LCOV - code coverage report
Current view: top level - synthesis/TransformMachines - WPConvFunc.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 443 0.0 %
Date: 2024-12-11 20:54:31 Functions: 0 12 0.0 %

          Line data    Source code
       1             : //# WPConvFunc.cc: implementation of WPConvFunc
       2             : //# Copyright (C) 2007
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This library is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU Library General Public License as published by
       7             : //# the Free Software Foundation; either version 2 of the License, or (at your
       8             : //# option) any later version.
       9             : //#
      10             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Library General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU Library General Public License
      16             : //# along with this library; if not, write to the Free Software Foundation,
      17             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be adressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : //#
      27             : //# $Id$
      28             : #include <sstream>
      29             : #include <iostream>
      30             : #include <iomanip>
      31             : #include <casacore/casa/Arrays/ArrayMath.h>
      32             : #include <casacore/casa/Arrays/Array.h>
      33             : #include <casacore/casa/Arrays/MaskedArray.h>
      34             : #include <casacore/casa/Arrays/Vector.h>
      35             : #include <casacore/casa/Arrays/Slice.h>
      36             : #include <casacore/casa/Arrays/Matrix.h>
      37             : #include <casacore/casa/Arrays/Cube.h>
      38             : #include <casacore/casa/OS/HostInfo.h>
      39             : #include <casacore/casa/OS/Timer.h>
      40             : #include <casacore/casa/Utilities/Assert.h>
      41             : #include <casacore/casa/Utilities/CompositeNumber.h>
      42             : #include <casacore/coordinates/Coordinates/CoordinateSystem.h>
      43             : #include <casacore/coordinates/Coordinates/DirectionCoordinate.h>
      44             : 
      45             : #include <casacore/images/Images/ImageInterface.h>
      46             : #include <casacore/images/Images/PagedImage.h>
      47             : #include <casacore/images/Images/TempImage.h>
      48             : #include <casacore/casa/Logging/LogIO.h>
      49             : #include <casacore/casa/Logging/LogSink.h>
      50             : #include <casacore/casa/Logging/LogMessage.h>
      51             : 
      52             : #include <casacore/lattices/Lattices/ArrayLattice.h>
      53             : #include <casacore/lattices/Lattices/SubLattice.h>
      54             : #include <casacore/lattices/LRegions/LCBox.h>
      55             : #include <casacore/lattices/LEL/LatticeExpr.h>
      56             : #include <casacore/lattices/Lattices/LatticeCache.h>
      57             : #include <casacore/lattices/LatticeMath/LatticeFFT.h>
      58             : #include <casacore/scimath/Mathematics/ConvolveGridder.h>
      59             : #include <casacore/scimath/Mathematics/FFTPack.h>
      60             : #include <msvis/MSVis/VisBuffer.h>
      61             : #include <msvis/MSVis/VisibilityIterator.h>
      62             : #include <synthesis/TransformMachines/SimplePBConvFunc.h> //por SINCOS
      63             : 
      64             : #include <synthesis/TransformMachines/WPConvFunc.h>
      65             : #ifdef _OPENMP
      66             : #include <omp.h>
      67             : #endif
      68             : 
      69             : 
      70             : using namespace casacore;
      71             : namespace casa { //# NAMESPACE CASA - BEGIN
      72             : 
      73             :   typedef unsigned long long ooLong; 
      74             : 
      75           0 :   WPConvFunc::WPConvFunc(const Double minW, const Double maxW, const Double rmsW):
      76           0 :    actualConvIndex_p(-1), convSize_p(0), convSupport_p(0), minW_p(minW), maxW_p(maxW), rmsW_p(rmsW) {
      77             :    //
      78           0 :   }
      79             : 
      80           0 :   WPConvFunc::~WPConvFunc(){
      81             :     //usage of CountedPtr keeps this simple
      82             : 
      83           0 :   }
      84             : 
      85           0 :   WPConvFunc::WPConvFunc(const RecordInterface& rec):
      86           0 :    actualConvIndex_p(-1), convSize_p(0), convSupport_p(0){
      87           0 :     String error;
      88           0 :     if (!fromRecord(error, rec)) {
      89           0 :       throw (AipsError("Failed to create WPConvFunc: " + error));
      90             :     }
      91             :   
      92           0 :   }
      93           0 :   WPConvFunc::WPConvFunc(const WPConvFunc& other):
      94           0 :    actualConvIndex_p(-1), convSize_p(0), convSupport_p(0){
      95             : 
      96           0 :     operator=(other);
      97           0 :   }
      98             : 
      99           0 :   WPConvFunc& WPConvFunc::operator=(const WPConvFunc& other){
     100           0 :     if(this != &other){
     101           0 :       uInt numConv=other.convFunctions_p.nelements();
     102           0 :       convFunctions_p.resize(numConv, true, false);
     103           0 :       convSupportBlock_p.resize(numConv, true, false);
     104           0 :       for (uInt k=0; k < numConv; ++k){
     105           0 :         convFunctions_p[k]=new Cube<Complex>();
     106           0 :         *(convFunctions_p[k])=*(other.convFunctions_p[k]);
     107           0 :         convSupportBlock_p[k]=new Vector<Int> ();
     108           0 :         *(convSupportBlock_p[k]) = *(other.convSupportBlock_p[k]);
     109             :       }
     110             :      
     111           0 :       convFunctionMap_p=other.convFunctionMap_p;
     112           0 :       convSizes_p.resize();
     113           0 :       convSizes_p=other.convSizes_p;
     114           0 :       actualConvIndex_p=other.actualConvIndex_p;
     115           0 :       convSize_p=other.convSize_p;
     116           0 :       convSupport_p.resize();
     117           0 :       convSupport_p=other.convSupport_p;
     118           0 :       convFunc_p.resize();
     119           0 :       convFunc_p=other.convFunc_p;
     120           0 :       wScaler_p=other.wScaler_p;
     121           0 :       convSampling_p=other.convSampling_p;
     122           0 :       nx_p=other.nx_p; 
     123           0 :       ny_p=other.ny_p;
     124           0 :       minW_p=other.minW_p;
     125           0 :       maxW_p=other.maxW_p;
     126           0 :       rmsW_p=other.rmsW_p;
     127             : 
     128             : 
     129             :       
     130             :     }
     131           0 :     return *this;
     132             :   }
     133             :    
     134           0 : void WPConvFunc::findConvFunction(const ImageInterface<Complex>& image, 
     135             :                                     const VisBuffer& vb,
     136             :                                     const Int& wConvSizeUser,
     137             :                                     const Vector<Double>& uvScale,
     138             :                                     const Vector<Double>& uvOffset, 
     139             :                                     const Float& padding,
     140             :                                     Int& convSampling,
     141             :                                     Cube<Complex>& convFunc, 
     142             :                                     Int& convSize,
     143             :                                     Vector<Int>& convSupport, Double& wScale){
     144           0 :    if(checkCenterPix(image)){ 
     145           0 :      convFunc.resize();
     146           0 :      convFunc.reference(convFunc_p);
     147           0 :      convSize=convSize_p;
     148           0 :      convSampling=convSampling_p;
     149           0 :      convSupport.resize();
     150           0 :      convSupport=convSupport_p;
     151           0 :     wScale=Float((convFunc.shape()(2)-1)*(convFunc.shape()(2)-1))/wScaler_p;
     152           0 :     return;
     153             :    }
     154           0 :    LogIO os;
     155           0 :    os << LogOrigin("WPConvFunc", "findConvFunction")  << LogIO::NORMAL;
     156             :    
     157             :    
     158             :   // Get the coordinate system
     159           0 :    CoordinateSystem coords(image.coordinates());
     160           0 :    Int directionIndex=coords.findCoordinate(Coordinate::DIRECTION);
     161           0 :    nx_p=Int(image.shape()(directionIndex)); 
     162           0 :    ny_p=Int(image.shape()(directionIndex+1));
     163             :    
     164           0 :    Int wConvSize=wConvSizeUser;
     165             :    ////Automatic mode
     166             :    Double maxUVW;
     167           0 :    if(wConvSize < 1){
     168           0 :      maxUVW=rmsW_p < 0.5*(minW_p+maxW_p) ? 1.05*maxW_p: (rmsW_p /(0.5*((minW_p)+maxW_p))*1.05*maxW_p) ;
     169           0 :      wConvSize=Int(maxUVW*fabs(sin(fabs(image.coordinates().increment()(0))*max(nx_p, ny_p)/2.0)));  
     170           0 :      convSupport.resize(wConvSize);
     171             :    }
     172             :    else{    
     173           0 :      if(maxW_p> 0.0)
     174           0 :        maxUVW= 1.05*maxW_p;
     175             :      else
     176           0 :        maxUVW=0.25/abs(image.coordinates().increment()(0));
     177             :      
     178             :    }
     179           0 :    if(wConvSize>1) {
     180           0 :      os << "W projection using " << wConvSize << " planes" << LogIO::POST;
     181             :      
     182             :      os << "Using maximum possible W = " << maxUVW
     183           0 :         << " (wavelengths)" << LogIO::POST;
     184             :     
     185           0 :      Double invLambdaC=vb.frequency()(0)/C::c;
     186             :      os << "Typical wavelength = " << 1.0/invLambdaC
     187           0 :         << " (m)" << LogIO::POST;
     188             :      
     189             :     
     190           0 :      wScale=Float((wConvSize-1)*(wConvSize-1))/maxUVW;
     191             :      //wScale=Float(wConvSize-1)/maxUVW;
     192           0 :      wScaler_p=maxUVW;;
     193           0 :      os << "Scaling in W (at maximum W) = " << 1.0/wScale
     194           0 :         << " wavelengths per pixel" << LogIO::POST;
     195             :    }
     196             : 
     197           0 :    Int planesPerChunk=100;
     198             : 
     199             : 
     200           0 :    if(wConvSize>1) {
     201           0 :      Int maxMemoryMB=min(uInt64(HostInfo::memoryTotal(true)), uInt64(HostInfo::memoryFree()))/1024;
     202             :      ////Common you have to have 4 GB
     203           0 :      if(maxMemoryMB < 4000)
     204           0 :        maxMemoryMB=4000;
     205           0 :      convSize=max(Int(nx_p*padding),Int(ny_p*padding));
     206             :      ///Do the same thing as in WProject::init
     207           0 :      CompositeNumber cn(convSize);    
     208           0 :      convSize    = cn.nextLargerEven(convSize);
     209             :     //nominal  100 wprojplanes above that you may (or not) go swapping
     210             :      //cerr << "maxmem " << maxMemoryMB << " npixels " << sqrt(Double(maxMemoryMB)/8.0*1024.0*1024.0) << endl;
     211           0 :      planesPerChunk=Int((Double(maxMemoryMB)/8.0*1024.0*1024.0)/Double(convSize)/Double(convSize));
     212             :      //cerr << "planesPerChunk " << planesPerChunk << endl;
     213           0 :      planesPerChunk=min(planesPerChunk, 100);
     214             :      //    CompositeNumber cn(Int(maxConvSizeConsidered/2.0)*2);
     215           0 :     convSampling_p=4;
     216             :     
     217             :     //convSize=min(convSize,(Int)cn.nearestEven(Int(maxConvSizeConsidered/2.0)*2));
     218             : 
     219           0 :    }
     220             :    else{
     221           0 :      convSampling_p=1;
     222           0 :     convSize=max(Int(nx_p*padding),Int(ny_p*padding));
     223             :    }
     224           0 :    convSampling=convSampling_p;
     225           0 :    Int maxConvSize=convSize;
     226           0 :    convSupport.resize(wConvSize);
     227           0 :    convSupport.set(-1);
     228             :    ////set sampling
     229           0 :    AlwaysAssert(directionIndex>=0, AipsError);
     230           0 :    DirectionCoordinate dc=coords.directionCoordinate(directionIndex);
     231           0 :    Vector<Double> sampling;
     232           0 :    sampling = dc.increment();
     233           0 :    sampling*=Double(convSampling_p);
     234             :    //sampling*=Double(max(nx,ny))/Double(convSize);
     235           0 :    sampling[0]*=Double(padding*Float(nx_p))/Double(convSize);
     236           0 :    sampling[1]*=Double(padding*Float(ny_p))/Double(convSize);
     237             :    /////
     238           0 :    Int inner=convSize/convSampling_p;
     239             :    ConvolveGridder<Double, Complex>
     240           0 :      ggridder(IPosition(2, inner, inner), uvScale, uvOffset, "SF");
     241             :    
     242           0 :    Int nchunk=wConvSize/planesPerChunk;
     243           0 :    if((wConvSize%planesPerChunk) !=0)
     244           0 :      nchunk +=1;
     245           0 :    Vector<Int> chunksize(nchunk, planesPerChunk);
     246           0 :    if((wConvSize%planesPerChunk) !=0)
     247           0 :     chunksize(nchunk-1)=wConvSize%planesPerChunk;
     248             :    
     249           0 :    Int warner=0;
     250           0 :    Vector<Complex> maxes(wConvSize);
     251             :   // Bool maxdel;
     252             :   // Complex* maxptr=maxes.getStorage(maxdel);
     253           0 :   Matrix<Complex> corr(inner, inner);
     254           0 :   Vector<Complex> correction(inner);
     255           0 :    for (Int iy=-inner/2;iy<inner/2;iy++) {
     256             :      
     257           0 :      ggridder.correctX1D(correction, iy+inner/2);
     258           0 :      corr.row(iy+inner/2)=correction;
     259             :    }
     260             :    Bool cpcor;
     261             :   
     262           0 :    Complex *cor=corr.getStorage(cpcor);
     263           0 :    Vector<Int>pcsupp;
     264           0 :    pcsupp=convSupport;
     265             :    Bool delsupstor;
     266           0 :    Int* suppstor=pcsupp.getStorage(delsupstor);
     267           0 :    Double s1=sampling(1);
     268           0 :    Double s0=sampling(0);
     269             :    ///////////Por FFTPack
     270           0 :    Vector<Float> wsave(2*convSize*convSize+15);
     271           0 :    Int lsav=2*convSize*convSize+15;
     272             :    Bool wsavesave;
     273           0 :    Float *wsaveptr=wsave.getStorage(wsavesave);
     274             :    Int ier;
     275           0 :    FFTPack::cfft2i(convSize, convSize, wsaveptr, lsav, ier);
     276             :    ////////// 
     277           0 :    Matrix<Complex> screen(convSize, convSize);
     278           0 :    makeGWplane(screen, 0, s0, s1, wsaveptr, lsav, inner, cor, wScale);
     279           0 :    Float maxconv=abs(screen(0,0));
     280           0 :    for (Int chunkId=nchunk-1; chunkId >= 0;  --chunkId){
     281             :      //cerr << "chunkId " << chunkId << endl;
     282           0 :      Cube<Complex> convFuncSect( maxConvSize/2-1, maxConvSize/2-1, chunksize(chunkId));
     283           0 :      convFuncSect.set(0.0);
     284           0 :      Bool convFuncStor=false;
     285           0 :      Complex *convFuncPtr=convFuncSect.getStorage(convFuncStor);
     286             :       //////openmp like to share reference param ...but i don't like to share
     287           0 :      Int cpConvSize=maxConvSize;
     288             :      //cerr << "orig convsize " << convSize << endl;
     289             :      // Int cpWConvSize=wConvSize;
     290           0 :      Double cpWscale=wScale;
     291           0 :      Int wstart=planesPerChunk*chunkId;
     292           0 :      Int wend=wstart+chunksize(chunkId)-1;
     293             : #ifdef _OPENMP
     294           0 :      omp_set_nested(0);
     295             : #endif
     296           0 : #pragma omp parallel for default(none) firstprivate(/*cpWConvSize,*/ cpConvSize, convFuncPtr, s0, s1, wsaveptr, lsav, cor, inner, cpWscale,  wstart, wend) 
     297             :      for (Int iw=wstart; iw < (wend+1)  ; ++iw) {
     298             :        Matrix<Complex> screen1(cpConvSize, cpConvSize);
     299             :        makeGWplane(screen1, iw, s0, s1, wsaveptr, lsav, inner, cor, cpWscale);
     300             :        ooLong offset=ooLong(ooLong(iw-wstart)*ooLong(cpConvSize/2-1)*ooLong(cpConvSize/2-1));
     301             :        for (ooLong y=0; y< ooLong(cpConvSize/2)-1; ++y){
     302             :          for (ooLong x=0; x< ooLong(cpConvSize/2)-1; ++x){
     303             :            ////////convFuncPtr[offset+y*(convSize/2-1)+x] = quarter(x,y);
     304             :            convFuncPtr[offset+y*ooLong(cpConvSize/2-1)+x] = screen1(x,y);
     305             :          }
     306             :        }
     307             : 
     308             :      }//iw
     309           0 :      convFuncSect.putStorage(convFuncPtr, convFuncStor);
     310           0 :      for (uInt iw=0; iw< uInt(chunksize(chunkId)); ++iw){
     311           0 :        convFuncSect.xyPlane(iw)=convFuncSect.xyPlane(iw)/(maxconv);
     312             :      }
     313           0 :      convFuncPtr=convFuncSect.getStorage(convFuncStor);
     314           0 :      Int thischunkSize=chunksize(chunkId);
     315             :      //cerr << "chunkId* planesPerChunk " << chunkId* planesPerChunk << "  chunksize " << thischunkSize << endl;
     316           0 : #pragma omp parallel for default(none) firstprivate(suppstor, cpConvSize, /*cpWConvSize,*/ convFuncPtr, maxConvSize, thischunkSize, wstart, planesPerChunk, chunkId) reduction(+: warner)      
     317             :      for (Int iw=0; iw<thischunkSize; iw++) {
     318             :        Bool found=false;
     319             :        Int trial=0;
     320             :        ooLong ploffset=(ooLong)(cpConvSize/2-1)*(ooLong)(cpConvSize/2-1)*(ooLong)iw;
     321             :        for (trial=cpConvSize/2-2;trial>0;trial--) {
     322             :          // if((abs(convFunc(trial,0,iw))>1e-3)||(abs(convFunc(0,trial,iw))>1e-3) ) {
     323             :          if((abs(convFuncPtr[(ooLong)(trial)+ploffset])>1e-3)||(abs(convFuncPtr[(ooLong)(trial*(cpConvSize/2-1))+ploffset])>1e-3) ) {
     324             :            //cout <<"iw " << iw << " x " << abs(convFunc(trial,0,iw)) << " y " 
     325             :            //   <<abs(convFunc(0,trial,iw)) << endl; 
     326             :            found=true;
     327             :            break;
     328             :          }
     329             :        }
     330             :        Int trueIw=iw+chunkId* planesPerChunk;
     331             :        if(found) {
     332             :          suppstor[trueIw]=Int(0.5+Float(trial)/Float(convSampling_p))+1;
     333             :          if(suppstor[trueIw]*convSampling_p*2 >= maxConvSize){
     334             :            suppstor[trueIw]=cpConvSize/2/convSampling_p-1;
     335             :            ++warner;
     336             :          }
     337             :        }
     338             :        else{
     339             :          suppstor[trueIw]=cpConvSize/2/convSampling_p-1;
     340             :          ++warner;
     341             :        }
     342             :      }
     343           0 :      convFuncSect.putStorage(convFuncPtr, convFuncStor);
     344           0 :      if(chunkId==(nchunk-1)){
     345           0 :          Int newConvSize=2*(suppstor[wConvSize-1]+2)*convSampling;
     346           0 :          if(newConvSize < convSize){
     347           0 :            convFunc.resize((newConvSize/2-1),
     348           0 :                   (newConvSize/2-1),
     349             :                            wConvSize);
     350           0 :            convSize=newConvSize;
     351             :          }
     352             :          else{
     353           0 :            convFunc.resize((convSize/2-1),
     354           0 :                   (convSize/2-1),
     355             :                            wConvSize);
     356             :          }               
     357             :      }
     358           0 :     IPosition blc(3, 0,0,wstart);
     359           0 :     IPosition trc(3, (convSize/2-2),(convSize/2-2),wend);
     360           0 :     convFunc(blc, trc)=convFuncSect(IPosition(3, 0,0,0), IPosition(3, (convSize/2-2),
     361           0 :                                                                   (convSize/2-2), thischunkSize-1));
     362             : 
     363             : 
     364           0 :    }//chunkId
     365           0 :    corr.putStorage(cor, cpcor);
     366           0 :    pcsupp.putStorage(suppstor, delsupstor);
     367           0 :    convSupport=pcsupp;
     368           0 :    Double pbSum=0.0;
     369           0 :    for (Int iy=-convSupport(0);iy<=convSupport(0);iy++) {
     370           0 :      for (Int ix=-convSupport(0);ix<=convSupport(0);ix++) {
     371           0 :        pbSum+=real(convFunc(abs(ix)*convSampling_p,abs(iy)*convSampling_p,0));
     372             :      }
     373             :    }
     374           0 :    if(pbSum>0.0) {
     375           0 :      convFunc*=Complex(1.0/pbSum,0.0);
     376             :    }
     377             :    else {
     378             :      os << "Convolution function integral is not positive"
     379           0 :         << LogIO::EXCEPTION;
     380             :   } 
     381             : 
     382             : 
     383           0 :     os << "Convolution support = " << convSupport*convSampling_p
     384             :           << " pixels in Fourier plane"
     385           0 :           << LogIO::POST;
     386           0 :     convSupportBlock_p.resize(actualConvIndex_p+1);
     387           0 :     convSupportBlock_p[actualConvIndex_p]= new Vector<Int>();
     388           0 :     convSupportBlock_p[actualConvIndex_p]->assign(convSupport);
     389           0 :     convFunctions_p.resize(actualConvIndex_p+1);
     390           0 :     convFunctions_p[actualConvIndex_p]= new Cube<Complex>(convFunc);
     391           0 :     convSizes_p.resize(actualConvIndex_p+1, true);
     392           0 :     convSizes_p(actualConvIndex_p)=convSize;
     393           0 :     Int maxMemoryMB=HostInfo::memoryTotal(true)/1024;
     394             :   Int memoryMB;
     395           0 :   memoryMB = Int(Double(convSize/2-1)*Double(convSize/2-1)*
     396           0 :                  Double(wConvSize)*8.0/1024.0/1024.0);
     397             :   os << "Memory used in gridding function = "
     398             :      << memoryMB << " MB from maximum "
     399           0 :           << maxMemoryMB << " MB" << LogIO::POST;
     400           0 :   convSampling=convSampling_p;
     401           0 :   wScale=Float((wConvSize-1)*(wConvSize-1))/wScaler_p;
     402             : 
     403           0 : }//end func
     404             : 
     405           0 :   void WPConvFunc::makeGWplane(Matrix<Complex>& screen, const Int iw, Double s0, Double s1, Float *& wsaveptr, Int& lsav, Int& inner, Complex*& cor, Double&cpWscale){
     406             : 
     407           0 :     Int cpConvSize=screen.shape()(0);
     408             :     //cerr << "cpConvSize " << cpConvSize << "   shape " << screen.shape() << endl;
     409           0 :     screen.set(0.0);
     410             :      Bool cpscr;
     411           0 :      Complex *scr=screen.getStorage(cpscr);
     412           0 :       Double twoPiW=2.0*C::pi*Double(iw*iw)/cpWscale;
     413           0 :          for (Int iy=-inner/2;iy<inner/2;iy++) {
     414           0 :            Double m=s1*Double(iy);
     415           0 :            Double msq=m*m;
     416             :            //////Int offset= (iy+convSize/2)*convSize;
     417             :            ///fftpack likes it flipped
     418           0 :            ooLong offset= (iy>-1 ? ooLong(iy) : ooLong(iy+cpConvSize))*ooLong(cpConvSize);
     419           0 :            for (Int ix=-inner/2;ix<inner/2;ix++) {
     420             :              //////       Int ind=offset+ix+convSize/2;
     421             :              ///fftpack likes it flipped
     422           0 :              ooLong ind=offset+(ix > -1 ? ooLong(ix) : ooLong(ix+cpConvSize));
     423           0 :              Double l=s0*Double(ix);
     424           0 :              Double rsq=l*l+msq;
     425           0 :              if(rsq<1.0) {
     426           0 :                Double phase=twoPiW*(sqrt(1.0-rsq)-1.0);
     427             :                Double cval, sval;
     428           0 :                SINCOS(phase, sval, cval);
     429           0 :                Complex comval(cval, sval);
     430           0 :                scr[ind]=(cor[ix+inner/2+ (iy+inner/2)*inner])*comval;
     431             :                //screen(ix+convSize/2, iy+convSize/2)=comval; 
     432             :              }
     433             :            }
     434             :          }
     435             :          ////Por FFTPack
     436           0 :          Vector<Float>work(2*cpConvSize*cpConvSize);
     437           0 :          Int lenwrk=2*cpConvSize*cpConvSize;
     438             :          Bool worksave;
     439           0 :          Float *workptr=work.getStorage(worksave);
     440             :          Int ier;
     441           0 :          FFTPack::cfft2f(cpConvSize, cpConvSize, cpConvSize, scr, wsaveptr, lsav, workptr, lenwrk, ier);
     442             :        
     443           0 :        screen.putStorage(scr, cpscr);
     444             : 
     445           0 :   } 
     446           0 :   void WPConvFunc::findConvFunction2(const ImageInterface<Complex>& image, 
     447             :                                     const VisBuffer& vb,
     448             :                                     const Int& wConvSizeUser,
     449             :                                     const Vector<Double>& uvScale,
     450             :                                     const Vector<Double>& uvOffset, 
     451             :                                     const Float& padding,
     452             :                                     Int& convSampling,
     453             :                                     Cube<Complex>& convFunc, 
     454             :                                     Int& convSize,
     455             :                                     Vector<Int>& convSupport, Double& wScale){
     456             : 
     457             : 
     458             : 
     459             : 
     460           0 :   if(checkCenterPix(image)){ 
     461           0 :     convFunc.resize();
     462           0 :     convFunc.reference(convFunc_p);
     463           0 :     convSize=convSize_p;
     464           0 :     convSampling=convSampling_p;
     465           0 :     convSupport.resize();
     466           0 :     convSupport=convSupport_p;
     467           0 :     wScale=Float((convFunc.shape()(2)-1)*(convFunc.shape()(2)-1))/wScaler_p;
     468           0 :     return;
     469             :   }
     470             : 
     471             : 
     472           0 :   LogIO os;
     473           0 :   os << LogOrigin("WPConvFunc", "findConvFunction")  << LogIO::NORMAL;
     474             :   
     475             :   
     476             :   // Get the coordinate system
     477           0 :   CoordinateSystem coords(image.coordinates());
     478           0 :   Int directionIndex=coords.findCoordinate(Coordinate::DIRECTION);
     479           0 :   nx_p=Int(image.shape()(directionIndex)); 
     480           0 :   ny_p=Int(image.shape()(directionIndex+1));
     481             : 
     482           0 :   Int wConvSize=wConvSizeUser;
     483             :   ////Automatic mode
     484             :   Double maxUVW;
     485           0 :   if(wConvSize < 1){
     486             :     //cerr << "max, min, rms " << maxW_p << "  " << minW_p << "  " << rmsW_p << endl;
     487           0 :     maxUVW=rmsW_p < 0.5*(minW_p+maxW_p) ? 1.05*maxW_p: (rmsW_p /(0.5*((minW_p)+maxW_p))*1.05*maxW_p) ;
     488             :     //maxUVW=min(maxUVW, 0.25/abs(image.coordinates().increment()(0)));
     489           0 :     wConvSize=Int(maxUVW*fabs(sin(fabs(image.coordinates().increment()(0))*max(nx_p, ny_p)/2.0)));
     490             :     //maxUVW=1.05*maxW_p;
     491             :     //wConvSize=100*(maxUVW*maxUVW*image.coordinates().increment()(0)*image.coordinates().increment()(0));
     492             :     //cerr << "wConvSize 0 " << wConvSize << " nx_p " << nx_p << endl;
     493             :     //if(rmsW_p < 0.5*(minW_p+maxW_p))
     494             :     // wConvSize=wConvSize*(minW_p+maxW_p)*(minW_p+maxW_p)/(rmsW_p*rmsW_p);
     495             : 
     496           0 :     convSupport.resize(wConvSize);
     497             :   }
     498             :   else{
     499             :     
     500             :     
     501           0 :     if(maxW_p> 0.0)
     502           0 :       maxUVW= 1.05*maxW_p;
     503             :     else
     504           0 :       maxUVW=0.25/abs(image.coordinates().increment()(0));
     505             : 
     506             :   }
     507           0 :   if(wConvSize>1) {
     508           0 :     os << "W projection using " << wConvSize << " planes" << LogIO::POST;
     509             :     
     510             :     os << "Using maximum possible W = " << maxUVW
     511           0 :             << " (wavelengths)" << LogIO::POST;
     512             :     
     513           0 :     Double invLambdaC=vb.frequency()(0)/C::c;
     514             :     os << "Typical wavelength = " << 1.0/invLambdaC
     515           0 :             << " (m)" << LogIO::POST;
     516             :     
     517             :     //    uvScale(2)=sqrt(Float(wConvSize-1))/maxUVW;
     518             :     //    uvScale(2)=(Float(wConvSize-1))/maxUVW;
     519           0 :     wScale=Float((wConvSize-1)*(wConvSize-1))/maxUVW;
     520             :     //wScale=Float(wConvSize-1)/maxUVW;
     521           0 :     wScaler_p=maxUVW;;
     522           0 :     os << "Scaling in W (at maximum W) = " << 1.0/wScale
     523           0 :             << " wavelengths per pixel" << LogIO::POST;
     524             :   }
     525             : 
     526           0 :   Timer tim;
     527             :   
     528             :   // Set up the convolution function. 
     529           0 :   if(wConvSize>1) {
     530             :     /* if(wConvSize>256) {
     531             :       convSampling=4;
     532             :       convSize=min(nx,ny); 
     533             :       Int maxMemoryMB=HostInfo::memoryTotal()/1024; 
     534             :       if(maxMemoryMB > 4000){
     535             :         convSize=min(convSize,1024);
     536             :       }
     537             :       else{
     538             :         convSize=min(convSize,512);
     539             :       }
     540             : 
     541             :     }
     542             :     else {
     543             :       convSampling=4;
     544             :       convSize=min(nx,ny);
     545             :       convSize=min(convSize,1024);
     546             :     }
     547             :     */
     548             :     // use memory size defined in aipsrc if exists
     549           0 :     Int maxMemoryMB=HostInfo::memoryTotal(true)/1024;
     550             :     //nominal  512 wprojplanes above that you may (or not) go swapping
     551           0 :     Double maxConvSizeConsidered=sqrt(Double(maxMemoryMB)/8.0*1024.0*1024.0/Double(wConvSize));
     552           0 :     CompositeNumber cn(Int(maxConvSizeConsidered/2.0)*2);
     553             :     
     554           0 :     convSampling_p=4;
     555           0 :     convSize=max(Int(nx_p*padding),Int(ny_p*padding));
     556           0 :     convSize=min(convSize,(Int)cn.nearestEven(Int(maxConvSizeConsidered/2.0)*2));
     557             : 
     558             :     
     559           0 :   }
     560             :   else {
     561           0 :     convSampling_p=1;
     562           0 :     convSize=max(Int(nx_p*padding),Int(ny_p*padding));
     563             :   }
     564           0 :   convSampling=convSampling_p;
     565           0 :   Int maxConvSize=convSize;
     566             :   
     567             :   
     568             :   // Make a two dimensional image to calculate the
     569             :   // primary beam. We want this on a fine grid in the
     570             :   // UV plane 
     571           0 :   CompositeNumber cn(uInt(nx_p*2)); 
     572           0 :   AlwaysAssert(directionIndex>=0, AipsError);
     573           0 :   DirectionCoordinate dc=coords.directionCoordinate(directionIndex);
     574           0 :   Vector<Double> sampling;
     575           0 :   sampling = dc.increment();
     576           0 :   sampling*=Double(convSampling_p);
     577             :   //sampling*=Double(max(nx,ny))/Double(convSize);
     578           0 :   sampling[0]*=Double(cn.nextLargerEven(Int(padding*Float(nx_p)-0.5)))/Double(convSize);
     579           0 :   sampling[1]*=Double(cn.nextLargerEven(Int(padding*Float(ny_p)-0.5)))/Double(convSize);
     580           0 :   dc.setIncrement(sampling);
     581             :   
     582           0 :   Vector<Double> unitVec(2);
     583           0 :   unitVec=convSize/2;
     584           0 :   dc.setReferencePixel(unitVec);
     585             :   
     586             :   // Set the reference value to that of the image center for sure.
     587             :   {
     588             :     // dc.setReferenceValue(mTangent_p.getAngle().getValue());
     589           0 :     MDirection wcenter;  
     590           0 :     Vector<Double> pcenter(2);
     591           0 :     pcenter(0) = nx_p/2;
     592           0 :     pcenter(1) = ny_p/2;    
     593           0 :     coords.directionCoordinate(directionIndex).toWorld( wcenter, pcenter );
     594           0 :     dc.setReferenceValue(wcenter.getAngle().getValue());
     595           0 :   }
     596           0 :   coords.replaceCoordinate(dc, directionIndex);
     597             :   //  coords.list(os, MDoppler::RADIO, IPosition(), IPosition());
     598             :   
     599           0 :   IPosition pbShape(4, convSize, convSize, 1, 1);
     600           0 :   TempImage<Complex> twoDPB(pbShape, coords);
     601             : 
     602           0 :   Int inner=convSize/convSampling_p;
     603             :   ConvolveGridder<Double, Complex>
     604           0 :     ggridder(IPosition(2, inner, inner), uvScale, uvOffset, "SF");
     605             :   /*
     606             :   ConvolveGridder<Double, Complex>
     607             :     ggridder(IPosition(2, cn.nextLargerEven(Int(padding*Float(nx_p)-0.5)), 
     608             :                        cn.nextLargerEven(Int(padding*Float(ny_p)-0.5))), uvScale, 
     609             :              uvOffset, "SF");
     610             :   */
     611           0 :   convFunc.resize(); // break any reference 
     612           0 :   convFunc.resize(convSize/2-1, convSize/2-1, wConvSize);
     613           0 :   convFunc.set(0.0);
     614           0 :   Bool convFuncStor=false;
     615           0 :   Complex *convFuncPtr=convFunc.getStorage(convFuncStor);
     616             : 
     617           0 :   IPosition start(4, 0, 0, 0, 0);
     618           0 :   IPosition pbSlice(4, convSize, convSize, 1, 1);
     619             :   
     620             :   //Bool writeResults=false;
     621           0 :   Int warner=0;
     622             : 
     623             : 
     624             :   // Accumulate terms 
     625             :   //Matrix<Complex> screen(convSize, convSize);
     626             :   //screen.set(Complex(0.0));
     627           0 :   Vector<Complex> maxes(wConvSize);
     628             :   Bool maxdel;
     629           0 :   Complex* maxptr=maxes.getStorage(maxdel);
     630           0 :   Matrix<Complex> corr(inner, inner);
     631           0 :   Vector<Complex> correction(inner);
     632           0 :    for (Int iy=-inner/2;iy<inner/2;iy++) {
     633             :      
     634           0 :      ggridder.correctX1D(correction, iy+inner/2);
     635           0 :      corr.row(iy+inner/2)=correction;
     636             :    }
     637             :    Bool cpcor;
     638             :   
     639           0 :    Complex *cor=corr.getStorage(cpcor);
     640           0 :    Double s1=sampling(1);
     641           0 :    Double s0=sampling(0);
     642             :    ///////////Por FFTPack
     643           0 :    Vector<Float> wsave(2*convSize*convSize+15);
     644           0 :    Int lsav=2*convSize*convSize+15;
     645             :    Bool wsavesave;
     646           0 :    Float *wsaveptr=wsave.getStorage(wsavesave);
     647             :    Int ier;
     648           0 :    FFTPack::cfft2i(convSize, convSize, wsaveptr, lsav, ier);
     649             :    //////////
     650             : #ifdef _OPENMP
     651           0 :    omp_set_nested(0);
     652             : #endif
     653             :    //////openmp like to share reference param ...but i don't like to share
     654           0 :    Int cpConvSize=convSize;
     655           0 :    Int cpWConvSize=wConvSize;
     656           0 :    Double cpWscale=wScale;
     657             :    //Float max0=1.0;
     658           0 : #pragma omp parallel for default(none) firstprivate(cpWConvSize, cpConvSize, convFuncPtr, s0, s1, wsaveptr, ier, lsav, cor, inner, maxptr, cpWscale, C::pi )
     659             : 
     660             :   for (Int iw=0; iw< cpWConvSize;iw++) {
     661             :     // First the w term
     662             :     Matrix<Complex> screen(cpConvSize, cpConvSize);
     663             :     screen=0.0;
     664             :     Bool cpscr;
     665             :     Complex *scr=screen.getStorage(cpscr);
     666             :     if(cpWConvSize>1) {
     667             :       //      Double twoPiW=2.0*C::pi*sqrt(Double(iw))/uvScale(2);
     668             :       //Double twoPiW=2.0*C::pi*Double(iw)/wScale_p;
     669             :       Double twoPiW=2.0*C::pi*Double(iw*iw)/cpWscale;
     670             :       for (Int iy=-inner/2;iy<inner/2;iy++) {
     671             :         Double m=s1*Double(iy);
     672             :         Double msq=m*m;
     673             :         //////Int offset= (iy+convSize/2)*convSize;
     674             :         ///fftpack likes it flipped
     675             :         ooLong offset= (iy>-1 ? ooLong(iy) : ooLong(iy+cpConvSize))*ooLong(cpConvSize);
     676             :         for (Int ix=-inner/2;ix<inner/2;ix++) {
     677             :           //////          Int ind=offset+ix+convSize/2;
     678             :           ///fftpack likes it flipped
     679             :           ooLong ind=offset+(ix > -1 ? ooLong(ix) : ooLong(ix+cpConvSize));
     680             :           Double l=s0*Double(ix);
     681             :           Double rsq=l*l+msq;
     682             :           if(rsq<1.0) {
     683             :             Double phase=twoPiW*(sqrt(1.0-rsq)-1.0);
     684             :             Double cval, sval;
     685             :             SINCOS(phase, sval, cval);
     686             :             Complex comval(cval, sval);
     687             :             scr[ind]=(cor[ix+inner/2+ (iy+inner/2)*inner])*comval;
     688             :             //screen(ix+convSize/2, iy+convSize/2)=comval; 
     689             :           }
     690             :         }
     691             :       }
     692             :     }
     693             :     else {
     694             :       screen=1.0;
     695             :     }
     696             :     /////////screen.putStorage(scr, cpscr);
     697             :     
     698             :     // spheroidal function
     699             :     /*    Vector<Complex> correction(inner);
     700             :     for (Int iy=-inner/2;iy<inner/2;iy++) {
     701             :       ggridder.correctX1D(correction, iy+inner/2);
     702             :       for (Int ix=-inner/2;ix<inner/2;ix++) {
     703             :         screen(ix+convSize/2,iy+convSize/2)*=correction(ix+inner/2);
     704             :       }
     705             :     }
     706             :     */
     707             :     //twoDPB.putSlice(screen, IPosition(4, 0));
     708             :     // Write out screen as an image
     709             :     /*if(writeResults) {
     710             :       ostringstream name;
     711             :       name << "Screen" << iw+1;
     712             :       if(Table::canDeleteTable(name)) Table::deleteTable(name);
     713             :       PagedImage<Float> thisScreen(pbShape, coords, name);
     714             :       LatticeExpr<Float> le(real(twoDPB));
     715             :       thisScreen.copyData(le);
     716             :     }
     717             :     */
     718             : 
     719             :     
     720             :  // Now FFT and get the result back
     721             :     //LatticeFFT::cfft2d(twoDPB);
     722             :     /////////Por FFTPack
     723             :     Vector<Float>work(2*cpConvSize*cpConvSize);
     724             :     Int lenwrk=2*cpConvSize*cpConvSize;
     725             :     Bool worksave;
     726             :     Float *workptr=work.getStorage(worksave);
     727             :     FFTPack::cfft2f(cpConvSize, cpConvSize, cpConvSize, scr, wsaveptr, lsav, workptr, lenwrk, ier);
     728             :    
     729             :     screen.putStorage(scr, cpscr);
     730             :     /////////////////////
     731             :     // Write out FT of screen as an image
     732             :     /*if(1) {
     733             :       CoordinateSystem ftCoords(coords);
     734             :       directionIndex=ftCoords.findCoordinate(Coordinate::DIRECTION);
     735             :       AlwaysAssert(directionIndex>=0, AipsError);
     736             :       dc=coords.directionCoordinate(directionIndex);
     737             :       Vector<Bool> axes(2); axes(0)=true;axes(1)=true;
     738             :       Vector<Int> shape(2); shape(0)=convSize;shape(1)=convSize;
     739             :       Coordinate* ftdc=dc.makeFourierCoordinate(axes,shape);
     740             :       ftCoords.replaceCoordinate(*ftdc, directionIndex);
     741             :       delete ftdc; ftdc=0;
     742             :       ostringstream name;
     743             :       name << "FTScreen" << iw+1;
     744             :       if(Table::canDeleteTable(name)) Table::deleteTable(name);
     745             :       PagedImage<Float> thisScreen(pbShape, ftCoords, name);
     746             :       //LatticeExpr<Float> le(real(twoDPB));
     747             :       //thisScreen.copyData(le);
     748             :       thisScreen.put(real(screen));
     749             :     }
     750             :     */
     751             :     ////////IPosition start(4, convSize/2, convSize/2, 0, 0);
     752             :     ////////IPosition pbSlice(4, convSize/2-1, convSize/2-1, 1, 1);
     753             :     ///////convFunc.xyPlane(iw)=twoDPB.getSlice(start, pbSlice, true);
     754             :     //////Matrix<Complex> quarter(twoDPB.getSlice(start, pbSlice, true));
     755             :     //   cerr << "quartershape " << quarter.shape() << endl;
     756             :     ooLong offset=ooLong(ooLong(iw)*ooLong(cpConvSize/2-1)*ooLong(cpConvSize/2-1));
     757             :     //    cerr << "offset " << offset << " convfuncshape " << convFunc.shape() << " convSize " << convSize  << endl;
     758             :     maxptr[iw]=screen(0,0);
     759             :     for (ooLong y=0; y< ooLong(cpConvSize/2)-1; ++y){
     760             :       for (ooLong x=0; x< ooLong(cpConvSize/2)-1; ++x){
     761             :         ////////convFuncPtr[offset+y*(convSize/2-1)+x] = quarter(x,y);
     762             :         convFuncPtr[offset+y*ooLong(cpConvSize/2-1)+x] = screen(x,y);
     763             :       }
     764             :     }
     765             :   }
     766             :   
     767           0 :   convFunc.putStorage(convFuncPtr, convFuncStor);
     768           0 :   corr.putStorage(cor, cpcor);
     769           0 :   maxes.putStorage(maxptr, maxdel);
     770           0 :   cerr << "maxes " << maxes << endl;
     771             :   //tim.show("After convFunc making ");
     772             : //Complex maxconv=max(abs(convFunc));
     773           0 :  Complex maxconv=max(abs(maxes));
     774             :  //cerr << maxes << " maxconv " << maxconv << endl;
     775             :  //Do it by plane as the / operator makes a copy of the whole array
     776           0 :  for (uInt iw=0; iw< uInt(wConvSize); ++iw)
     777           0 :    convFunc.xyPlane(iw)=convFunc.xyPlane(iw)/real(maxconv);
     778             :  //tim.show("After convFunc norming ");
     779             :   // Find the edge of the function by stepping in from the
     780             :   // uv plane edge. We do this for each plane to save time on the
     781             :   // gridding (about a factor of two)
     782           0 :   convSupport=-1;
     783           0 :   Vector<Int> pcsupp=convSupport;
     784             : #ifdef _OPENMP
     785           0 :   omp_set_nested(0);
     786             : #endif
     787             :   Bool delsupstor;
     788           0 :   Int* suppstor=pcsupp.getStorage(delsupstor);
     789           0 :   convFuncPtr=convFunc.getStorage(convFuncStor);
     790           0 : #pragma omp parallel for default(none) firstprivate(suppstor, cpConvSize, cpWConvSize, convFuncPtr, maxConvSize) reduction(+: warner) 
     791             :   for (Int iw=0;iw<cpWConvSize;iw++) {
     792             :     Bool found=false;
     793             :     Int trial=0;
     794             :     ooLong ploffset=(ooLong)(cpConvSize/2-1)*(ooLong)(cpConvSize/2-1)*(ooLong)iw;
     795             :     for (trial=cpConvSize/2-2;trial>0;trial--) {
     796             :       // if((abs(convFunc(trial,0,iw))>1e-3)||(abs(convFunc(0,trial,iw))>1e-3) ) {
     797             :       if((abs(convFuncPtr[(ooLong)(trial)+ploffset])>1e-3)||(abs(convFuncPtr[(ooLong)(trial*(cpConvSize/2-1))+ploffset])>1e-3) ) {
     798             :         //cout <<"iw " << iw << " x " << abs(convFunc(trial,0,iw)) << " y " 
     799             :         //   <<abs(convFunc(0,trial,iw)) << endl; 
     800             :         found=true;
     801             :         break;
     802             :       }
     803             :     }
     804             :     if(found) {
     805             :       suppstor[iw]=Int(0.5+Float(trial)/Float(convSampling_p))+1;
     806             :       if(suppstor[iw]*convSampling_p*2 >= maxConvSize){
     807             :         suppstor[iw]=cpConvSize/2/convSampling_p-1;
     808             :         ++warner;
     809             :       }
     810             :     }
     811             :     else{
     812             :       suppstor[iw]=cpConvSize/2/convSampling_p-1;
     813             :       ++warner;
     814             :     }
     815             :   }
     816           0 :   pcsupp.putStorage(suppstor, delsupstor);
     817           0 :   convSupport=pcsupp;
     818             :   //tim.show("After suppport locing ");
     819           0 :   if(convSupport(0)<1) {
     820             :     os << "Convolution function is misbehaved - support seems to be zero"
     821           0 :             << LogIO::EXCEPTION;
     822             :   }
     823             : 
     824           0 :   if(warner > 5) {
     825             :     os << LogIO::WARN 
     826             :             <<"Many of the Convolution functions go beyond " << maxConvSize 
     827           0 :             <<" pixels allocated" << LogIO::POST;
     828             :     os << LogIO::WARN
     829             :             << "You may consider reducing the size of your image or use facets"
     830           0 :             << LogIO::POST;
     831             :   }
     832             :   /*
     833             :   if(1) {
     834             :       CoordinateSystem ftCoords(coords);
     835             :       Int directionIndex=ftCoords.findCoordinate(Coordinate::DIRECTION);
     836             :       AlwaysAssert(directionIndex>=0, AipsError);
     837             :       dc=coords.directionCoordinate(directionIndex);
     838             :       Vector<Bool> axes(2); axes(0)=true;axes(1)=true;
     839             :       Vector<Int> shape(2); shape(0)=convSize;shape(1)=convSize;
     840             :       Coordinate* ftdc=dc.makeFourierCoordinate(axes,shape);
     841             :       ftCoords.replaceCoordinate(*ftdc, directionIndex);
     842             :       delete ftdc; ftdc=0;
     843             :       ostringstream name;
     844             :       name << "FTScreenWproj" ;
     845             :       if(Table::canDeleteTable(name)) Table::deleteTable(name);
     846             :       PagedImage<Complex> thisScreen(IPosition(4, convFunc.shape()(0), convFunc.shape()(1), 1, convFunc.shape()(2)), ftCoords, name);
     847             :       thisScreen.put(convFunc.reform(IPosition(4, convFunc.shape()(0), convFunc.shape()(1), 1, convFunc.shape()(2))));
     848             :   }
     849             :   */
     850             : 
     851             : 
     852             :   // Normalize such that plane 0 sums to 1 (when jumping in
     853             :   // steps of convSampling)
     854           0 :   Double pbSum=0.0;
     855           0 :   for (Int iy=-convSupport(0);iy<=convSupport(0);iy++) {
     856           0 :     for (Int ix=-convSupport(0);ix<=convSupport(0);ix++) {
     857           0 :       pbSum+=real(convFunc(abs(ix)*convSampling_p,abs(iy)*convSampling_p,0));
     858             :     }
     859             :   }
     860           0 :   if(pbSum>0.0) {
     861           0 :     convFunc*=Complex(1.0/pbSum,0.0);
     862             :   }
     863             :   else {
     864             :     os << "Convolution function integral is not positive"
     865           0 :             << LogIO::EXCEPTION;
     866             :   } 
     867           0 :   os << "Convolution support = " << convSupport*convSampling_p
     868             :           << " pixels in Fourier plane"
     869           0 :           << LogIO::POST;
     870             : 
     871             :   //tim.show("After pbsumming ");
     872             : 
     873           0 :   convSupportBlock_p.resize(actualConvIndex_p+1);
     874           0 :   convSupportBlock_p[actualConvIndex_p]= new Vector<Int>();
     875           0 :   convSupportBlock_p[actualConvIndex_p]->assign(convSupport);
     876           0 :   convFunctions_p.resize(actualConvIndex_p+1);
     877           0 :   convFunctions_p[actualConvIndex_p]= new Cube<Complex>();
     878           0 :   Int newConvSize=2*(max(convSupport)+2)*convSampling;
     879             :   
     880           0 :   if(newConvSize < convSize){
     881           0 :     IPosition blc(3, 0,0,0);
     882           0 :     IPosition trc(3, (newConvSize/2-2),
     883           0 :                   (newConvSize/2-2),
     884           0 :                   convSupport.shape()(0)-1);
     885             :    
     886           0 :     *(convFunctions_p[actualConvIndex_p])=convFunc(blc,trc);
     887             :     // convFunctions_p[actualConvIndex_p]->assign(Cube<Complex>(convFunc(blc,trc)));
     888           0 :     convSize=newConvSize;
     889           0 :   }
     890             :   else{
     891           0 :     *(convFunctions_p[actualConvIndex_p])=convFunc;
     892             :   }
     893             :   // read out memory size from aisprc if exists
     894           0 :   Int maxMemoryMB=HostInfo::memoryTotal(true)/1024;
     895             :   Int memoryMB;
     896           0 :   memoryMB = Int(Double(convSize/2-1)*Double(convSize/2-1)*
     897           0 :                  Double(wConvSize)*8.0/1024.0/1024.0);
     898             :   os << "Memory used in gridding function = "
     899             :           << memoryMB << " MB from maximum "
     900           0 :           << maxMemoryMB << " MB" << LogIO::POST;
     901           0 :   convFunc.resize();
     902           0 :   convFunc.reference(*convFunctions_p[actualConvIndex_p]);
     903           0 :   convSizes_p.resize(actualConvIndex_p+1, true);
     904           0 :   convSizes_p(actualConvIndex_p)=convSize;
     905             : 
     906           0 :   convSampling=convSampling_p;
     907           0 :   wScale=Float((wConvSize-1)*(wConvSize-1))/wScaler_p;
     908             :   //tim.show("After calculating WConv funx ");
     909             : 
     910             : 
     911             : 
     912           0 :   }
     913             : 
     914           0 : Bool WPConvFunc::checkCenterPix(const ImageInterface<Complex>& image){
     915             : 
     916           0 :   CoordinateSystem imageCoord=image.coordinates();
     917           0 :   MDirection wcenter;  
     918           0 :   Int directionIndex=imageCoord.findCoordinate(Coordinate::DIRECTION);
     919             :   DirectionCoordinate
     920           0 :     directionCoord=imageCoord.directionCoordinate(directionIndex);
     921           0 :   Vector<Double> incr=directionCoord.increment();
     922           0 :   nx_p=image.shape()(directionIndex);
     923           0 :   ny_p=image.shape()(directionIndex+1);
     924             : 
     925             : 
     926             :   //Images with same number of pixels and increments can have the same conv functions
     927           0 :   ostringstream oos;
     928           0 :   oos << std::setprecision(6);
     929             : 
     930           0 :   oos << nx_p << "_"<< fabs(incr(0)) << "_";
     931           0 :   oos << ny_p << "_"<< fabs(incr(1));
     932           0 :   String imageKey(oos);
     933             : 
     934           0 :   if(convFunctionMap_p.size( ) == 0){
     935           0 :     convFunctionMap_p.insert(std::pair<casacore::String, casacore::Int>(imageKey, 0));
     936           0 :     actualConvIndex_p=0;
     937           0 :     return false;
     938             :   }
     939             :    
     940           0 :   if( convFunctionMap_p.find(imageKey) == convFunctionMap_p.end( ) ){
     941           0 :     actualConvIndex_p=convFunctionMap_p.size( );
     942           0 :     convFunctionMap_p.insert(std::pair<casacore::String, casacore::Int>(imageKey,actualConvIndex_p));
     943           0 :     return false;
     944             :   }
     945             :   else{
     946           0 :     actualConvIndex_p=convFunctionMap_p[imageKey];
     947           0 :     convFunc_p.resize(); // break any reference
     948           0 :     convFunc_p.reference(*convFunctions_p[actualConvIndex_p]);
     949           0 :     convSupport_p.resize();
     950           0 :     convSupport_p.reference(*convSupportBlock_p[actualConvIndex_p]);
     951           0 :     convSize_p=convSizes_p[actualConvIndex_p];
     952             : 
     953             :   }
     954             : 
     955           0 :   return true;
     956           0 : }
     957             : 
     958           0 : Bool WPConvFunc::toRecord(RecordInterface& rec){
     959             : 
     960           0 :   Int numConv=convFunctions_p.nelements();
     961             :   try{
     962           0 :     rec.define("numconv", numConv);
     963           0 :     auto convptr = convFunctionMap_p.begin( );
     964           0 :     for (Int k=0; k < numConv; ++k, ++convptr){
     965           0 :       rec.define("convfunctions"+String::toString(k), *(convFunctions_p[k]));
     966           0 :       rec.define("convsupportblock"+String::toString(k), *(convSupportBlock_p[k]));
     967           0 :       rec.define("key"+String::toString(k), convptr->first);
     968           0 :       rec.define("val"+String::toString(k), convptr->second);
     969             :     }
     970           0 :     rec.define("convsizes", convSizes_p);
     971           0 :     rec.define("actualconvIndex",actualConvIndex_p);
     972           0 :     rec.define("convsize", convSize_p);
     973           0 :     rec.define("convsupport", convSupport_p);
     974           0 :     rec.define("convfunc",convFunc_p);
     975           0 :     rec.define("wscaler", wScaler_p);
     976           0 :     rec.define("convsampling", convSampling_p);
     977           0 :     rec.define("nx", nx_p);
     978           0 :     rec.define("ny", ny_p);
     979             :   }
     980           0 :   catch(AipsError x) {
     981           0 :     return false;
     982           0 :   }
     983           0 :   return true;
     984             : 
     985             :  
     986             : 
     987             : }
     988             : 
     989           0 :  Bool WPConvFunc::fromRecord(String& err, const RecordInterface& rec){
     990             :   
     991           0 :   Int numConv=0;
     992             :   try{
     993           0 :     rec.get("numconv", numConv);
     994           0 :     convFunctions_p.resize(numConv, true, false);
     995           0 :     convSupportBlock_p.resize(numConv, true, false);
     996           0 :     convFunctionMap_p.clear( );
     997           0 :     for (Int k=0; k < numConv; ++k){
     998           0 :       convFunctions_p[k]=new Cube<Complex>();
     999           0 :       convSupportBlock_p[k]=new Vector<Int>();
    1000           0 :       rec.get("convfunctions"+String::toString(k), *(convFunctions_p[k]));
    1001           0 :       rec.get("convsupportblock"+String::toString(k), *(convSupportBlock_p[k]));
    1002           0 :       String key;
    1003             :       Int val;
    1004           0 :       rec.get("key"+String::toString(k), key);
    1005           0 :       rec.get("val"+String::toString(k), val);
    1006           0 :       convFunctionMap_p.insert(std::pair<casacore::String, casacore::Int>(key,val));
    1007           0 :     }
    1008           0 :     rec.get("convsizes", convSizes_p);
    1009           0 :     rec.get("actualconvIndex",actualConvIndex_p);
    1010           0 :     rec.get("convsize", convSize_p);
    1011           0 :     rec.get("convsupport", convSupport_p);
    1012           0 :     rec.get("convfunc",convFunc_p);
    1013           0 :     if(rec.isDefined("wscaler"))
    1014           0 :        rec.get("wscaler", wScaler_p);
    1015           0 :     rec.get("convsampling", convSampling_p);
    1016           0 :     rec.get("nx", nx_p);
    1017           0 :     rec.get("ny", ny_p);
    1018             :   }
    1019           0 :   catch(AipsError x) {
    1020           0 :     err=x.getMesg();
    1021           0 :     return false;
    1022           0 :   }
    1023           0 :   return true;
    1024             : 
    1025             :   }
    1026             : 
    1027             : 
    1028             : 
    1029             : 
    1030             : 
    1031             : } //# NAMESPACE CASA - END

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