumWeight);
    1270             :   
    1271             :   // If the weights are all zero then we cannot normalize
    1272             :   // otherwise we don't care.
    1273           1 :   if(max(weights)==0.0) {
    1274           0 :     if(normalize) {
    1275             :       logIO() << LogIO::SEVERE
    1276             :               << "No useful data in WProjectFT: weights all zero"
    1277           0 :               << LogIO::POST;
    1278             :     }
    1279             :     else {
    1280             :       logIO() << LogIO::WARN
    1281             :               << "No useful data in WProjectFT: weights all zero"
    1282           0 :               << LogIO::POST;
    1283             :     }
    1284             :   }
    1285             :   else {
    1286             :     logIO() << LogIO::DEBUGGING
    1287           1 :             << "Starting FFT and scaling of image" << LogIO::POST;
    1288             :     
    1289           1 :     if(useDoubleGrid_p){
    1290           0 :       ArrayLattice<DComplex> darrayLattice(griddedData2);
    1291           0 :       LatticeFFT::cfft2d(darrayLattice,false);
    1292           0 :       griddedData.resize(griddedData2.shape());
    1293           0 :       convertArray(griddedData, griddedData2);
    1294           0 :       SynthesisUtilMethods::getResource("mem peak in getImage");
    1295           0 :       griddedData2.resize();
    1296           0 :       arrayLattice = new ArrayLattice<Complex>(griddedData);
    1297           0 :       lattice=arrayLattice;
    1298           0 :     }else{
    1299           1 :       arrayLattice = new ArrayLattice<Complex>(griddedData);
    1300           1 :       lattice=arrayLattice;
    1301           1 :       LatticeFFT::cfft2d(*lattice,false);
    1302             : 
    1303             :     }
    1304             : 
    1305             : 
    1306           1 :     const IPosition latticeShape = lattice->shape();
    1307             :     
    1308             :     
    1309             :     {
    1310           1 :       Int inx = lattice->shape()(0);
    1311           1 :       Int iny = lattice->shape()(1);
    1312           1 :       Vector<Complex> correction(inx);
    1313           1 :       correction=Complex(1.0, 0.0);
    1314             : 
    1315           1 :       Int npixCorr= max(nx,ny);
    1316           1 :       Vector<Float> sincConv(npixCorr);
    1317         101 :       for (Int ix=0;ix<npixCorr;ix++) {
    1318         100 :         Float x=C::pi*Float(ix-npixCorr/2)/(Float(npixCorr)*Float(convSampling));
    1319         100 :         if(ix==npixCorr/2) {
    1320           1 :           sincConv(ix)=1.0;
    1321             :         }
    1322             :         else {
    1323          99 :           sincConv(ix)=sin(x)/x;
    1324             :         }
    1325             :       }
    1326             : 
    1327           1 :       IPosition cursorShape(4, inx, 1, 1, 1);
    1328           1 :       IPosition axisPath(4, 0, 1, 2, 3);
    1329           1 :       LatticeStepper lsx(lattice->shape(), cursorShape, axisPath);
    1330           1 :       LatticeIterator<Complex> lix(*lattice, lsx);
    1331         101 :       for(lix.reset();!lix.atEnd();lix++) {
    1332         100 :         Int pol=lix.position()(2);
    1333         100 :         Int chan=lix.position()(3);
    1334         100 :         if(weights(pol, chan)!=0.0) {
    1335         100 :           Int iy=lix.position()(1);
    1336         100 :           gridder->correctX1D(correction,iy);
    1337       10100 :           for (Int ix=0;ix<nx;ix++) {
    1338       10000 :             correction(ix)*=sincConv(ix)*sincConv(iy);
    1339             :           }
    1340         100 :           lix.rwVectorCursor()/=correction;
    1341         100 :           if(normalize) {
    1342         100 :             Complex rnorm(Float(inx)*Float(iny)/weights(pol,chan));
    1343         100 :             lix.rwCursor()*=rnorm;
    1344             :           }
    1345             :           else {
    1346           0 :             Complex rnorm(Float(inx)*Float(iny));
    1347           0 :             lix.rwCursor()*=rnorm;
    1348             :           }
    1349             :         }
    1350             :         else {
    1351           0 :           lix.woCursor()=0.0;
    1352             :         }
    1353             :       }
    1354           1 :     }
    1355             : 
    1356           1 :     if(!isTiled) {
    1357           1 :       LatticeLocker lock1 (*(image), FileLocker::Write);
    1358             :       // Check the section from the image BEFORE converting to a lattice 
    1359           2 :       IPosition blc(4, (nx-image->shape()(0)+(nx%2==0))/2,
    1360           2 :                     (ny-image->shape()(1)+(ny%2==0))/2, 0, 0);
    1361           1 :       IPosition stride(4, 1);
    1362           2 :       IPosition trc(blc+image->shape()-stride);
    1363             :       
    1364             :       // Do the copy
    1365           1 :       image->put(griddedData(blc, trc));
    1366             :       //if(arrayLattice) delete arrayLattice; arrayLattice=0;
    1367           1 :       griddedData.resize(IPosition(1,0));
    1368           1 :     }
    1369           1 :   }
    1370           1 :   if(!lattice.null()) lattice=nullptr;
    1371           1 :   if(!arrayLattice.null()) lattice=nullptr;
    1372           1 :   griddedData.resize();
    1373           1 :   return *image;
    1374             : }
    1375             : 
    1376             : // Get weight image
    1377           0 : void WProjectFT::getWeightImage(ImageInterface<Float>& weightImage,
    1378             :                               Matrix<Float>& weights) 
    1379             : {
    1380             :   
    1381           0 :   logIO() << LogOrigin("WProjectFT", "getWeightImage") << LogIO::NORMAL;
    1382             :   
    1383           0 :   weights.resize(sumWeight.shape());
    1384           0 :   convertArray(weights,sumWeight);
    1385             :   
    1386           0 :   const IPosition latticeShape = weightImage.shape();
    1387             :   
    1388           0 :   Int inx=latticeShape(0);
    1389           0 :   Int iny=latticeShape(1);
    1390             :   
    1391           0 :   IPosition loc(2, 0);
    1392           0 :   IPosition cursorShape(4, inx, iny, 1, 1);
    1393           0 :   IPosition axisPath(4, 0, 1, 2, 3);
    1394           0 :   LatticeStepper lsx(latticeShape, cursorShape, axisPath);
    1395           0 :   LatticeIterator<Float> lix(weightImage, lsx);
    1396           0 :   for(lix.reset();!lix.atEnd();lix++) {
    1397           0 :     Int pol=lix.position()(2);
    1398           0 :     Int chan=lix.position()(3);
    1399           0 :     lix.rwCursor()=weights(pol,chan);
    1400             :   }
    1401           0 : }
    1402             : 
    1403           0 : Bool WProjectFT::toRecord(String& error,
    1404             :                           RecordInterface& outRec, Bool withImage, const String diskimage)
    1405             : {  
    1406             : 
    1407             :   /*
    1408             : 
    1409             :   CountedPtr<WPConvFunc> wpConvFunc_p;
    1410             :   */
    1411             : 
    1412             :   // Save the current WProjectFT object to an output state record
    1413           0 :   Bool retval = true;
    1414             :   //save the base class variables
    1415             :   //this is a memory hog and slow on saving and recovering...better to recompute convfunctions
    1416             :   /* Record wpconvrec;
    1417             :   if(wpConvFunc_p->toRecord(wpconvrec))
    1418             :     outRec.defineRecord("wpconvfunc", wpconvrec);
    1419             :   */
    1420           0 :    Float elpadd=padding_p;
    1421           0 :   if(toVis_p && withImage)
    1422           0 :     elpadd=1.0;
    1423           0 :   if(!FTMachine::toRecord(error, outRec, withImage, diskimage))
    1424           0 :     return false;
    1425             : 
    1426           0 :   outRec.define("uvscale", uvScale);
    1427           0 :   outRec.define("uvoffset", uvOffset);
    1428           0 :   outRec.define("istiled", isTiled);
    1429           0 :   outRec.define("cachesize", Int64(cachesize));
    1430           0 :   outRec.define("tilesize", tilesize);
    1431           0 :   outRec.define("maxabsdata", maxAbsData);
    1432           0 :   Vector<Int> center_loc(4), offset_loc(4);
    1433           0 :   for (Int k=0; k<4 ; k++){
    1434           0 :     center_loc(k)=centerLoc(k);
    1435           0 :     offset_loc(k)=offsetLoc(k);
    1436             :   }
    1437           0 :   outRec.define("centerloc", center_loc);
    1438           0 :   outRec.define("offsetloc", offset_loc);
    1439           0 :   outRec.define("padding", elpadd);
    1440           0 :   outRec.define("nwplanes", nWPlanes_p);
    1441           0 :   outRec.define("savedwscale", savedWScale_p);
    1442           0 :   outRec.define("usezero", usezero_p);
    1443             :   ///no need to save convfunc as it can be big and is recalculated anyways
    1444             :   ///outRec.define("convfunc", convFunc);
    1445           0 :   outRec.define("convsampling", convSampling);
    1446           0 :   outRec.define("convsize", convSize);
    1447           0 :   outRec.define("convsupport", convSupport);
    1448           0 :   outRec.define("convsizes", convSizes_p);
    1449           0 :   outRec.define("wconvsize", wConvSize);
    1450           0 :   outRec.define("lastindex", lastIndex_p);
    1451           0 :   outRec.define("minw", minW_p);
    1452           0 :   outRec.define("maxw", maxW_p);
    1453           0 :   outRec.define("rmsw", rmsW_p);
    1454             : 
    1455             : 
    1456             : 
    1457           0 :   return retval;
    1458           0 : }
    1459             : 
    1460           0 : Bool WProjectFT::fromRecord(String& error,
    1461             :                             const RecordInterface& inRec)
    1462             : {
    1463           0 :   if(!FTMachine::fromRecord(error, inRec))
    1464           0 :     return false;
    1465           0 :   machineName_p="WProjectFT";
    1466           0 :   Bool retval = true;
    1467           0 :   imageCache=0; lattice=0; arrayLattice=0;
    1468           0 :   inRec.get("uvscale", uvScale);
    1469           0 :   inRec.get("uvoffset", uvOffset);
    1470           0 :   inRec.get("istiled", isTiled);
    1471           0 :   cachesize=inRec.asInt64("cachesize");
    1472           0 :   inRec.get("tilesize", tilesize);
    1473           0 :   inRec.get("maxabsdata", maxAbsData);
    1474           0 :   Vector<Int> center_loc(4), offset_loc(4);
    1475           0 :   inRec.get("centerloc", center_loc);
    1476           0 :   inRec.get("offsetloc", offset_loc);
    1477           0 :   uInt ndim4 = 4;
    1478           0 :   centerLoc=IPosition(ndim4, center_loc(0), center_loc(1), center_loc(2), 
    1479           0 :                       center_loc(3));
    1480           0 :   offsetLoc=IPosition(ndim4, offset_loc(0), offset_loc(1), offset_loc(2), 
    1481           0 :                       offset_loc(3));
    1482           0 :   inRec.get("minw", minW_p);
    1483           0 :   inRec.get("maxw", maxW_p);
    1484           0 :   inRec.get("rmsw", rmsW_p);
    1485           0 :   if(inRec.isDefined("wpconvfunc")){
    1486           0 :     wpConvFunc_p=new WPConvFunc(inRec.asRecord("wpconvfunc"));
    1487             :   }
    1488             :   else{
    1489           0 :     wpConvFunc_p=new WPConvFunc(minW_p, maxW_p, rmsW_p);
    1490             :   }
    1491           0 :   inRec.get("padding", padding_p);
    1492           0 :   inRec.get("nwplanes", nWPlanes_p);
    1493           0 :   inRec.get("savedwscale", savedWScale_p);
    1494           0 :   inRec.get("usezero", usezero_p);
    1495             :   //inRec.get("convfunc", convFunc);
    1496           0 :   convFunc.resize();
    1497           0 :   inRec.get("convsampling", convSampling);
    1498           0 :   inRec.get("convsize", convSize);
    1499           0 :   inRec.get("convsupport", convSupport);
    1500           0 :   inRec.get("convsizes", convSizes_p);
    1501           0 :   inRec.get("wconvsize", wConvSize);
    1502           0 :   inRec.get("lastindex", lastIndex_p);
    1503           0 :   gridder=0;
    1504             :     ///setup some of the parameters
    1505           0 :   init();
    1506             :      
    1507             : 
    1508             :   
    1509           0 :   return retval;
    1510           0 : }
    1511             : 
    1512         801 : void WProjectFT::ok() {
    1513         801 :   AlwaysAssert(image, AipsError);
    1514         801 : }
    1515             : 
    1516             : // Make a plain straightforward honest-to-God image. This returns
    1517             : // a complex image, without conversion to Stokes. The representation
    1518             : // is that required for the visibilities.
    1519             : //----------------------------------------------------------------------
    1520           0 : void WProjectFT::makeImage(FTMachine::Type type, 
    1521             :                          VisibilityIterator2& vi,
    1522             :                          ImageInterface<Complex>& theImage,
    1523             :                          Matrix<Float>& weight) {
    1524             :   
    1525             :   
    1526           0 :   logIO() << LogOrigin("WProjectFT", "makeImage") << LogIO::NORMAL;
    1527             :   
    1528           0 :   if(type==FTMachine::COVERAGE) {
    1529             :     logIO() << "Type COVERAGE not defined for Fourier transforms"
    1530           0 :             << LogIO::EXCEPTION;
    1531             :   }
    1532             :   
    1533             :   
    1534             :   
    1535             :   // Loop over all visibilities and pixels
    1536           0 :   VisBuffer2 *vb=vi.getVisBuffer();
    1537             :   
    1538             :   // Initialize put (i.e. transform to Sky) for this model
    1539           0 :   vi.origin();
    1540             :   
    1541           0 :   if(vb->polarizationFrame()==MSIter::Linear) {
    1542           0 :     StokesImageUtil::changeCStokesRep(theImage, StokesImageUtil::LINEAR);
    1543             :   }
    1544             :   else {
    1545           0 :     StokesImageUtil::changeCStokesRep(theImage, StokesImageUtil::CIRCULAR);
    1546             :   }
    1547             :   
    1548           0 :   initializeToSky(theImage,weight,*vb);
    1549             :   
    1550             :   // Loop over the visibilities, putting VisBuffers
    1551           0 :   for (vi.originChunks();vi.moreChunks();vi.nextChunk()) {
    1552           0 :     for (vi.origin(); vi.more(); vi.next()) {
    1553             :       
    1554           0 :       switch(type) {
    1555           0 :       case FTMachine::RESIDUAL:
    1556             :           //vb.visCube()=vb.correctedVisCube();
    1557           0 :           vb->setVisCube(vb->visCubeCorrected()-vb->visCubeModel());
    1558           0 :           put(*vb, -1, false);
    1559           0 :           break;
    1560           0 :       case FTMachine::MODEL:
    1561           0 :           vb->setVisCube(vb->visCubeModel());
    1562           0 :           put(*vb, -1, false);
    1563           0 :           break;
    1564           0 :       case FTMachine::CORRECTED:
    1565           0 :           vb->setVisCube(vb->visCubeCorrected());
    1566           0 :           put(*vb, -1, false);
    1567           0 :           break;
    1568           0 :       case FTMachine::PSF:
    1569           0 :           vb->setVisCube(Complex(1.0,0.0));
    1570           0 :           put(*vb, -1, true);
    1571           0 :           break;
    1572           0 :       case FTMachine::OBSERVED:
    1573             :       default:
    1574           0 :           put(*vb, -1, false);
    1575           0 :           break;
    1576             :       }
    1577             :     }
    1578             :   }
    1579           0 :   finalizeToSky();
    1580             :   // Normalize by dividing out weights, etc.
    1581           0 :   getImage(weight, true);
    1582           0 : }
    1583             : 
    1584             : 
    1585           0 : String WProjectFT::name() const {
    1586             : 
    1587           0 :   return machineName_p;
    1588             : 
    1589             : }
    1590           0 : void WProjectFT::wStat(vi::VisibilityIterator2& vi, Double& minW, Double& maxW, Double& rmsW){
    1591           0 :   VisBuffer2* vb= vi.getVisBuffer();
    1592           0 :     maxW=0.0;
    1593           0 :     minW=1e99;
    1594           0 :     Double nval=0;
    1595           0 :     rmsW=0.0;
    1596           0 :     for (vi.originChunks(); vi.moreChunks(); vi.nextChunk()) {
    1597           0 :       for (vi.origin();vi.more();vi.next()) {
    1598           0 :         maxW=max(maxW, max(abs(vb->uvw().row(2)*max(vb->getFrequencies(0))))/C::c);
    1599           0 :         minW=min(minW, min(abs(vb->uvw().row(2)*min(vb->getFrequencies(0))))/C::c);
    1600             :         ///////////some shenanigans as some compilers is confusing * operator for vector
    1601           0 :         Vector<Double> elw;
    1602           0 :         elw=vb->uvw().row(2);
    1603           0 :         elw*=vb->uvw().row(2);
    1604             :         //////////////////////////////////////////////////
    1605           0 :         rmsW+=sum(elw);
    1606             : 
    1607           0 :         nval+=Double(vb->nRows());
    1608           0 :       }
    1609             :     }
    1610           0 :     rmsW=sqrt(rmsW/Double(nval))*max(vb->getFrequencies(0))/C::c;
    1611             : 
    1612           0 :   }
    1613             : 
    1614             : 
    1615             : } // end of namespace refim
    1616             : } //# NAMESPACE CASA - END
    1617             : 

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