LCOV - code coverage report
Current view: top level - synthesis/ImagerObjects - SynthesisImagerVi2.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 1783 0.0 %
Date: 2024-10-09 13:55:54 Functions: 0 46 0.0 %

          Line data    Source code
       1             : //# SynthesisImagerVi2.cc: Implementation of SynthesisImager.h
       2             : //# Copyright (C) 1997-2019
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //# This library is free software; you can redistribute it and/or modify it
       5             : //# under the terms of the GNU General Public License as published by
       6             : //# the Free Software Foundation; either version 3 of the License, or (at your
       7             : //# option) any later version.
       8             : //#
       9             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      10             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      11             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
      12             : //# License for more details.
      13             : //#
      14             : //# https://www.gnu.org/licenses/
      15             : //#
      16             : //# You should have received a copy of the GNU  General Public License
      17             : //# along with this library; if not, write to the Free Software Foundation,
      18             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      19             : //#
      20             : //# Queries concerning CASA should be submitted at
      21             : //#        https://help.nrao.edu
      22             : //#
      23             : //#        Postal address: CASA Project Manager 
      24             : //#                        National Radio Astronomy Observatory
      25             : //#                        520 Edgemont Road
      26             : //#                        Charlottesville, VA 22903-2475 USA
      27             : //#
      28             : //#
      29             : //# $Id$
      30             : 
      31             : #define CFC_VERBOSE false /* Control the verbosity when building CFCache. */
      32             : 
      33             : #include <casacore/casa/Exceptions/Error.h>
      34             : #include <iostream>
      35             : #include <sstream>
      36             : 
      37             : #include <casacore/casa/Arrays/Matrix.h>
      38             : #include <casacore/casa/Arrays/ArrayMath.h>
      39             : #include <casacore/casa/Arrays/ArrayLogical.h>
      40             : 
      41             : 
      42             : #include <casacore/casa/Logging.h>
      43             : #include <casacore/casa/Logging/LogIO.h>
      44             : #include <casacore/casa/Logging/LogMessage.h>
      45             : #include <casacore/casa/Logging/LogSink.h>
      46             : #include <casacore/casa/Logging/LogMessage.h>
      47             : #include <casacore/casa/System/ProgressMeter.h>
      48             : 
      49             : #include <casacore/casa/OS/DirectoryIterator.h>
      50             : #include <casacore/casa/OS/File.h>
      51             : #include <casacore/casa/OS/HostInfo.h>
      52             : #include <casacore/casa/OS/Path.h>
      53             : //#include <casa/OS/Memory.h>
      54             : 
      55             : #include <casacore/lattices/LRegions/LCBox.h>
      56             : 
      57             : #include <casacore/measures/Measures/MeasTable.h>
      58             : 
      59             : #include <casacore/ms/MeasurementSets/MSHistoryHandler.h>
      60             : #include <casacore/ms/MeasurementSets/MeasurementSet.h>
      61             : #include <casacore/ms/MSSel/MSSelection.h>
      62             : 
      63             : 
      64             : #include <synthesis/ImagerObjects/SynthesisImagerVi2.h>
      65             : 
      66             : #include <synthesis/ImagerObjects/SynthesisUtilMethods.h>
      67             : #include <synthesis/ImagerObjects/SIImageStore.h>
      68             : #include <synthesis/ImagerObjects/SIImageStoreMultiTerm.h>
      69             : #include <synthesis/ImagerObjects/CubeMajorCycleAlgorithm.h>
      70             : #include <synthesis/ImagerObjects/CubeMakeImageAlgorithm.h>
      71             : #include <synthesis/MeasurementEquations/VPManager.h>
      72             : #include <imageanalysis/Utilities/SpectralImageUtil.h>
      73             : #include <msvis/MSVis/MSUtil.h>
      74             : #include <msvis/MSVis/VisSetUtil.h>
      75             : #include <msvis/MSVis/VisImagingWeight.h>
      76             : 
      77             : #include <synthesis/TransformMachines2/GridFT.h>
      78             : #include <synthesis/TransformMachines2/WPConvFunc.h>
      79             : #include <synthesis/TransformMachines2/WProjectFT.h>
      80             : #include <synthesis/TransformMachines2/VisModelData.h>
      81             : #include <synthesis/TransformMachines2/AWProjectFT.h>
      82             : #include <synthesis/TransformMachines2/HetArrayConvFunc.h>
      83             : #include <synthesis/TransformMachines2/MosaicFTNew.h>
      84             : #include <synthesis/TransformMachines2/AWPLPG.h>
      85             : #include <synthesis/TransformMachines2/MultiTermFTNew.h>
      86             : #include <synthesis/TransformMachines2/AWProjectWBFTNew.h>
      87             : #include <synthesis/TransformMachines2/AWConvFunc.h>
      88             : //#include <synthesis/TransformMachines2/AWConvFuncEPJones.h>
      89             : #include <synthesis/TransformMachines2/NoOpATerm.h>
      90             : #include <synthesis/TransformMachines2/SDGrid.h>
      91             : #include <synthesis/TransformMachines/WProjectFT.h>
      92             : #include <synthesis/TransformMachines2/BriggsCubeWeightor.h>
      93             : #include <casacore/casa/Utilities/Regex.h>
      94             : #include <casacore/casa/OS/Directory.h>
      95             : #include <msvis/MSVis/VisibilityIteratorImpl2.h>
      96             : //#include <casadbus/utilities/BusAccess.h>
      97             : //#include <casadbus/session/DBusSession.h>
      98             : 
      99             : #include <sys/types.h>
     100             : #include <unistd.h>
     101             : #include <iomanip>
     102             : #include <thread>
     103             : #include <synthesis/Parallel/Applicator.h>
     104             : 
     105             : using namespace std;
     106             : 
     107             : using namespace casacore;
     108             : 
     109             : namespace casa { //# NAMESPACE CASA - BEGIN
     110             :   extern Applicator applicator;
     111           0 :   SynthesisImagerVi2::SynthesisImagerVi2() : SynthesisImager(), vi_p(0), fselections_p(nullptr), imparsVec_p(0), gridparsVec_p(0) {
     112             :         /*cerr << "is applicator initialized " << applicator.initialized() << endl;
     113             :         if(!applicator.initialized()){
     114             :           int argc=1;
     115             :         char **argv;
     116             :         casa::applicator.init ( argc, argv );
     117             :         cerr << "controller ?" <<  applicator.isController() <<  " worker? " <<  applicator.isWorker() <<  " numprocs " << applicator.numProcs() <<  endl;
     118             :         }
     119             :         */
     120           0 :     mss_p.resize(0);
     121           0 :   }
     122             : 
     123           0 :   SynthesisImagerVi2::~SynthesisImagerVi2(){
     124           0 :     for (uInt k=0; k < mss_p.nelements(); ++k){
     125           0 :       if(mss_p[k])
     126           0 :         delete mss_p[k];
     127             :     }
     128           0 :       SynthesisUtilMethods::getResource("End Run");
     129           0 : }
     130             : 
     131           0 :   Bool SynthesisImagerVi2::selectData(const SynthesisParamsSelect& selpars){
     132           0 :  LogIO os( LogOrigin("SynthesisImagerVi2","selectData",WHERE) );
     133           0 :  Bool retval=True;
     134             : 
     135           0 :     SynthesisUtilMethods::getResource("Start Run");
     136             :     
     137             :     try
     138             :       {
     139             : 
     140             : 
     141           0 :         MeasurementSet thisms;
     142             :         { ///Table system seems to have a bug when running in multi-process as the source table disappears
     143             :           /// temporarily when other processes are updating it 
     144           0 :           uInt exceptCounter=0;
     145             :           
     146             :           while(true){
     147             :             try{
     148             :               //Respect the readonly flag...necessary for multi-process access
     149           0 :               thisms=MeasurementSet(selpars.msname, TableLock(TableLock::UserNoReadLocking),
     150           0 :                                     selpars.readonly ? Table::Old : Table::Update);
     151           0 :               break;
     152             :             }
     153           0 :             catch(AipsError &x){
     154             :               
     155           0 :               String mes=x.getMesg();
     156           0 :               if(mes.contains("FilebufIO::readBlock") || mes.contains("SOURCE")){
     157           0 :             std::this_thread::sleep_for(std::chrono::milliseconds(50));
     158           0 :             os << LogIO::WARN << "#####CATCHING a sleep because "<< mes<< LogIO::POST;
     159             :               }
     160             :               else
     161           0 :                 throw(AipsError("Error in selectdata: "+mes));
     162             :               
     163           0 :               if(exceptCounter > 100){
     164           0 :                 throw(AipsError("Error in selectdata got 100 of this exeception: "+mes));
     165             :                 
     166             :               }
     167             :               
     168           0 :             }
     169           0 :             ++exceptCounter;
     170           0 :           }
     171             :         }//End of work around for table disappearing bug
     172             :         
     173             : 
     174             :     
     175           0 :     useScratch_p=selpars.usescratch;
     176           0 :     readOnly_p = selpars.readonly;
     177           0 :     lockMS(thisms);     
     178           0 :     thisms.setMemoryResidentSubtables (MrsEligibility::defaultEligible());
     179             : 
     180             :     
     181             :     //    cout << "**************** usescr : " << useScratch_p << "     readonly : " << readOnly_p << endl;
     182             :     //if you want to use scratch col...make sure they are there
     183             :     ///Need to clear this in first pass only...child processes or loops for cube ///should skip it
     184           0 :     if(!(impars_p.mode.contains("cube")) || ((impars_p.mode.contains("cube")) && doingCubeGridding_p)){
     185           0 :       if(selpars.usescratch && !selpars.readonly){
     186           0 :         VisSetUtil::addScrCols(thisms, true, false, true, false);
     187           0 :         refim::VisModelData::clearModel(thisms);
     188             :       }
     189             :     ////TESTOO
     190             :     //Int CPUID;
     191             :         //MPI_Comm_rank(MPI_COMM_WORLD, &CPUID);
     192             :     //cerr  << " SELPARS " << selpars.toRecord()  << endl;
     193           0 :       if(!selpars.incrmodel && !selpars.usescratch && !selpars.readonly)
     194           0 :         refim::VisModelData::clearModel(thisms, selpars.field, selpars.spw);
     195             :     }//end of first pass if for cubes
     196             :     // unlockMSs();
     197             : 
     198             : 
     199           0 :     os << "MS : " << selpars.msname << " | ";
     200             : 
     201             :     //Some MSSelection 
     202             :     //If everything is empty (which is valid) it will throw an exception..below
     203             :     //So make sure the main defaults are not empy i.e field and spw
     204           0 :     MSSelection thisSelection;
     205           0 :     if(selpars.field != ""){
     206           0 :       thisSelection.setFieldExpr(selpars.field);
     207           0 :       os << "Selecting on fields : " << selpars.field << " | " ;//LogIO::POST;
     208             :     }else
     209           0 :       thisSelection.setFieldExpr("*");
     210           0 :     if(selpars.spw != ""){
     211           0 :         thisSelection.setSpwExpr(selpars.spw);
     212           0 :         os << "Selecting on spw :"<< selpars.spw  << " | " ;//LogIO::POST;
     213             :     }else
     214           0 :       thisSelection.setSpwExpr("*");
     215             :     
     216           0 :     if(selpars.antenna != ""){
     217           0 :       Vector<String> antNames(1, selpars.antenna);
     218             :       // thisSelection.setAntennaExpr(MSSelection::nameExprStr( antNames));
     219           0 :       thisSelection.setAntennaExpr(selpars.antenna);
     220           0 :       os << "Selecting on antenna names : " << selpars.antenna << " | " ;//LogIO::POST;
     221             :         
     222           0 :     }            
     223           0 :     if(selpars.timestr != ""){
     224           0 :         thisSelection.setTimeExpr(selpars.timestr);
     225           0 :         os << "Selecting on time range : " << selpars.timestr << " | " ;//LogIO::POST;    
     226             :       }
     227           0 :     if(selpars.uvdist != ""){
     228           0 :       thisSelection.setUvDistExpr(selpars.uvdist);
     229           0 :       os << "Selecting on uvdist : " << selpars.uvdist << " | " ;//LogIO::POST;   
     230             :     }
     231           0 :     if(selpars.scan != ""){
     232           0 :       thisSelection.setScanExpr(selpars.scan);
     233           0 :       os << "Selecting on scan : " << selpars.scan << " | " ;//LogIO::POST;       
     234             :     }
     235           0 :     if(selpars.obs != ""){
     236           0 :       thisSelection.setObservationExpr(selpars.obs);
     237           0 :       os << "Selecting on Observation Expr : " << selpars.obs << " | " ;//LogIO::POST;    
     238             :     }
     239           0 :     if(selpars.state != ""){
     240           0 :       thisSelection.setStateExpr(selpars.state);
     241           0 :       os << "Selecting on Scan Intent/State : " << selpars.state << " | " ;//LogIO::POST; 
     242             :     }
     243             :     // if(selpars.taql != ""){
     244             :     //  thisSelection.setTaQLExpr(selpars.taql);
     245             :     //  os << "Selecting via TaQL : " << selpars.taql << " | " ;//LogIO::POST;    
     246             :     // }
     247           0 :     os << "[Opened " << (readOnly_p?"in readonly mode":(useScratch_p?"with scratch model column":"with virtual model column"))  << "]" << LogIO::POST;
     248           0 :     TableExprNode exprNode=thisSelection.toTableExprNode(&thisms);
     249           0 :     if(!(exprNode.isNull()))
     250             :       {
     251             :         
     252             :     
     253           0 :         MeasurementSet thisMSSelected0 = MeasurementSet(thisms(exprNode));
     254           0 :         mss_p.resize(mss_p.nelements()+1, false, true);
     255           0 :         if(selpars.taql != "")
     256             :           {
     257           0 :             MSSelection mss0;
     258           0 :             mss0.setTaQLExpr(selpars.taql);
     259           0 :             os << "Selecting via TaQL : " << selpars.taql << " | " ;//LogIO::POST;        
     260             : 
     261           0 :             TableExprNode tenWithTaQL=mss0.toTableExprNode(&thisMSSelected0);
     262           0 :             MeasurementSet thisMSSelected1 = MeasurementSet(thisMSSelected0(tenWithTaQL));
     263             :             //mss4vi_p[mss4vi_p.nelements()-1]=MeasurementSet(thisms(exprNode));
     264           0 :             mss_p[mss_p.nelements()-1]=new MeasurementSet(thisMSSelected1);
     265           0 :           }
     266             :         else
     267           0 :           mss_p[mss_p.nelements()-1]=new MeasurementSet(thisMSSelected0);
     268             :           
     269           0 :         os << "  NRows selected : " << (mss_p[mss_p.nelements()-1])->nrow() << LogIO::POST;
     270           0 :         unlockMSs();
     271           0 :       }
     272             :     else{
     273           0 :       throw(AipsError("Selection for given MS "+selpars.msname+" is invalid"));
     274             :     }
     275           0 :     if((mss_p[mss_p.nelements()-1])->nrow() ==0){
     276           0 :       delete mss_p[mss_p.nelements()-1];
     277           0 :       mss_p.resize(mss_p.nelements()-1, True, True);
     278           0 :       if(mss_p.nelements()==0)
     279           0 :         throw(AipsError("Data selection ended with 0 rows"));
     280             :       //Sill have some valid ms's so return false and do not proceed to do 
     281             :       //channel selection
     282           0 :       unlockMSs();
     283           0 :       return False;
     284             :     }
     285             : 
     286             : 
     287             :     
     288             :     ///Channel selection
     289             :     {
     290           0 :       if(!fselections_p) fselections_p=new FrequencySelections();
     291           0 :       Matrix<Int> chanlist = thisSelection.getChanList(mss_p[mss_p.nelements()-1]);
     292           0 :       Matrix<Double> freqList=thisSelection.getChanFreqList(mss_p[mss_p.nelements()-1]);
     293             :       //cerr << std::setprecision(12) << "FreqList " << freqList << endl;
     294           0 :       IPosition shape = freqList.shape();
     295           0 :       uInt nSelections = shape[0];
     296             :       ///temporary variable as we carry that for tunechunk...till we get rid of it
     297           0 :       selFreqFrame_p=selpars.freqframe;
     298           0 :       Bool ignoreframe=False;
     299           0 :       MFrequency::Types freqFrame=MFrequency::castType(MSColumns(*mss_p[mss_p.nelements()-1]).spectralWindow().measFreqRef()(Int(chanlist(0,0))));
     300             :   
     301           0 :       if(selpars.freqframe == MFrequency::REST ||selpars.freqframe == MFrequency::Undefined){   
     302           0 :         selFreqFrame_p=freqFrame;
     303           0 :         ignoreframe=True;
     304             :       }
     305           0 :       if(selpars.freqbeg==""){
     306             :            // Going round the problem of CAS-8829
     307             :         /*vi::FrequencySelectionUsingChannels channelSelector;
     308             : 
     309             :         channelSelector.add(thisSelection, mss_p[mss_p.nelements()-1]);
     310             : 
     311             :         fselections_p.add(channelSelector);
     312             :         */
     313             :         ////////////////////////////
     314             :         Double lowfreq;
     315             :         Double topfreq;
     316           0 :       Vector<Int> fieldList=thisSelection.getFieldList(mss_p[mss_p.nelements()-1]);
     317             :          // cerr << "chanlist " << chanlist.column(0) << "\n fieldList " << fieldList << endl;
     318             :         
     319             :         //cerr << "selpars.freqframe " << selpars.freqframe << endl;
     320           0 :         vi::FrequencySelectionUsingFrame channelSelector(selFreqFrame_p);
     321             :         ///temporary variable as we carry that for tunechunk
     322             :                 
     323           0 :         Bool selectionValid=False;
     324           0 :           for(uInt k=0; k < nSelections; ++k){
     325           0 :             Bool thisSpwSelValid=False;
     326             :             //The getChanfreqList is wrong for beg and end..going round that too.
     327           0 :             Vector<Double> freqies=MSColumns(*mss_p[mss_p.nelements()-1]).spectralWindow().chanFreq()(Int(chanlist(k,0)));
     328           0 :             Vector<Double> chanwidth=MSColumns(*mss_p[mss_p.nelements()-1]).spectralWindow().chanWidth()(Int(chanlist(k,0)));
     329             :             
     330           0 :             if(freqList(k,3) < 0.0){
     331           0 :               topfreq=freqies(chanlist(k,1));//-chanwidth(chanlist(k,1))/2.0;
     332           0 :               lowfreq=freqies(chanlist(k,2));//+chanwidth(chanlist(k,2))/2.0;
     333             :               //lowfreq=freqList(k,2); //+freqList(k,3)/2.0;
     334             :               //topfreq=freqList(k, 1); //-freqList(k,3)/2.0;
     335             :             }
     336             :             else{
     337           0 :               lowfreq=freqies(chanlist(k,1));//-chanwidth(chanlist(k,1))/2.0;
     338           0 :               topfreq=freqies(chanlist(k,2));//+chanwidth(chanlist(k,2))/2.0;
     339             :               //lowfreq=freqList(k,1);//-freqList(k,3)/2.0;
     340             :               //topfreq=freqList(k, 2);//+freqList(k,3)/2.0;
     341             :             }
     342             :             
     343           0 :             if(!ignoreframe){
     344             :                 
     345             :                         
     346             :           //cerr << "begin " << lowfreq << "  " << topfreq << endl; 
     347             :               //vi::VisibilityIterator2 tmpvi(mss_p, vi::SortColumns(), false); 
     348             :               //VisBufferUtil::getFreqRangeFromRange(lowfreq, topfreq,  freqFrame, lowfreq,  topfreq, tmpvi, selFreqFrame_p);
     349             :               //    lockMS(*(const_cast<MeasurementSet*> (mss_p[mss_p.nelements()-1])));
     350           0 :               if(MSUtil::getFreqRangeInSpw( lowfreq,
     351           0 :                                   topfreq, Vector<Int>(1,chanlist(k,0)), Vector<Int>(1,chanlist(k,1)),
     352           0 :                                   Vector<Int>(1, chanlist(k,2)-chanlist(k,1)+1),
     353           0 :                                  *mss_p[mss_p.nelements()-1] , 
     354             :                                   selFreqFrame_p,
     355             :                                                  fieldList, False))
     356             :                 {
     357           0 :                   selectionValid=True;
     358           0 :                   thisSpwSelValid=True;
     359             :                 }
     360             :               //  unlockMSs();
     361             :                     
     362             :             }
     363             :             
     364           0 :             if(thisSpwSelValid || ignoreframe){
     365           0 :               andFreqSelection(mss_p.nelements()-1, Int(freqList(k,0)), lowfreq, topfreq, selFreqFrame_p);
     366           0 :               andChanSelection(mss_p.nelements()-1, Int(chanlist(k,0)), Int(chanlist(k,1)),Int(chanlist(k,2)));
     367             :             }
     368           0 :           }
     369           0 :           if(! (selectionValid && !ignoreframe)){
     370             :             //os << "Did not match spw selection in the selected ms " << LogIO::WARN << LogIO::POST;
     371           0 :             retval=False;
     372             :           }
     373             :             //fselections_p->add(channelSelector);
     374             :           //////////////////////////////////
     375           0 :       }
     376             :       else{
     377             : 
     378             :         //////More workaroung CAS-8829
     379             :         //MFrequency::Types freqFrame=MFrequency::castType(MSColumns(*mss_p[mss_p.nelements()-1]).spectralWindow().measFreqRef()(Int(freqList(0,0))));
     380           0 :           Quantity freq;
     381           0 :           Quantity::read(freq, selpars.freqbeg);
     382           0 :           Double lowfreq=freq.getValue("Hz");
     383           0 :           Quantity::read(freq, selpars.freqend);
     384           0 :           Double topfreq=freq.getValue("Hz");
     385             :          
     386             :           ////Work aroun CAS-8829
     387             :           // if(vi_p) 
     388             :             //VisBufferUtil::getFreqRangeFromRange(lowfreq, topfreq,  selpars.freqframe, lowfreq,  topfreq, *vi_p, freqFrame);
     389             :           //cerr << "lowFreq "<< lowfreq << " topfreq " << topfreq << endl;
     390             :           //vi::FrequencySelectionUsingFrame channelSelector((vi_p ? freqFrame :selpars.freqframe));
     391             :           //vi::FrequencySelectionUsingFrame channelSelector(selpars.freqframe);
     392           0 :           for(uInt k=0; k < nSelections; ++k){
     393             :             //channelSelector.add(Int(freqList(k,0)), lowfreq, topfreq);
     394             :             //andFreqSelection((mss_p.nelements()-1), Int(freqList(k,0)), lowfreq, topfreq, vi_p ?freqFrame : selpars.freqframe);
     395           0 :             andFreqSelection((mss_p.nelements()-1), Int(freqList(k,0)), lowfreq, topfreq, selFreqFrame_p);
     396             :           }
     397             :           //fselections_p->add(channelSelector);
     398             : 
     399           0 :       }
     400           0 :     }//End of channel selection
     401             :           
     402           0 :     writeAccess_p=writeAccess_p && !selpars.readonly;
     403           0 :     createVisSet(writeAccess_p);
     404             : 
     405             :     /////// Remove this when the new vi/vb is able to get the full freq range.
     406           0 :     mssFreqSel_p.resize();
     407           0 :     mssFreqSel_p  = thisSelection.getChanFreqList(NULL,true);
     408             :    
     409             :     //// Set the data column on which to operate
     410             :     // TT: added checks for the requested data column existace 
     411             :     //    cout << "Using col : " << selpars.datacolumn << endl;
     412           0 :     if( selpars.datacolumn.contains("data") || selpars.datacolumn.contains("obs") ) 
     413           0 :       {    if( thisms.tableDesc().isColumn("DATA") ) { datacol_p = FTMachine::OBSERVED; }
     414           0 :            else { os << LogIO::SEVERE <<"DATA column does not exist" << LogIO::EXCEPTION;}
     415             :       }
     416           0 :     else if( selpars.datacolumn.contains("corr") ) { datacol_p = FTMachine::CORRECTED; }
     417           0 :     else { os << LogIO::WARN << "Invalid data column : " << selpars.datacolumn << ". Using corrected (or observed if corrected doesn't exist)" << LogIO::POST;  datacol_p =  FTMachine::CORRECTED;}
     418             : 
     419             : 
     420           0 :     dataSel_p.resize(dataSel_p.nelements()+1, true);
     421           0 :     dataSel_p[dataSel_p.nelements()-1]=selpars;
     422             :         //cerr << "AT THE end of DATASEL " << selpars.toRecord() << endl;
     423             : 
     424           0 :     unlockMSs();
     425           0 :       }
     426           0 :     catch(AipsError &x)
     427             :       {
     428           0 :         unlockMSs();
     429           0 :         throw( AipsError("Error in selectData() : "+x.getMesg()) );
     430           0 :       }
     431             : 
     432           0 :     return retval;
     433             : 
     434             : 
     435             : 
     436           0 :   }
     437           0 : void SynthesisImagerVi2::andChanSelection(const Int msId, const Int spwId, const Int startchan, const Int endchan){
     438             : 
     439           0 :         map<Int, Vector<Int> > spwsel;
     440           0 :         auto it=channelSelections_p.find(msId);
     441           0 :         if(it !=channelSelections_p.end())
     442           0 :                 spwsel=it->second;
     443           0 :         auto hasspw=spwsel.find(spwId);
     444           0 :         Vector<Int>chansel(2,-1);
     445           0 :         if(hasspw != spwsel.end()){
     446           0 :                 chansel.resize();
     447           0 :                 chansel=hasspw->second;
     448             :         }
     449           0 :         Int nchan=endchan-startchan+1;
     450           0 :         if(chansel(1)== -1)
     451           0 :                 chansel(1)=startchan;
     452           0 :         if(chansel(1) >= startchan){
     453           0 :           if(nchan > (chansel(1)-startchan+chansel(0))){
     454           0 :                         chansel(0)=nchan;
     455             :           }
     456             :           else{
     457           0 :                         chansel(0)=chansel(1)-startchan+chansel(0);
     458             :           }
     459           0 :           chansel(1)=startchan;
     460             :         }
     461             :         else{
     462           0 :                 if((chansel(0) -(startchan - chansel(1)+1)) < nchan){        
     463           0 :                   chansel(0)=nchan+(startchan-chansel(1));
     464             :                 }
     465             :         }
     466           0 :         spwsel[spwId]=chansel;
     467           0 :         channelSelections_p[msId]=spwsel;
     468             :         //cerr << "chansel "<< channelSelections_p << endl;
     469             :         
     470           0 : }
     471           0 :   void SynthesisImagerVi2::andFreqSelection(const Int msId, const Int spwId,  const Double freqBeg, const Double freqEnd, const MFrequency::Types frame){
     472             :     
     473             :     
     474           0 :     Int key=msId;
     475             :    
     476           0 :     Bool isDefined=False;
     477           0 :     FrequencySelectionUsingFrame frameSel(frame);
     478           0 :     for (uInt k =0; k<freqBegs_p.size(); ++k){ 
     479             :       //cerr <<freqBegs_p[k].first  << " == " << key << " && " << freqSpws_p[k].second<< " == " << spwId << " && " << freqBeg << " < " << freqEnds_p[k].second<< " && " << freqEnd << " > " << freqBegs_p[k].second << endl;
     480           0 :         if((freqBegs_p[k].first == key || key <0 ) && (freqSpws_p[k].second==spwId || spwId <0)  && (freqBeg < freqEnds_p[k].second) && (freqEnd > freqBegs_p[k].second)){
     481           0 :         isDefined=True;
     482             :         //cerr << k << " inside freqBegs " << freqBegs_p[k].second << "  " << freqBeg << endl;  
     483           0 :         if(freqBegs_p[k].second < freqBeg)
     484           0 :           freqBegs_p[k].second=freqBeg;
     485           0 :         if(freqEnds_p[k].second > freqEnd)
     486           0 :           freqEnds_p[k].second=freqEnd;
     487           0 :         if(msId < 0) key=freqBegs_p[k].first;
     488             :         //cerr << "modified " <<  freqBegs_p[k].second << "   "  <<  freqEnds_p[k].second << endl;
     489             :       }
     490             :         ///add only those that have the same msid
     491           0 :         if(freqBegs_p[k].first == key){
     492             :           //cerr << "added " << k << " freqBegs " << freqBegs_p[k].second << "  " << freqEnds_p[k].second << endl;  
     493           0 :           frameSel.add(freqSpws_p[k].second ,  freqBegs_p[k].second, freqEnds_p[k].second);
     494             :         }
     495             :     }
     496           0 :     if(!isDefined && msId >=0){
     497             :       //cerr << "undefined " << key << " freqBegs "  << freqBeg << "  " << freqEnd << endl;  
     498           0 :       freqBegs_p.push_back(make_pair(key, freqBeg));
     499           0 :       freqEnds_p.push_back(make_pair(key, freqEnd));
     500           0 :       freqSpws_p.push_back(make_pair(key, spwId));
     501           0 :       frameSel.add(spwId,  freqBeg, freqEnd);
     502             :     }
     503           0 :     CountedPtr<vi::FrequencySelections> copyFsels=fselections_p->clone();
     504           0 :     uInt nMSs=copyFsels->size() <=msId ? msId+1 : copyFsels->size();
     505             :     //cerr << "nms " << nMSs << endl;
     506           0 :     fselections_p=new FrequencySelections();
     507           0 :     for (uInt k=0;  k < nMSs ; ++k){
     508           0 :       if(k==uInt(key)){
     509           0 :         fselections_p->add(frameSel);
     510             :         //cerr <<"adding framesel " << frameSel.toString() << endl;
     511             :       }
     512             :       else{
     513           0 :         const FrequencySelectionUsingFrame& thissel= static_cast<const FrequencySelectionUsingFrame &> (copyFsels->get(k));
     514             :         //cerr <<"framesel orig " << thissel.toString() << endl;
     515           0 :         fselections_p->add(thissel);
     516             : 
     517             :       }
     518             :     }
     519             :     
     520             :  
     521             : 
     522           0 :   }
     523             : 
     524           0 :   void SynthesisImagerVi2::tuneChunk(const Int gmap) {
     525             : 
     526           0 :     CoordinateSystem cs=itsMappers.imageStore(gmap)->getCSys();
     527           0 :     IPosition imshape=itsMappers.imageStore(gmap)->getShape();
     528             :     /////For some reason imagestore returns 0 channel image sometimes
     529             :     ////
     530           0 :     if(imshape(3) < 1) {
     531           0 :       return;
     532             :     }
     533             :    
     534           0 :     Double minFreq=SpectralImageUtil::worldFreq(cs, 0.0);
     535           0 :     Double maxFreq=SpectralImageUtil::worldFreq(cs,imshape(3)-1);
     536             :    
     537           0 :     if(maxFreq < minFreq){
     538           0 :       Double tmp=minFreq;
     539           0 :       minFreq=maxFreq;
     540           0 :       maxFreq=tmp;
     541             :     }
     542             :     
     543           0 :     Int spectralIndex=cs.findCoordinate(Coordinate::SPECTRAL);
     544           0 :     SpectralCoordinate spectralCoord=cs.spectralCoordinate(spectralIndex);
     545           0 :     maxFreq+=fabs(spectralCoord.increment()(0))/2.0;
     546           0 :     minFreq-=fabs(spectralCoord.increment()(0))/2.0;
     547           0 :     if(minFreq < 0.0) minFreq=0.0;
     548           0 :     MFrequency::Types intype=spectralCoord.frequencySystem(True);
     549             :     
     550           0 :     if(!VisBufferUtil::getFreqRangeFromRange(minFreq, maxFreq,  intype, minFreq,  maxFreq, *vi_p, selFreqFrame_p)){
     551             :       //Do not retune if conversion did not happen
     552           0 :       return;
     553             :     }
     554             :       
     555           0 :     maxFreq+=3.0*fabs(spectralCoord.increment()(0))/2.0;
     556           0 :     minFreq-=3.0*fabs(spectralCoord.increment()(0))/2.0;
     557           0 :     if(minFreq < 0.0) minFreq=0.0;
     558             :     
     559           0 :     auto copyFreqBegs=freqBegs_p;
     560           0 :     auto copyFreqEnds=freqEnds_p;
     561           0 :     auto copyFreqSpws=  freqSpws_p;
     562             :     ///////////////TESTOO
     563             :     //cerr << std::setprecision(12) << "AFTER maxFreq " << maxFreq << "  minFreq " << minFreq << endl;
     564             :     //for (Int k =0 ; k < (fselections_p->size()) ; ++k){
     565             :     //  cerr << k << (fselections_p->get(k)).toString() << endl;
     566             :     // }
     567             :     ///////////////////////////////////////        
     568             :     ///TESTOO
     569             :     // andFreqSelection(-1, -1, minFreq, maxFreq, MFrequency::TOPO); 
     570           0 :     andFreqSelection(-1, -1, minFreq, maxFreq, selFreqFrame_p);
     571             :     
     572           0 :     vi_p->setFrequencySelection (*fselections_p);
     573             : 
     574           0 :     freqBegs_p=copyFreqBegs;
     575           0 :     freqEnds_p=copyFreqEnds;
     576           0 :     freqSpws_p=copyFreqSpws;
     577           0 :   }
     578             : 
     579             : 
     580           0 : Bool SynthesisImagerVi2::defineImage(
     581             :         SynthesisParamsImage& impars,
     582             :         const SynthesisParamsGrid& gridpars)
     583             :   {
     584           0 :     LogIO os( LogOrigin("SynthesisImagerVi2", "defineImage", WHERE) );
     585             : 
     586           0 :     if (mss_p.nelements() == 0)
     587           0 :       os << "SelectData has to be run before defineImage" << LogIO::EXCEPTION;
     588             : 
     589           0 :     CoordinateSystem csys;
     590           0 :     CountedPtr<refim::FTMachine> ftm, iftm;
     591           0 :     impars_p = impars;
     592           0 :     gridpars_p = gridpars; 
     593             : 
     594             :     try {
     595           0 :       os << "Define image coordinates for [" << impars.imageName << "] : "
     596           0 :          << LogIO::POST;
     597           0 :         os << "Define image coordinates for [" << impars.imageName << "] : " << LogIO::POST;
     598             :         //    cerr <<  "DEFIM " <<  gridpars_p.ftmachine <<  endl;
     599             :         //    cerr <<  "###### gridpars compute " <<  gridpars.computePAStep <<  "   " <<  gridpars_p.computePAStep <<  endl;
     600           0 :         csys = impars_p.buildCoordinateSystem( *vi_p, channelSelections_p, mss_p );
     601             :         //use the location defined for coordinates frame;
     602           0 :         mLocation_p=impars_p.obslocation;
     603           0 :         IPosition imshape = impars_p.shp();
     604             : 
     605             :         
     606           0 :          os << "Impars: start " << impars_p.start << LogIO::POST;
     607             :          os << "Shape: " << imshape
     608           0 :          << " Spectral: " << csys.spectralCoordinate().referenceValue()
     609           0 :          << " at " << csys.spectralCoordinate().referencePixel()
     610           0 :          << " with increment " << csys.spectralCoordinate().increment()
     611           0 :          << LogIO::POST;
     612             : 
     613           0 :         if( (itsMappers.nMappers()==0) || 
     614           0 :             (impars_p.imsize[0]*impars_p.imsize[1] > itsMaxShape[0]*itsMaxShape[1]))
     615             :           {
     616           0 :             itsMaxShape=imshape;
     617           0 :             itsMaxCoordSys=csys;
     618             :           }
     619           0 :         itsNchan = imshape[3];
     620           0 :         itsCsysRec = impars_p.getcsys();
     621             :         /*
     622             :         os << "Define image  [" << impars.imageName << "] : nchan : " << impars.nchan 
     623             :            //<< ", freqstart:" << impars.freqStart.getValue() << impars.freqStart.getUnit() 
     624             :            << ", start:" << impars.start
     625             :            <<  ", imsize:" << impars.imsize 
     626             :            << ", cellsize: [" << impars.cellsize[0].getValue() << impars.cellsize[0].getUnit() 
     627             :            << " , " << impars.cellsize[1].getValue() << impars.cellsize[1].getUnit() 
     628             :            << LogIO::POST;
     629             :         */
     630             :         // phasecenter
     631           0 :         if (impars_p.phaseCenterFieldId == -1) {
     632             :           // user-specified
     633           0 :           phaseCenter_p = impars_p.phaseCenter;
     634           0 :         } else if (impars_p.phaseCenterFieldId >= 0) {
     635             :           // FIELD_ID
     636           0 :           auto const msobj = mss_p[0];
     637           0 :           MSFieldColumns msfield(msobj->field());
     638           0 :           phaseCenter_p=msfield.phaseDirMeas(impars_p.phaseCenterFieldId);
     639           0 :         } else {
     640             :           // use default FIELD_ID (0)
     641           0 :           auto const msobj = mss_p[0];
     642           0 :           MSFieldColumns msfield(msobj->field());
     643           0 :           phaseCenter_p=msfield.phaseDirMeas(0);
     644           0 :         }
     645             : 
     646             : 
     647           0 :       if ( (itsMappers.nMappers() == 0) or
     648           0 :            (impars_p.imsize[0]*impars_p.imsize[1] > itsMaxShape[0]*itsMaxShape[1])
     649             :          ) {
     650           0 :         itsMaxShape = imshape;
     651           0 :         itsMaxCoordSys = csys;
     652             :       }
     653           0 :       itsNchan = imshape[3];
     654           0 :       itsCsysRec = impars_p.getcsys();
     655             : 
     656             :       // os << "Define image  [" << impars.imageName << "] : nchan : " << impars.nchan
     657             :       //    //<< ", freqstart:" << impars.freqStart.getValue() << impars.freqStart.getUnit()
     658             :       //    << ", start:" << impars.start
     659             :       //    <<  ", imsize:" << impars.imsize
     660             :       //    << ", cellsize: [" << impars.cellsize[0].getValue() << impars.cellsize[0].getUnit()
     661             :       //    << " , " << impars.cellsize[1].getValue() << impars.cellsize[1].getUnit()
     662             :       //    << LogIO::POST;
     663             : 
     664             :       // phasecenter
     665           0 :       if (impars_p.phaseCenterFieldId == -1) { // user-specified
     666           0 :         phaseCenter_p = impars_p.phaseCenter;
     667           0 :       } else if (impars_p.phaseCenterFieldId >= 0) { // FIELD_ID
     668           0 :         auto const msobj = mss_p[0];
     669           0 :         MSFieldColumns msfield(msobj->field());
     670           0 :         phaseCenter_p = msfield.phaseDirMeas(impars_p.phaseCenterFieldId);
     671           0 :       } else { // use default FIELD_ID (0)
     672           0 :         auto const msobj = mss_p[0];
     673           0 :         MSFieldColumns msfield(msobj->field());
     674           0 :         phaseCenter_p = msfield.phaseDirMeas(0);
     675           0 :       }
     676           0 :     }
     677           0 :     catch (AipsError &x) {
     678             :       os << "Error in building Coordinate System and Image Shape: "
     679             :          << x.getMesg()
     680           0 :          << LogIO::EXCEPTION;
     681           0 :     }
     682             : 
     683             :     try {
     684           0 :       os << "Set Gridding options for [" << impars_p.imageName << "]"
     685           0 :          << " with ftmachine: " << gridpars.ftmachine
     686           0 :          << LogIO::POST;
     687             : 
     688           0 :       itsVpTable = gridpars.vpTable;
     689           0 :       itsMakeVP = ( gridpars.ftmachine.contains("mosaicft") or
     690           0 :                     gridpars.ftmachine.contains("awprojectft") ) ?
     691             :                   False : True;
     692             : 
     693             :       //cerr << "DEFINEimage " << impars_p.toRecord() << endl;
     694             : 
     695           0 :       createFTMachine(
     696           0 :         ftm, iftm, gridpars.ftmachine, impars_p.nTaylorTerms, gridpars.mType,
     697           0 :         gridpars.facets, gridpars.wprojplanes,
     698           0 :         gridpars.padding, gridpars.useAutoCorr, gridpars.useDoublePrec,
     699           0 :         gridpars.convFunc,
     700           0 :         gridpars.aTermOn, gridpars.psTermOn, gridpars.mTermOn,
     701           0 :         gridpars.wbAWP, gridpars.cfCache, gridpars.usePointing, gridpars.pointingOffsetSigDev.tovector(),
     702           0 :         gridpars.doPBCorr, gridpars.conjBeams,
     703           0 :         gridpars.computePAStep, gridpars.rotatePAStep,
     704           0 :         gridpars.interpolation, impars_p.freqFrameValid, 1000000000, 16, impars_p.stokes,
     705           0 :         impars_p.imageName,
     706           0 :         gridpars.pointingDirCol, gridpars.convertFirst, gridpars.skyPosThreshold,
     707           0 :         gridpars.convSupport, gridpars.truncateSize, gridpars.gwidth, gridpars.jwidth,
     708           0 :         gridpars.minWeight, gridpars.clipMinMax, impars_p.pseudoi
     709             :       );
     710             : 
     711             :     }
     712           0 :     catch (AipsError &x) {
     713           0 :       os << "Error in setting up FTMachine(): " << x.getMesg() << LogIO::EXCEPTION;
     714           0 :     }
     715             : 
     716             : 
     717             :     try {
     718           0 :       appendToMapperList(
     719           0 :         impars_p.imageName, csys, impars_p.shp(),
     720             :         ftm, iftm,
     721           0 :         gridpars.distance, gridpars.facets, gridpars.chanchunks, impars_p.overwrite,
     722           0 :         gridpars.mType, gridpars.padding, impars_p.nTaylorTerms, impars_p.startModel
     723             :       );
     724             : 
     725           0 :       imageDefined_p = true;
     726             :     }
     727           0 :     catch(AipsError &x) {
     728           0 :       os << "Error in adding Mapper: " + x.getMesg() << LogIO::EXCEPTION;
     729           0 :     }
     730             : 
     731           0 :     imparsVec_p.resize(imparsVec_p.nelements()+1, true);
     732           0 :     imparsVec_p[imparsVec_p.nelements()-1] = impars_p;
     733             :     ///For now cannot deal with cube and mtmfs in C++ parallel mode
     734           0 :     if (imparsVec_p[0].deconvolver == "mtmfs") setCubeGridding(False);
     735             :     // cerr << "DECONV " << imparsVec_p[0].deconvolver
     736             :     //      << " cube gridding " << doingCubeGridding_p << endl;
     737           0 :     gridparsVec_p.resize(gridparsVec_p.nelements()+1, true);
     738           0 :     gridparsVec_p[imparsVec_p.nelements()-1] = gridpars_p;
     739             :     // For now as awproject does not work with the c++ mpi cube gridding
     740             :     // make sure it works the old way as mfs
     741             :     // if ( gridparsVec_p[0].ftmachine.contains("awproject") )
     742             :     //   setCubeGridding(False);
     743           0 :     itsMakeVP =
     744           0 :       (  gridparsVec_p[0].ftmachine.contains("mosaicft") or
     745           0 :         (gridparsVec_p[0].ftmachine.at(0,3) == "awp")
     746           0 :       ) ? False : True;
     747           0 :     return true;
     748           0 :   }
     749             : 
     750           0 : Bool SynthesisImagerVi2::defineImage(
     751             :         CountedPtr<SIImageStore> imstor,
     752             :         SynthesisParamsImage& impars,
     753             :         const SynthesisParamsGrid& gridpars)
     754             :   {
     755           0 :     gridpars_p=gridpars;
     756           0 :     Int id = itsMappers.nMappers();
     757           0 :     CoordinateSystem csys = imstor->getCSys();
     758           0 :     IPosition imshape = imstor->getShape();
     759           0 :     Int nx=imshape[0], ny=imshape[1];
     760           0 :     if ( (id==0) || (nx*ny > itsMaxShape[0]*itsMaxShape[1]) ) {
     761           0 :       itsMaxShape=imshape;
     762           0 :       itsMaxCoordSys=csys;
     763             :     }
     764           0 :     mLocation_p=impars.obslocation;
     765             :     // phasecenter
     766           0 :     if (impars.phaseCenterFieldId == -1) { // user-specified
     767           0 :       phaseCenter_p = impars.phaseCenter;
     768             :     }
     769           0 :     else if (impars.phaseCenterFieldId >= 0) { // FIELD_ID
     770           0 :       auto const msobj = mss_p[0];
     771           0 :       MSFieldColumns msfield(msobj->field());
     772           0 :       phaseCenter_p = msfield.phaseDirMeas(impars.phaseCenterFieldId);
     773           0 :     }
     774             :     else { // use default FIELD_ID (0)
     775           0 :       auto const msobj = mss_p[0];
     776           0 :       MSFieldColumns msfield(msobj->field());
     777           0 :       phaseCenter_p = msfield.phaseDirMeas(0);
     778           0 :     }
     779             : 
     780           0 :     itsVpTable = gridpars.vpTable;
     781           0 :     itsMakeVP = (  gridpars.ftmachine.contains("mosaicft") or
     782           0 :                   (gridpars.ftmachine.at(0,3) == "awp")
     783           0 :                 ) ? False : True;
     784           0 :     CountedPtr<refim::FTMachine> ftm, iftm;
     785             : 
     786           0 :     createFTMachine(
     787           0 :       ftm, iftm, gridpars.ftmachine, impars.nTaylorTerms, gridpars.mType,
     788           0 :       gridpars.facets, gridpars.wprojplanes,
     789           0 :       gridpars.padding,gridpars.useAutoCorr,gridpars.useDoublePrec,
     790           0 :       gridpars.convFunc,
     791           0 :       gridpars.aTermOn,gridpars.psTermOn, gridpars.mTermOn,
     792           0 :       gridpars.wbAWP,gridpars.cfCache,gridpars.usePointing,
     793           0 :       gridpars.pointingOffsetSigDev.tovector(),
     794           0 :       gridpars.doPBCorr,gridpars.conjBeams,
     795           0 :       gridpars.computePAStep,gridpars.rotatePAStep,
     796           0 :       gridpars.interpolation, impars.freqFrameValid, 1000000000, 16, impars.stokes,
     797           0 :       impars.imageName,
     798           0 :       gridpars.pointingDirCol, gridpars.convertFirst, gridpars.skyPosThreshold,
     799           0 :       gridpars.convSupport, gridpars.truncateSize, gridpars.gwidth, gridpars.jwidth,
     800           0 :       gridpars.minWeight, gridpars.clipMinMax, impars.pseudoi);
     801             : 
     802           0 :   if (gridpars.facets >1) {
     803             :     // Make and connect the list.
     804             :     Block<CountedPtr<SIImageStore> > imstorList =
     805           0 :       createFacetImageStoreList( imstor, gridpars.facets );
     806           0 :     for( uInt facet=0; facet<imstorList.nelements(); facet++) {
     807           0 :       CountedPtr<refim::FTMachine> new_ftm, new_iftm;
     808           0 :       if (facet == 0) {
     809           0 :         new_ftm = ftm;
     810           0 :         new_iftm = iftm;
     811             :       }
     812             :       else {
     813           0 :         new_ftm = ftm->cloneFTM();
     814           0 :         new_iftm = iftm->cloneFTM();
     815             :       }
     816           0 :       itsMappers.addMapper(
     817           0 :         createSIMapper( gridpars.mType, imstorList[facet], new_ftm, new_iftm)
     818             :       );
     819           0 :     }
     820           0 :   }
     821             :   else {
     822           0 :     itsMappers.addMapper(
     823           0 :       createSIMapper( gridpars.mType, imstor, ftm, iftm)
     824             :     );
     825             :   }
     826           0 :   impars_p = impars;
     827           0 :   gridpars_p = gridpars;
     828           0 :   imageDefined_p = true;
     829             : 
     830           0 :   imparsVec_p.resize(imparsVec_p.nelements()+1, true);
     831           0 :   imparsVec_p[imparsVec_p.nelements()-1] = impars_p;
     832             : 
     833           0 :   gridparsVec_p.resize(gridparsVec_p.nelements()+1, true);
     834           0 :   gridparsVec_p[gridparsVec_p.nelements()-1] = gridpars_p;
     835             : 
     836           0 :   return true;
     837           0 : }
     838             : 
     839           0 : Bool SynthesisImagerVi2::defineImage(CountedPtr<SIImageStore> imstor, 
     840             :                                     const String& ftmachine)
     841             :   {
     842           0 :     CountedPtr<refim::FTMachine> ftm, iftm;
     843             : 
     844             :     // The following call to createFTMachine() uses the
     845             :     // following defaults
     846             :     //
     847             :     // facets=1, wprojplane=1, padding=1.0, useAutocorr=false, 
     848             :     // useDoublePrec=true, gridFunction=String("SF")
     849             :     //
     850           0 :     createFTMachine(ftm, iftm, ftmachine);
     851             :     
     852           0 :     Int id=itsMappers.nMappers();
     853           0 :     CoordinateSystem csys =imstor->getCSys();
     854           0 :     IPosition imshape=imstor->getShape();
     855           0 :     Int nx=imshape[0], ny=imshape[1];
     856           0 :     if( (id==0) || (nx*ny > itsMaxShape[0]*itsMaxShape[1]))
     857             :       {
     858           0 :         itsMaxShape=imshape;
     859           0 :         itsMaxCoordSys=csys;
     860             :       }
     861             : 
     862           0 :     itsMappers.addMapper(  createSIMapper( "default", imstor, ftm, iftm ) );
     863           0 :     imageDefined_p=true;
     864           0 :     return true;
     865           0 :   }
     866           0 : Bool SynthesisImagerVi2::defineImage(CountedPtr<SIImageStore> imstor, 
     867             :                                     const Record& ftmRec, const Record& iftmRec)
     868             :   {
     869           0 :     CountedPtr<refim::FTMachine> ftm, iftm;
     870           0 :         ftm=refim::VisModelData::NEW_FT(ftmRec);
     871           0 :         iftm=refim::VisModelData::NEW_FT(iftmRec);
     872             :     
     873           0 :     Int id=itsMappers.nMappers();
     874           0 :     CoordinateSystem csys =imstor->getCSys();
     875           0 :     IPosition imshape=imstor->getShape();
     876           0 :     Int nx=imshape[0], ny=imshape[1];
     877           0 :     if( (id==0) || (nx*ny > itsMaxShape[0]*itsMaxShape[1]))
     878             :       {
     879           0 :         itsMaxShape=imshape;
     880           0 :         itsMaxCoordSys=csys;
     881             :       }
     882             : 
     883           0 :     itsMappers.addMapper(  createSIMapper( "default", imstor, ftm, iftm, id ) );
     884           0 :     imageDefined_p=true;
     885           0 :     return true;
     886           0 :   }
     887           0 :  Bool SynthesisImagerVi2::weight(const Record& inrec){
     888           0 :         String type, rmode, filtertype;
     889           0 :         Quantity noise, fieldofview,filterbmaj,filterbmin, filterbpa;  
     890             :         Double robust, fracBW;
     891             :         Int npixels;
     892             :         Bool multiField, useCubeBriggs;
     893           0 :         SynthesisUtilMethods::getFromWeightRecord(type, rmode,noise, robust,fieldofview,npixels, multiField, useCubeBriggs,
     894             :                                   filtertype, filterbmaj,filterbmin, filterbpa, fracBW, inrec);
     895           0 :         return weight(type, rmode,noise, robust,fieldofview,npixels, multiField, useCubeBriggs,
     896           0 :                                   filtertype, filterbmaj,filterbmin, filterbpa, fracBW );
     897             :                                 
     898             :          
     899           0 :  }
     900           0 :  Bool SynthesisImagerVi2::weight(const String& type, const String& rmode,
     901             :                                const Quantity& noise, const Double robust,
     902             :                                const Quantity& fieldofview,
     903             :                                  const Int npixels, const Bool multiField, const Bool useCubeBriggs,
     904             :                                const String& filtertype, const Quantity& filterbmaj,
     905             :                                const Quantity& filterbmin, const Quantity& filterbpa, Double fracBW)
     906             :   {
     907           0 :       LogIO os(LogOrigin("SynthesisImagerVi2", "weight()", WHERE));
     908             :       
     909           0 :       if(rmode=="bwtaper") //See CAS-13021 for bwtaper algorithm details
     910             :       {
     911           0 :           if(fracBW == 0.0)
     912             :           {
     913           0 :               Double minFreq = 0.0;
     914           0 :               Double maxFreq = 0.0;
     915             :               
     916           0 :               if(itsMaxShape(3) < 1) {
     917           0 :                 cout << "SynthesisImagerVi2::weight Only one channel in image " << endl;
     918             :               }
     919             :               else{
     920           0 :                   minFreq=abs(SpectralImageUtil::worldFreq(itsMaxCoordSys, 0.0));
     921           0 :                   maxFreq=abs(SpectralImageUtil::worldFreq(itsMaxCoordSys,itsMaxShape(3)-1));
     922             : 
     923           0 :                   if(maxFreq < minFreq){
     924           0 :                     Double tmp=minFreq;
     925           0 :                     minFreq=maxFreq;
     926           0 :                     maxFreq=tmp;
     927             :                   }
     928             :                   
     929           0 :                   if((maxFreq != 0.0) || (minFreq != 0.0)) fracBW = 2*(maxFreq - minFreq)/(maxFreq + minFreq);
     930             :                   
     931           0 :                   os << LogIO::NORMAL << " Fractional bandwidth used by briggsbwtaper " << fracBW << endl;  //<< LogIO::POST;
     932             :                   
     933             :               }
     934             :           }
     935             :       }
     936             :       
     937           0 :         weightParams_p=SynthesisUtilMethods::fillWeightRecord(type, rmode,noise, robust,fieldofview,
     938           0 :                                  npixels, multiField, useCubeBriggs,filtertype, filterbmaj,filterbmin, filterbpa, fracBW);
     939             : 
     940             :        try {
     941             :         //Int nx=itsMaxShape[0];
     942             :         //Int ny=itsMaxShape[1];
     943             :         
     944             : 
     945             :          ///////////////////////
     946           0 :          Quantity cellx=Quantity(itsMaxCoordSys.increment()[0], itsMaxCoordSys.worldAxisUnits()[0]);
     947           0 :          Quantity celly=Quantity(itsMaxCoordSys.increment()[1], itsMaxCoordSys.worldAxisUnits()[1]);
     948             :          os << LogIO::NORMAL // Loglevel INFO
     949           0 :             << "Set imaging weights : " ; //<< LogIO::POST;
     950             :          
     951           0 :          if (type=="natural") {
     952             :            os << LogIO::NORMAL // Loglevel INFO
     953           0 :               << "Natural weighting" << LogIO::POST;
     954           0 :            imwgt_p=VisImagingWeight("natural");
     955             :          }
     956           0 :       else if (type=="radial") {
     957           0 :         os << "Radial weighting" << LogIO::POST;
     958           0 :           imwgt_p=VisImagingWeight("radial");
     959             :       }
     960             :       else{
     961           0 :         vi_p->originChunks();
     962           0 :         vi_p->origin();
     963           0 :           if(!imageDefined_p)
     964           0 :                   throw(AipsError("Need to define image"));
     965           0 :           Int nx=itsMaxShape[0];
     966           0 :           Int ny=itsMaxShape[1];
     967           0 :           Quantity cellx=Quantity(itsMaxCoordSys.increment()[0], itsMaxCoordSys.worldAxisUnits()[0]);
     968           0 :           Quantity celly=Quantity(itsMaxCoordSys.increment()[1], itsMaxCoordSys.worldAxisUnits()[1]);
     969           0 :           if(type=="superuniform"){
     970           0 :                   if(!imageDefined_p) throw(AipsError("Please define image first"));
     971           0 :                   Int actualNpix=npixels;
     972           0 :                   if(actualNpix <=0)
     973           0 :                           actualNpix=3;
     974             :                   os << LogIO::NORMAL // Loglevel INFO
     975             :                                   << "SuperUniform weighting over a square cell spanning ["
     976             :                                   << -actualNpix
     977           0 :                                   << ", " << actualNpix << "] in the uv plane" << LogIO::POST;
     978           0 :                   imwgt_p=VisImagingWeight(*vi_p, rmode, noise, robust, nx,
     979             :                                   ny, cellx, celly, actualNpix,
     980           0 :                                   actualNpix, multiField);
     981             :           }
     982           0 :           else if ((type=="robust")||(type=="uniform")||(type=="briggs")) {
     983           0 :                   if(!imageDefined_p) throw(AipsError("Please define image first"));
     984           0 :                   Quantity actualFieldOfView_x(fieldofview), actualFieldOfView_y(fieldofview) ;
     985           0 :                   Int actualNPixels_x(npixels),actualNPixels_y(npixels) ;
     986           0 :                   String wtype;
     987           0 :                   if(type=="briggs") {
     988           0 :                           wtype = "Briggs";
     989             :                   }
     990             :                   else {
     991           0 :                           wtype = "Uniform";
     992             :                   }
     993           0 :                   if(actualFieldOfView_x.get().getValue()==0.0&&actualNPixels_x==0) {
     994           0 :                           actualNPixels_x=nx;
     995           0 :                           actualFieldOfView_x=Quantity(actualNPixels_x*cellx.get("rad").getValue(),"rad");
     996           0 :                           actualNPixels_y=ny;
     997           0 :                           actualFieldOfView_y=Quantity(actualNPixels_y*celly.get("rad").getValue(),"rad");
     998             :                           os << LogIO::NORMAL // Loglevel INFO
     999             :                                           << wtype
    1000             :                                           << " weighting: sidelobes will be suppressed over full image"
    1001           0 :                                           << LogIO::POST;
    1002             :                   }
    1003           0 :                   else if(actualFieldOfView_x.get().getValue()>0.0&&actualNPixels_x==0) {
    1004           0 :                           actualNPixels_x=nx;
    1005           0 :                           actualNPixels_y=ny;
    1006             :                           os << LogIO::NORMAL // Loglevel INFO
    1007             :                                           << wtype
    1008             :                                           << " weighting: sidelobes will be suppressed over specified field of view: "
    1009           0 :                                           << actualFieldOfView_x.get("arcsec").getValue() << " arcsec by " 
    1010           0 :                                           << actualFieldOfView_y.get("arcsec").getValue()  << " arcsec" << LogIO::POST;
    1011             :                   }
    1012           0 :                   else if(actualFieldOfView_x.get().getValue()==0.0&&actualNPixels_x>0) {
    1013           0 :                           actualFieldOfView_x=Quantity(actualNPixels_x*cellx.get("rad").getValue(),"rad");
    1014           0 :                           actualFieldOfView_y=Quantity(actualNPixels_y*celly.get("rad").getValue(),"rad");
    1015             :                           os << LogIO::NORMAL // Loglevel INFO
    1016             :                                           << wtype
    1017             :                                           << " weighting: sidelobes will be suppressed over full image field of view: "
    1018           0 :                                           << actualFieldOfView_x.get("arcsec").getValue() << " arcsec by " 
    1019           0 :                                           << actualFieldOfView_y.get("arcsec").getValue() << " arcsec" << LogIO::POST;
    1020             :                   }
    1021             :                   else {
    1022             :                           os << LogIO::NORMAL // Loglevel INFO
    1023             :                                           << wtype
    1024             :                                           << " weighting: sidelobes will be suppressed over specified field of view: "
    1025           0 :                                           << actualFieldOfView_x.get("arcsec").getValue() << " arcsec by " 
    1026           0 :                                           << actualFieldOfView_y.get("arcsec").getValue() << " arcsec" << LogIO::POST;
    1027             :                   }
    1028             :                   os << LogIO::DEBUG1
    1029             :                      << "Weighting used " << actualNPixels_x << " by " << actualNPixels_y << " uv pixels."
    1030           0 :                      << LogIO::POST;
    1031           0 :                   Quantity actualCellSize_x(actualFieldOfView_x.get("rad").getValue()/actualNPixels_x, "rad");
    1032           0 :                   Quantity actualCellSize_y(actualFieldOfView_y.get("rad").getValue()/actualNPixels_y, "rad");
    1033             : 
    1034             : 
    1035             :                   //              cerr << "rmode " << rmode << " noise " << noise << " robust " << robust << " npixels " << actualNPixels << " cellsize " << actualCellSize << " multifield " << multiField << endl;
    1036             :                   //              Timer timer;
    1037             :                   //timer.mark();
    1038             :                   //Construct imwgt_p with old vi for now if old vi is in use as constructing with vi2 is slower
    1039             :                   //Determine if any image is cube
    1040           0 :                   if(useCubeBriggs){
    1041           0 :                     String outstr=String("Doing spectral cube Briggs weighting formula --  " + rmode + (rmode=="abs" ? " with estimated noise "+ String::toString(noise.getValue())+noise.getUnit()  : "")); 
    1042           0 :                     os << outstr << LogIO::POST;
    1043             :                     //VisImagingWeight nat("natural");
    1044             :                     //vi_p->useImagingWeight(nat);
    1045           0 :                     if(rmode=="abs" && robust==0.0 && noise.getValue()==0.0)
    1046           0 :                       throw(AipsError("Absolute Briggs formula does not allow for robust 0 and estimated noise per visibility 0"));
    1047             :                 
    1048           0 :             CountedPtr<refim::BriggsCubeWeightor> bwgt=new refim::BriggsCubeWeightor(wtype=="Uniform" ? "none" : rmode, noise, robust,fracBW, npixels, multiField);
    1049           0 :             for (Int k=0; k < itsMappers.nMappers(); ++k){
    1050           0 :                       itsMappers.getFTM2(k)->setBriggsCubeWeight(bwgt);
    1051             :                     }
    1052             :               
    1053             :               
    1054           0 :                   }
    1055             :                   else
    1056             :                   {
    1057           0 :                     imwgt_p=VisImagingWeight(*vi_p, wtype=="Uniform" ? "none" : rmode, noise, robust,
    1058             :                                              actualNPixels_x, actualNPixels_y, actualCellSize_x,
    1059           0 :                                              actualCellSize_y, 0, 0, multiField);
    1060             :                   }
    1061             : 
    1062             :                   /*
    1063             :                   if(rvi_p !=NULL){
    1064             :                     imwgt_p=VisImagingWeight(*rvi_p, rmode, noise, robust,
    1065             :                                  actualNPixels, actualNPixels, actualCellSize,
    1066             :                                  actualCellSize, 0, 0, multiField);
    1067             :                   }
    1068             :                   else{
    1069             :                     ////This is slower by orders of magnitude as of 2014/06/25
    1070             :                     imwgt_p=VisImagingWeight(*vi_p, rmode, noise, robust,
    1071             :                                  actualNPixels, actualNPixels, actualCellSize,
    1072             :                                  actualCellSize, 0, 0, multiField);
    1073             :                   }
    1074             :                   */
    1075             :                     //timer.show("After making visweight ");
    1076             : 
    1077           0 :           }
    1078             :           else {
    1079             :                   //this->unlock();
    1080             :                   os << LogIO::SEVERE << "Unknown weighting " << type
    1081           0 :                                   << LogIO::EXCEPTION;
    1082           0 :                   return false;
    1083             :           }
    1084           0 :       }
    1085             :          
    1086             :          //// UV-Tapering
    1087             :          //cout << "Taper type : " << filtertype << " : " << (filtertype=="gaussian") <<  endl;
    1088           0 :          if( filtertype == "gaussian" ) {
    1089             :            //      os << "Setting uv-taper" << LogIO::POST;
    1090           0 :            imwgt_p.setFilter( filtertype,  filterbmaj, filterbmin, filterbpa );
    1091             :          }
    1092           0 :          vi_p->useImagingWeight(imwgt_p);
    1093             :       ///////////////////////////////
    1094             :          
    1095           0 :              SynthesisUtilMethods::getResource("Set Weighting");
    1096             : 
    1097             :          ///     return true;
    1098             :          
    1099           0 :        }
    1100           0 :        catch(AipsError &x)
    1101             :          {
    1102           0 :            throw( AipsError("Error in Weighting : "+x.getMesg()) );
    1103           0 :          }
    1104             :        
    1105           0 :        return true;
    1106           0 :   }
    1107             : 
    1108           0 : void SynthesisImagerVi2::appendToMapperList(String imagename,  
    1109             :                                            CoordinateSystem& csys, 
    1110             :                                            IPosition imshape,
    1111             :                                             CountedPtr<refim::FTMachine>& ftm,
    1112             :                                             CountedPtr<refim::FTMachine>& iftm,
    1113             :                                            Quantity distance,
    1114             :                                            Int facets,
    1115             :                                            Int chanchunks,
    1116             :                                            const Bool overwrite,
    1117             :                                            String mappertype,
    1118             :                                            Float padding,
    1119             :                                            uInt ntaylorterms,
    1120             :                                            const Vector<String> &startmodel)
    1121             :     {
    1122           0 :       LogIO log_l(LogOrigin("SynthesisImagerVi2", "appendToMapperList(ftm)"));
    1123             :       //---------------------------------------------
    1124             :       // Some checks..
    1125             :       
    1126           0 :       if(facets > 1 && itsMappers.nMappers() > 0)
    1127           0 :         log_l << "Facetted image has to be the first of multifields" << LogIO::EXCEPTION;
    1128             : 
    1129           0 :      TcleanProcessingInfo procInfo;
    1130           0 :      CompositeNumber cn(uInt(imshape[0] * 2));
    1131             :      // heuristic factors multiplied to imshape based on gridder
    1132           0 :      size_t fudge_factor = 15;
    1133           0 :      if (ftm->name()=="MosaicFTNew") {
    1134           0 :          fudge_factor = 20;
    1135             :      }
    1136           0 :      else if (ftm->name()=="GridFT") {
    1137           0 :          fudge_factor = 9;
    1138             :      }
    1139           0 :      std::tie(procInfo, std::ignore, std::ignore) =
    1140           0 :          nSubCubeFitInMemory(fudge_factor, imshape, padding);
    1141             : 
    1142             :      // chanchunks auto-calculation block, for now still here for awproject (CAS-12204)
    1143           0 :      if(chanchunks<1)
    1144             :         {
    1145           0 :           log_l << "Automatically calculated chanchunks";
    1146           0 :           log_l << " using imshape : " << imshape << LogIO::POST;
    1147             : 
    1148             :           // Do calculation here.
    1149             :           // This runs once per image field (for multi-field imaging)
    1150             :           // This runs once per cube partition, and will see only its own partition's shape
    1151             :                 //chanchunks=1;
    1152             : 
    1153           0 :                 chanchunks = procInfo.chnchnks;
    1154             : 
    1155             :                 /*log_l << "Required memory " << required_mem / nlocal_procs / 1024. / 1024. / 1024.
    1156             :                  << "\nAvailable memory " << memory_avail / 1024. / 1024 / 1024.
    1157             :                  << " (rc: memory fraction " << usr_memfrac << "% rc memory " << usr_mem / 1024.
    1158             :                  << ")\n" << nlocal_procs << " other processes on node\n"
    1159             :                  << "Setting chanchunks to " << chanchunks << LogIO::POST;
    1160             :                 */
    1161             :         }
    1162             :         //record this in gridpars_p
    1163           0 :         gridpars_p.chanchunks=chanchunks;
    1164           0 :       if( imshape.nelements()==4 && imshape[3]<chanchunks )
    1165             :         {
    1166           0 :           log_l << LogIO::WARN << "An image with " << imshape[3] << " channel(s) cannot be divided into " << chanchunks << " chunks. Please set chanchunks=1 or choose chanchunks<nchan." << LogIO::EXCEPTION;
    1167             :         }
    1168             : 
    1169           0 :       if(chanchunks > 1 && itsMappers.nMappers() > 0)
    1170           0 :         log_l << "Channel chunking is currently not supported with multi(outlier)-fields. Please submit a feature request if needed." << LogIO::EXCEPTION;
    1171             : 
    1172           0 :       if(chanchunks > 1) itsDataLoopPerMapper=true;
    1173             :       
    1174           0 :       AlwaysAssert( ( ( ! (ftm->name()=="MosaicFTNew" && mappertype=="imagemosaic") )  && 
    1175             :                       ( ! (ftm->name()=="AWProjectWBFT" && mappertype=="imagemosaic") )) ,
    1176             :                     AipsError );
    1177             :       //---------------------------------------------
    1178             : 
    1179             :       // Create the ImageStore object
    1180           0 :       CountedPtr<SIImageStore> imstor;
    1181           0 :       MSColumns msc(*(mss_p[0]));
    1182           0 :       imstor = createIMStore(imagename, csys, imshape, overwrite,msc, mappertype, ntaylorterms, distance, procInfo, facets, iftm->useWeightImage(), startmodel );
    1183             : 
    1184             :       // Create the Mappers
    1185           0 :       if( facets<2 && chanchunks<2) // One facet. Just add the above imagestore to the mapper list.
    1186             :         {
    1187           0 :           itsMappers.addMapper(  createSIMapper( mappertype, imstor, ftm, iftm, ntaylorterms) );
    1188             :         }
    1189             :       else // This field is facetted. Make a list of reference imstores, and add all to the mapper list.
    1190             :         {
    1191             : 
    1192           0 :           if ( facets>1 && chanchunks==1 )
    1193             :             {
    1194             :               // Make and connect the list.
    1195           0 :               Block<CountedPtr<SIImageStore> > imstorList = createFacetImageStoreList( imstor, facets );
    1196           0 :               for( uInt facet=0; facet<imstorList.nelements(); facet++)
    1197             :                 {
    1198           0 :                   CountedPtr<refim::FTMachine> new_ftm, new_iftm;
    1199           0 :                   if(facet==0){ new_ftm = ftm;  new_iftm = iftm; }
    1200           0 :                   else{ new_ftm=ftm->cloneFTM();  new_iftm=iftm->cloneFTM(); }
    1201             : //                imstorList[facet]->setDataPolFrame(imstor->getDataPolFrame());
    1202           0 :                   itsMappers.addMapper(createSIMapper( mappertype, imstorList[facet], new_ftm, new_iftm, ntaylorterms));
    1203           0 :                 }
    1204           0 :             }// facets
    1205           0 :           else if ( facets==1 && chanchunks>1 )
    1206             :             {
    1207             :               // Make and connect the list.
    1208           0 :               Block<CountedPtr<SIImageStore> > imstorList = createChanChunkImageStoreList( imstor, chanchunks );
    1209           0 :               for( uInt chunk=0; chunk<imstorList.nelements(); chunk++)
    1210             :                 {
    1211             :                   
    1212           0 :                   CountedPtr<refim::FTMachine> new_ftm, new_iftm;
    1213           0 :                   if(chunk==0){ 
    1214           0 :                     new_ftm = ftm;  
    1215           0 :                     new_iftm = iftm; }
    1216             :                   else{ 
    1217           0 :                     new_ftm=ftm->cloneFTM();  
    1218           0 :                     new_iftm=iftm->cloneFTM(); }
    1219           0 :                   imstorList[chunk]->setDataPolFrame(imstor->getDataPolFrame());
    1220           0 :                   itsMappers.addMapper(createSIMapper( mappertype, imstorList[chunk], new_ftm, new_iftm, ntaylorterms));
    1221           0 :                 }
    1222           0 :             }// chanchunks
    1223             :           else
    1224             :             {
    1225           0 :               throw( AipsError("Error in requesting "+String::toString(facets)+" facets on a side with " + String::toString(chanchunks) + " channel chunks.  Support for faceting along with channel chunking is not yet available. Please submit a feature-request if you need multiple facets as well as chanchunks. ") );
    1226             :             }
    1227             : 
    1228             :         }// facets or chunks
    1229             : 
    1230           0 :     }
    1231             : 
    1232             :   /////////////////////////
    1233             :   /**
    1234             :    * Calculations of memory required / available -> nchunks .
    1235             :    *
    1236             :    * Returns a tuple with a TcleanProcessingInfo, vector of start channels per subchunk,
    1237             :    * vector of end channels.
    1238             :    */
    1239           0 :   std::tuple<TcleanProcessingInfo, Vector<Int>, Vector<Int> > SynthesisImagerVi2::nSubCubeFitInMemory(const Int fudge_factor, const IPosition& imshape, const Float padding){
    1240           0 :         LogIO log_l(LogOrigin("SynthesisImagerVi2", "nSubCubeFitInMemory"));
    1241             : 
    1242           0 :         Double required_mem = fudge_factor * sizeof(Float);
    1243           0 :         int nsubcube=1;
    1244           0 :         CompositeNumber cn(uInt(imshape[0] * 2));
    1245           0 :         for (size_t i = 0; i < imshape.nelements(); i++) {
    1246             :                         // gridding pads image and increases to composite number
    1247           0 :                         if (i < 2) {
    1248           0 :                                 required_mem *= cn.nextLargerEven(Int(padding*Float(imshape[i])-0.5));
    1249             :                         }
    1250             :                         else {
    1251           0 :                                 required_mem *= imshape[i];
    1252             :                         }
    1253             :         }
    1254             : 
    1255             :         // get number of tclean processes running on the same machine
    1256           0 :         size_t nlocal_procs = 1;
    1257           0 :         if (getenv("OMPI_COMM_WORLD_LOCAL_SIZE")) {
    1258           0 :                 std::stringstream ss(getenv("OMPI_COMM_WORLD_LOCAL_SIZE"));
    1259           0 :                 ss >> nlocal_procs;
    1260           0 :         }
    1261             :         //cerr << "NUM_PROC " << nlocal_procs << endl;
    1262             :         // assumes all processes need the same amount of memory
    1263           0 :         required_mem *= nlocal_procs;
    1264             :         Double usr_memfrac, usr_mem;
    1265           0 :         AipsrcValue<Double>::find(usr_memfrac, "system.resources.memfrac", 80.);
    1266           0 :         AipsrcValue<Double>::find(usr_mem, "system.resources.memory", -1.);
    1267             :         Double memory_avail;
    1268           0 :         if (usr_mem > 0.) {
    1269           0 :                 memory_avail = usr_mem * 1024. * 1024.;
    1270             :         }
    1271             :         else {
    1272           0 :             memory_avail = Double(HostInfo::memoryFree()) * (usr_memfrac / 100.) * 1024.;
    1273             :         }
    1274             :         // compute required chanchunks to fit into the available memory
    1275           0 :         nsubcube = (int)std::ceil((Double)required_mem / memory_avail);
    1276           0 :         Int nworkers= applicator.numProcs() < 2 ? 1 : applicator.numProcs()-1;
    1277           0 :         if((nsubcube/nworkers) >1 && nworkers !=1){
    1278           0 :           nsubcube=(Int(std::floor(Float(nsubcube)/Float(nworkers)))+1)*nworkers;
    1279             : 
    1280             :         }
    1281           0 :         if (imshape.nelements() == 4 && imshape[3] < nsubcube) {
    1282           0 :                 nsubcube = imshape[3];
    1283             :               // TODO make chanchunks a divisor of nchannels?
    1284             :         }
    1285           0 :         nsubcube = nsubcube < 1 ? 1 : nsubcube;
    1286           0 :         if( (imshape[3] >= nworkers) && (nsubcube < nworkers)){
    1287           0 :           nsubcube=nworkers;
    1288             :           ///TESTOO
    1289             :           //if(imshape[3] > 2*nworkers)
    1290             :           //  nsubcube=2*nworkers;
    1291             : 
    1292             :         }
    1293           0 :          else if(imshape[3] < (applicator.numProcs()-1)){
    1294           0 :                 nsubcube=imshape[3]; 
    1295             :          }
    1296           0 :         Int chunksize=imshape[3]/nsubcube;
    1297           0 :         Int rem=imshape[3] % nsubcube;
    1298             :         //case of nchan < numprocs
    1299           0 :         if(chunksize==0 && rem > 0){
    1300           0 :                 nsubcube=rem;
    1301           0 :                 chunksize=1;
    1302           0 :                 rem=0;
    1303             :         }
    1304             :         ///Avoid an extra chunk with 1 channel as it cause bumps in linear interpolation
    1305             :         ///See CAS-12625
    1306             :         /*
    1307             :         while((rem==1) && (chunksize >1)){
    1308             :                 nsubcube +=1;
    1309             :                 chunksize=imshape[3]/nsubcube;
    1310             :                 rem=imshape[3] % nsubcube;
    1311             :         }
    1312             :         if(rem !=0) ++nsubcube;
    1313             :         . */
    1314           0 :         Vector<Int> start(nsubcube,0);
    1315           0 :         Vector<Int> end(nsubcube,chunksize-1);
    1316           0 :         if(rem >0){
    1317           0 :           end(0)+=1;
    1318           0 :           --rem;
    1319             :         }
    1320           0 :         for (Int k=1; k < nsubcube; ++k){
    1321           0 :                 start(k)=end(k-1)+1;
    1322             :                 //      end(k)=((k !=nsubcube-1) || rem==0)? (start(k)+chunksize-1) : (start(k)+rem-1);
    1323           0 :                 end(k)=(start(k)+chunksize-1);
    1324           0 :                 if(rem > 0){
    1325           0 :                   end(k)+=1;
    1326           0 :                   --rem;
    1327             :                 }
    1328             :         }
    1329             : 
    1330             :         // print mem related info to log
    1331           0 :         const float toGB = 1024.0 * 1024.0 * 1024.0;
    1332           0 :         std::ostringstream usr_mem_msg;
    1333           0 :         if (usr_mem > 0.) {
    1334           0 :             usr_mem_msg << usr_mem / 1024.;
    1335             :         } else {
    1336           0 :             usr_mem_msg << "-";
    1337             :         }
    1338           0 :         std::ostringstream oss;
    1339           0 :         oss << setprecision(4);
    1340           0 :         oss << "Required memory: " << required_mem / toGB
    1341           0 :             << " GB. Available mem.: " << memory_avail / toGB
    1342           0 :             << " GB (rc, mem. fraction: " << usr_memfrac
    1343           0 :             << "%, memory: " << usr_mem_msg.str()
    1344           0 :             << ") => Subcubes: " << nsubcube
    1345           0 :             << ". Processes on node: " << nlocal_procs << ".\n";
    1346           0 :         log_l << oss.str() << LogIO::POST;
    1347             : 
    1348           0 :         TcleanProcessingInfo procInfo;
    1349           0 :         procInfo.mpiprocs = nlocal_procs;
    1350           0 :         procInfo.chnchnks = nsubcube;
    1351           0 :         procInfo.memavail = memory_avail / toGB;
    1352           0 :         procInfo.memreq = required_mem / toGB;
    1353           0 :         return make_tuple(procInfo, start, end);
    1354           0 :   }
    1355             :   
    1356           0 :  void SynthesisImagerVi2::runMajorCycleCube( const Bool dopsf, 
    1357             :                                       const Record inpcontrol) {
    1358           0 :         LogIO os( LogOrigin("SynthesisImagerVi2","runMajorCycleCube",WHERE) );                
    1359           0 :         if(dopsf){
    1360           0 :           runCubeGridding(True);
    1361             :           ///Store the beamsets in ImageInfo
    1362           0 :           for(Int k=0; k < itsMappers.nMappers(); ++k){
    1363             :            
    1364           0 :             (itsMappers.imageStore(k))->getBeamSet();
    1365             :           }
    1366             :         }
    1367             :         else
    1368           0 :                 runCubeGridding(False, inpcontrol);
    1369             :         
    1370             :                           
    1371             :                           
    1372           0 :         }
    1373           0 :  void SynthesisImagerVi2::runMajorCycle(const Bool dopsf, 
    1374             :                                       const Bool savemodel)
    1375             :   {
    1376           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","runMajorCycle",WHERE) );
    1377             : 
    1378             :     //    cout << "Savemodel : " << savemodel << "   readonly : " << readOnly_p << "   usescratch : " << useScratch_p << endl;
    1379           0 :     Bool savemodelcolumn = savemodel && !readOnly_p && useScratch_p;
    1380           0 :     Bool savevirtualmodel = savemodel && !readOnly_p && !useScratch_p;
    1381             : 
    1382           0 :     if( savemodelcolumn ) os << "Saving model column" << LogIO::POST;
    1383           0 :     if( savevirtualmodel ) os << "Saving virtual model" << LogIO::POST;
    1384             : 
    1385           0 :     SynthesisUtilMethods::getResource("Start Major Cycle");
    1386             : 
    1387           0 :     itsMappers.checkOverlappingModels("blank");
    1388             : 
    1389             :     {
    1390           0 :       vi::VisBuffer2* vb=vi_p->getVisBuffer();
    1391           0 :       vi_p->originChunks();
    1392           0 :       vi_p->origin();
    1393           0 :       Double numcoh=0;
    1394           0 :       for (uInt k=0; k< mss_p.nelements(); ++k)
    1395           0 :         numcoh+=Double(mss_p[k]->nrow());
    1396             :       ProgressMeter pm(1.0, numcoh, 
    1397           0 :                          dopsf?"Gridding Weights and PSF":"Major Cycle", "","","",true);
    1398           0 :       rownr_t cohDone=0;
    1399             : 
    1400             : 
    1401           0 :         if(!dopsf)itsMappers.initializeDegrid(*vb);
    1402           0 :         itsMappers.initializeGrid(*vi_p,dopsf);
    1403           0 :         SynthesisUtilMethods::getResource("After initGrid for all mappers");
    1404             :         ////Under some peculiar selection criterion and low channel ms  vb2 seems to return more channels than in spw
    1405             :         {
    1406           0 :           vi_p->originChunks();
    1407           0 :           vi_p->origin();
    1408           0 :           Int nchannow=vb->nChannels();
    1409           0 :           Int spwnow=vb->spectralWindows()[0];
    1410           0 :           Int nchaninms=MSColumns(vb->ms()).spectralWindow().numChan()(spwnow);
    1411             :           //cerr << "chans " << nchaninms << "   " << nchannow << endl;
    1412             :          
    1413           0 :           if (nchaninms < nchannow){
    1414           0 :             cerr << "NCHANS ms" << nchaninms << " now " << nchannow << " spw " << spwnow << "   " << vb->spectralWindows() << endl;
    1415           0 :             throw(AipsError("A nasty Visbuffer2 error occured...wait for CNGI"));
    1416             :           }
    1417             :         }
    1418             :           //////
    1419           0 :         for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    1420             :         {
    1421             : 
    1422           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    1423             :                 {
    1424             :                   //if (SynthesisUtilMethods::validate(*vb)==SynthesisUtilMethods::NOVALIDROWS) break; // No valid rows in this VB
    1425             :                   //              cerr << "nRows "<< vb->nRow() << "   " << max(vb->visCube()) <<  endl;
    1426           0 :                   if (SynthesisUtilMethods::validate(*vb)!=SynthesisUtilMethods::NOVALIDROWS)
    1427             :                     {
    1428           0 :                         if(!dopsf) {
    1429           0 :                           { Cube<Complex> mod(vb->nCorrelations(), vb->nChannels(), vb->nRows(), Complex(0.0));
    1430           0 :                             vb->setVisCubeModel(mod); 
    1431           0 :                           }
    1432           0 :                           itsMappers.degrid(*vb, savevirtualmodel );
    1433           0 :                           if(savemodelcolumn && writeAccess_p ){        
    1434           0 :                                 const_cast<MeasurementSet& >((vi_p->ms())).lock(true);
    1435           0 :                             vi_p->writeVisModel(vb->visCubeModel());
    1436           0 :                                 const_cast<MeasurementSet& >((vi_p->ms())).unlock();
    1437             :                                 
    1438             :                             //static_cast<VisibilityIteratorImpl2 *> (vi_p->getImpl())->writeVisModel(vb->visCubeModel());
    1439             : 
    1440             :                             // Cube<Complex> tt=vb->visCubeModel();
    1441             :                             // tt = 20.0;
    1442             :                             // cout << "Vis:" << tt << endl;
    1443             :                             // static_cast<VisibilityIteratorImpl2 *> (vi_p->getImpl())->writeVisModel(tt);
    1444             :                           }
    1445             :                         }
    1446           0 :                         itsMappers.grid(*vb, dopsf, (refim::FTMachine::Type)datacol_p);
    1447             :                         
    1448           0 :                         cohDone += vb->nRows();
    1449           0 :                         pm.update(Double(cohDone));
    1450             :                     }
    1451             :                 }
    1452             :         }
    1453             : 
    1454             :         // cerr << "VI2 data: " << cohDone << endl;
    1455             :         // exit(0);
    1456             :         //cerr << "IN SYNTHE_IMA" << endl;
    1457             :         //VisModelData::listModel(rvi_p->getMeasurementSet());
    1458           0 :         SynthesisUtilMethods::getResource("Before finalize for all mappers");
    1459           0 :         if(!dopsf) itsMappers.finalizeDegrid(*vb);
    1460           0 :         itsMappers.finalizeGrid(*vb, dopsf);
    1461             : 
    1462           0 :     }
    1463             : 
    1464           0 :     itsMappers.checkOverlappingModels("restore");
    1465             : 
    1466           0 :     unlockMSs();
    1467             : 
    1468           0 :     SynthesisUtilMethods::getResource("End Major Cycle");
    1469             : 
    1470           0 :   }// end runMajorCycle
    1471             : 
    1472             :  
    1473             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    1474             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    1475             : 
    1476             :   /// The mapper loop is outside the data iterator loop.
    1477             :   /// This is for cases where the image size is large compared to the RAM and
    1478             :   /// where data I/O is the relatively minor cost.
    1479           0 :   void SynthesisImagerVi2::runMajorCycle2(const Bool dopsf, 
    1480             :                                       const Bool savemodel)
    1481             :   {
    1482           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","runMajorCycle2",WHERE) );
    1483             : 
    1484             :     //    cout << "Savemodel : " << savemodel << "   readonly : " << readOnly_p << "   usescratch : " << useScratch_p << endl;
    1485             : 
    1486           0 :     Bool savemodelcolumn = savemodel && !readOnly_p && useScratch_p;
    1487           0 :     Bool savevirtualmodel = savemodel && !readOnly_p && !useScratch_p;
    1488             : 
    1489           0 :     if( savemodelcolumn ) os << "Saving model column" << LogIO::POST;
    1490           0 :     if( savevirtualmodel ) os << "Saving virtual model" << LogIO::POST;
    1491             : 
    1492           0 :     itsMappers.checkOverlappingModels("blank");
    1493             : 
    1494           0 :     Bool resetModel=False;
    1495           0 :     if( savemodelcolumn && writeAccess_p)
    1496             :       {
    1497           0 :         resetModel=True;
    1498           0 :         os << "Iterating through the model column to reset it to zero" << LogIO::POST;
    1499           0 :         vi::VisBuffer2* vb=vi_p->getVisBuffer();
    1500           0 :         vi_p->originChunks();
    1501           0 :         vi_p->origin();
    1502           0 :         Double numcoh=0;
    1503           0 :         for (uInt k=0; k< mss_p.nelements(); ++k)
    1504           0 :           numcoh+=Double(mss_p[k]->nrow());
    1505             :         ProgressMeter pm(1.0, numcoh, 
    1506           0 :                          dopsf?"Seting model column to zero":"pre-Major Cycle", "","","",True);
    1507           0 :         rownr_t cohDone=0;
    1508           0 :         for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    1509             :           {
    1510             :             
    1511           0 :             for (vi_p->origin(); vi_p->more(); vi_p->next())
    1512             :               {
    1513           0 :                 if (SynthesisUtilMethods::validate(*vb)!=SynthesisUtilMethods::NOVALIDROWS)
    1514             :                   {
    1515           0 :                     { Cube<Complex> mod(vb->nCorrelations(), vb->nChannels(), vb->nRows(), Complex(0.0));
    1516           0 :                             vb->setVisCubeModel(mod); 
    1517           0 :                     }
    1518           0 :                     vi_p->writeVisModel(vb->visCubeModel());
    1519             :                     
    1520             :                   }
    1521           0 :                 cohDone += vb->nRows();;
    1522           0 :                 pm.update(Double(cohDone));
    1523             :               }
    1524             :           }
    1525           0 :       }// setting model to zero
    1526             : 
    1527             :     //Need to inialize the the forward ft machine to save the virtual model on first pass of each ms.
    1528           0 :     if(!dopsf && savevirtualmodel){
    1529           0 :       vi::VisBuffer2* vb=vi_p->getVisBuffer();
    1530           0 :       vi_p->originChunks();
    1531           0 :       vi_p->origin();
    1532           0 :       itsMappers.initializeDegrid(*vb, -1);
    1533             :     }
    1534             :     
    1535           0 :     for(Int gmap=0;gmap<itsMappers.nMappers();gmap++)
    1536             :        {
    1537           0 :          os << "Running major cycle for chunk : " << gmap << LogIO::POST;
    1538             : 
    1539           0 :          SynthesisUtilMethods::getResource("Start Major Cycle for mapper"+String::toString(gmap));
    1540           0 :          CountedPtr<vi::FrequencySelections> copyFsels=fselections_p->clone();
    1541             :          ///CAS-12132  create a new visiter for each chunk
    1542           0 :          createVisSet(writeAccess_p);
    1543             :          ////////////////////////
    1544           0 :          vi::VisBuffer2* vb=vi_p->getVisBuffer();
    1545             :          /// Careful where tunechunk 
    1546           0 :          tuneChunk(gmap);
    1547             : 
    1548           0 :          vi_p->originChunks();
    1549           0 :          vi_p->origin();
    1550             : 
    1551           0 :          Double numcoh=0;
    1552           0 :          for (uInt k=0; k< mss_p.nelements(); ++k)
    1553           0 :            numcoh+=Double(mss_p[k]->nrow());
    1554             : 
    1555             : 
    1556             :          ProgressMeter pm(1.0, numcoh, 
    1557           0 :                           dopsf?"Gridding Weights and PSF":"Major Cycle", "","","",true);
    1558           0 :         rownr_t cohDone=0;
    1559             : 
    1560             : 
    1561           0 :         itsMappers.getFTM2(gmap, False)->reset();
    1562           0 :         itsMappers.getFTM2(gmap, True)->reset();
    1563             : 
    1564           0 :         if(!dopsf){
    1565           0 :           itsMappers.initializeDegrid(*vb, gmap);
    1566             :                   //itsMappers.getMapper(gmap)->initializeDegrid(*vb);
    1567             :         }
    1568           0 :         itsMappers.initializeGrid(*vi_p,dopsf, gmap);
    1569             :                 //itsMappers.getMapper(gmap)->initializeGrid(*vb,dopsf);
    1570             : 
    1571           0 :         SynthesisUtilMethods::getResource("After initialize for mapper"+String::toString(gmap));
    1572           0 :         Int iterNum=0;
    1573             : 
    1574             :         
    1575           0 :         for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    1576             :         {
    1577             : 
    1578           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    1579             :             {
    1580             :               //if (SynthesisUtilMethods::validate(*vb)==SynthesisUtilMethods::NOVALIDROWS) break; // No valid rows in this VB
    1581             :               //                  cerr << "nRows "<< vb->nRow() << "   " << max(vb->visCube()) <<  endl;
    1582           0 :               if (SynthesisUtilMethods::validate(*vb)!=SynthesisUtilMethods::NOVALIDROWS)
    1583             :                 {
    1584             :                   
    1585           0 :                   if(!dopsf) {
    1586           0 :                     if(resetModel==False) 
    1587             :                       { 
    1588           0 :                         Cube<Complex> mod(vb->nCorrelations(), vb->nChannels(), vb->nRows(), Complex(0.0));
    1589           0 :                         vb->setVisCubeModel(mod); 
    1590           0 :                       }
    1591           0 :                     itsMappers.degrid(*vb, savevirtualmodel, gmap );
    1592             :                     //itsMappers.getMapper(gmap)->degrid(*vb); //, savevirtualmodel );
    1593           0 :                     if(savemodelcolumn && writeAccess_p ){
    1594           0 :                       vi_p->writeVisModel(vb->visCubeModel());
    1595             :                       //vi_p->writeBackChanges(vb);
    1596             :                       // static_cast<VisibilityIteratorImpl2 *> (vi_p->getImpl())->writeVisModel(vb->visCubeModel());
    1597             :                     }
    1598             : 
    1599             :                   }
    1600           0 :                   itsMappers.grid(*vb, dopsf, (refim::FTMachine::Type)(datacol_p), gmap);
    1601             :                   //itsMappers.getMapper(gmap)->grid(*vb, dopsf, datacol_p);
    1602           0 :                   cohDone += vb->nRows();
    1603           0 :                   ++iterNum;
    1604           0 :                   pm.update(Double(cohDone));
    1605             :                 }
    1606             :             }
    1607             :         }
    1608             :         //cerr << "IN SYNTHE_IMA" << endl;
    1609             :         //VisModelData::listModel(rvi_p->getMeasurementSet());
    1610             : 
    1611           0 :         SynthesisUtilMethods::getResource("Before finalize for mapper"+String::toString(gmap));
    1612             :         
    1613           0 :         if(!dopsf) 
    1614             :           {
    1615           0 :             itsMappers.finalizeDegrid(*vb,gmap);
    1616             :             //itsMappers.getMapper(gmap)->finalizeDegrid();
    1617             :           }
    1618           0 :         itsMappers.finalizeGrid(*vb, dopsf,gmap);
    1619             :         //itsMappers.getMapper(gmap)->finalizeGrid(*vb, dopsf);
    1620             :         
    1621             :         //      itsMappers.getMapper(gmap)->releaseImageLocks();
    1622           0 :         itsMappers.getMapper(gmap)->imageStore()->releaseComplexGrids();        
    1623             :         
    1624           0 :         SynthesisUtilMethods::getResource("End Major Cycle for mapper"+String::toString(gmap));
    1625           0 :         fselections_p=copyFsels;
    1626           0 :        }// end of mapper loop
    1627             :     ///CAS-12132  create a new visiter for each chunk
    1628           0 :     createVisSet(writeAccess_p);
    1629             :     ////////////////////////
    1630             :     //////vi_p->setFrequencySelection(*fselections_p);
    1631             : 
    1632           0 :     itsMappers.checkOverlappingModels("restore");
    1633             : 
    1634           0 :     unlockMSs();
    1635             : 
    1636           0 :     SynthesisUtilMethods::getResource("End Major Cycle");
    1637             : 
    1638           0 :   }// end runMajorCycle2
    1639             : 
    1640             : //////////////////////////////
    1641             :  
    1642             :   ////////////////////////////////////////////////////////////////////////////////////////////////
    1643             : 
    1644           0 :   bool SynthesisImagerVi2::runCubeGridding(Bool dopsf, const Record inpcontrol){
    1645             : 
    1646           0 :         LogIO logger(LogOrigin("SynthesisImagerVi2", "runCubeGridding", WHERE));
    1647             : 
    1648             :           //dummy for now as init is overloaded on this signature
    1649           0 :         int argc=1;
    1650           0 :         char **argv=nullptr;
    1651           0 :         casa::applicator.init ( argc, argv );
    1652             :           //For serial or master only
    1653           0 :         if ( applicator.isController() ) {
    1654           0 :                 CubeMajorCycleAlgorithm cmc;
    1655             :                 //casa::applicator.defineAlgorithm(cmc);
    1656             :                 //Initialize everything to get the setup as serial
    1657             :                 {
    1658             :                 
    1659           0 :                         vi_p->originChunks();
    1660           0 :                         vi_p->origin();
    1661             :                 
    1662             :                 }
    1663             :                 ///Break things into chunks for parallelization or memory availabbility
    1664           0 :                 Vector<Int> startchan;
    1665           0 :                 Vector<Int> endchan; 
    1666             :                 Int numchunks;
    1667           0 :                 Int fudge_factor = 15;
    1668           0 :                 if ((itsMappers.getFTM2(0))->name()=="MosaicFTNew") {
    1669           0 :                         fudge_factor = 20;
    1670             :                 }
    1671           0 :                 else if ((itsMappers.getFTM2(0))->name()=="GridFT") {
    1672           0 :                         fudge_factor = 9;
    1673             :                 }
    1674           0 :                 TcleanProcessingInfo procInfo;
    1675           0 :                 std::tie(procInfo, startchan, endchan)=nSubCubeFitInMemory(fudge_factor, itsMaxShape, gridpars_p.padding);
    1676           0 :                 numchunks = procInfo.chnchnks;
    1677             :                 ////TESTOO
    1678             :                 //numchunks=2;
    1679             :                 //startchan.resize(2);startchan[0]=0; startchan[1]=2;
    1680             :                 //endchan.resize(2); endchan[0]=1; endchan[1]=2;
    1681             :                 
    1682             :                 /////END TESTOO
    1683             :                 //cerr << "NUMCHUNKS " << numchunks << " start " <<  startchan << " end " << endchan << endl;
    1684           0 :                 Record controlRecord=inpcontrol;
    1685             :                 //For now just field 0 but should loop over all
    1686             :                 ///This is to pass in explicit model, residual names etc
    1687           0 :                 controlRecord.define("nfields", Int(imparsVec_p.nelements()));
    1688             :         //CountedPtr<SIImageStore> imstor = imageStore ( 0 );
    1689             :         // checking that psf,  residual and sumwt is allDone
    1690             :         //cerr << "shapes "  <<  imstor->residual()->shape() <<  " " <<  imstor->sumwt()->shape() <<  endl;
    1691           0 :                 if(!dopsf){
    1692             :                         
    1693             :                   //controlRecord.define("lastcycle",  savemodel);
    1694           0 :                   controlRecord.define("nmajorcycles", nMajorCycles);
    1695           0 :                         Vector<String> modelnames(Int(imparsVec_p.nelements()),"");
    1696           0 :                         for(uInt k=0; k < imparsVec_p.nelements(); ++k){
    1697           0 :                                 Int imageStoreId=k;
    1698           0 :                                 if(k>0){
    1699           0 :                                         if(gridparsVec_p[0].chanchunks >1 && uInt(itsMappers.nMappers()) >=    (gridparsVec_p[0].chanchunks + gridparsVec_p.nelements()))
    1700           0 :                                                 imageStoreId+=gridparsVec_p[0].chanchunks-1;
    1701           0 :                                         if(gridparsVec_p[0].facets >1)
    1702           0 :                                                 imageStoreId+=gridparsVec_p[0].facets*gridparsVec_p[0].facets-1;
    1703             :                                 }
    1704           0 :                                 if((itsMappers.imageStore(imageStoreId))->hasModel()){
    1705           0 :                                         modelnames(k)=imparsVec_p[k].imageName+".model";
    1706           0 :                                         (itsMappers.imageStore(k))->model()->unlock();
    1707           0 :                                         controlRecord.define("modelnames", modelnames);
    1708             :                                 }
    1709             :                         }
    1710             :                         
    1711           0 :                 }
    1712           0 :                 Vector<String> weightnames(Int(imparsVec_p.nelements()),"");
    1713           0 :                 Vector<String> pbnames(Int(imparsVec_p.nelements()),"");
    1714           0 :                 for(uInt k=0; k < imparsVec_p.nelements(); ++k){
    1715           0 :                         Int imageStoreId=k;
    1716           0 :                         if(k>0){
    1717           0 :                                         if(gridparsVec_p[0].chanchunks >1 && uInt(itsMappers.nMappers()) >=    (gridparsVec_p[0].chanchunks + gridparsVec_p.nelements()))
    1718           0 :                                                 imageStoreId+=gridparsVec_p[0].chanchunks-1;
    1719           0 :                                         if(gridparsVec_p[0].facets >1)
    1720           0 :                                                 imageStoreId+=gridparsVec_p[0].facets*gridparsVec_p[0].facets-1;
    1721             :                                 }
    1722             :                         //cerr << "FTMachine name " << (itsMappers.getFTM2(imageStoreId))->name() << endl;
    1723           0 :                         if((itsMappers.getFTM2(imageStoreId))->useWeightImage()){
    1724             :                           //cerr << "Mosaic weight image " << max(itsMappers.imageStore(imageStoreId)->weight(k)->get()) << endl;
    1725           0 :                                 weightnames(k)=itsMappers.imageStore(imageStoreId)->weight(k)->name();
    1726             :                                 
    1727             :                                 
    1728             :                         }
    1729           0 :                         if(itsMakeVP){
    1730           0 :                           pbnames(k)=itsMappers.imageStore(imageStoreId)->pb(k)->name();
    1731           0 :                            (itsMappers.imageStore(imageStoreId)->pb(k))->unlock();
    1732             :                         }
    1733             :                 }
    1734           0 :                 controlRecord.define("weightnames", weightnames);
    1735           0 :                 controlRecord.define("pbnames", pbnames);
    1736             :         // Tell the child processes not to do the dividebyweight process as this is done
    1737             :                 // tell each child to do the normars stuff
    1738           0 :                 controlRecord.define("dividebyweight",  True);
    1739           0 :                 controlRecord.defineRecord("normpars", normpars_p); 
    1740             :                 ///Let's see if no per chan weight density was chosen
    1741           0 :                 String weightdensityimage=getWeightDensity();
    1742           0 :                 if(weightdensityimage != "")
    1743           0 :                         controlRecord.define("weightdensity", weightdensityimage);
    1744             :         
    1745           0 :                 Record vecSelParsRec, vecImParsRec, vecGridParsRec;
    1746           0 :                 Vector<Int>vecRange(2);
    1747           0 :                 for (uInt k = 0; k < dataSel_p.nelements(); ++k) {
    1748           0 :                         Record selparsRec = dataSel_p[k].toRecord();
    1749           0 :                         vecSelParsRec.defineRecord(String::toString(k), selparsRec);
    1750           0 :                 }
    1751           0 :                 for (uInt k=0; k < imparsVec_p.nelements(); ++k){
    1752           0 :                         Record imparsRec = imparsVec_p[k].toRecord();
    1753             :                         //need to send polrep
    1754           0 :                         imparsRec.define("polrep", Int((itsMappers.imageStore(k))->getDataPolFrame()));
    1755             :                         //need to send movingSourceName if any
    1756           0 :                         imparsRec.define("movingsource", movingSource_p);
    1757           0 :                         Record gridparsRec = gridparsVec_p[k].toRecord();
    1758             :                         /* Might need this to pass the state of the global ftmachines...test for parallel when needed
    1759             :                         String err;
    1760             :                         Record ftmrec, iftmrec;
    1761             :                         if(!( (itsMappers.getFTM2(k)->toRecord(err, iftmrec,False)) && (itsMappers.getFTM2(k, false)->toRecord(err, ftmrec,False))))
    1762             :                                 throw(AipsError("FTMachines serialization failed"));
    1763             :                         gridparsRec.defineRecord("ftmachine", ftmrec);
    1764             :                         gridparsRec.defineRecord("iftmachine", iftmrec);
    1765             :                         */
    1766           0 :                         vecImParsRec.defineRecord(String::toString(k), imparsRec);
    1767           0 :                         vecGridParsRec.defineRecord(String::toString(k), gridparsRec);
    1768           0 :                 }
    1769           0 :                 String workingdir="";
    1770             :                 //Int numchan=(dopsf) ? imstor->psf()->shape()[3] : imstor->residual()->shape() [3];
    1771             :                 //copy the imageinfo of main image here
    1772           0 :                 if(dopsf)
    1773           0 :                   cubePsfImageInfo_p=(itsMappers.imageStore(0)->psf())->imageInfo();
    1774           0 :         for(Int k=0; k < itsMappers.nMappers(); ++k){
    1775             :          
    1776           0 :                         if(dopsf){
    1777             :                            
    1778           0 :                                 for(uInt j =0; j <(itsMappers.imageStore(k)->getNTaylorTerms(true)); ++j){
    1779             :                                   ///TESTOO
    1780             :                                   //(itsMappers.imageStore(k))->psf(j)->set(0.0);
    1781             :                                   /////////
    1782           0 :                                         (itsMappers.imageStore(k))->psf(j)->unlock();
    1783           0 :                                         (itsMappers.imageStore(k))->pb()->unlock();
    1784             :                                 }
    1785             :                         }
    1786             :                         else{
    1787           0 :                                 for(uInt j =0; j <(itsMappers.imageStore(k)->getNTaylorTerms(false)); ++j){
    1788             :                                   /////////TESTOO
    1789             :                                   //(itsMappers.imageStore(k))->residual(j)->set(0.0);
    1790             :                                     ///////
    1791           0 :                                         (itsMappers.imageStore(k))->residual(j)->unlock();
    1792             :                                 }
    1793             :                         }
    1794           0 :                         for(uInt j =0; j <(itsMappers.imageStore(k)->getNTaylorTerms(true)); ++j){
    1795             :                         //cerr << k << " type " << (itsMappers.imageStore(k))->sumwt(j)->imageType() << " name " << (itsMappers.imageStore(k))->sumwt(j)->name() << endl;
    1796             :                                 
    1797             :                                
    1798           0 :                                 Path namewgt( (itsMappers.imageStore(k))->sumwt(j)->name());
    1799           0 :                                 workingdir=namewgt.dirName();
    1800             :                                 ///TESTOO
    1801             :                                 //(itsMappers.imageStore(k))->sumwt(j)->set(0.0);
    1802             :                                 ////
    1803           0 :                                 (itsMappers.imageStore(k))->sumwt(j)->unlock();
    1804             :                                 //(itsMappers.imageStore(k))->releaseLocks();
    1805           0 :                         }
    1806           0 :                         (itsMappers.imageStore(k))->releaseLocks();   
    1807             :         }               
    1808             :                 //Send the working directory as the child and master may be at different places
    1809             :                 
    1810           0 :                 controlRecord.define("workingdirectory", workingdir);
    1811             :                 // For now this contains lastcycle if necessary in the future this
    1812             :                 // should come from the master control record
    1813             :         
    1814             :                 //Int numprocs = applicator.numProcs();
    1815             :         //cerr << "Number of procs: " << numprocs << endl;
    1816           0 :         Int rank ( 0 );
    1817             :         Bool assigned; //(casa::casa::applicator.nextAvailProcess(pwrite, rank));
    1818           0 :         Bool allDone ( false );
    1819           0 :         Vector<Bool> retvals(numchunks, False);
    1820           0 :         Int indexofretval=0;
    1821           0 :         for ( Int k=0; k < numchunks; ++k ) {
    1822           0 :             assigned=casa::applicator.nextAvailProcess ( cmc, rank );
    1823             :             //cerr << "assigned "<< assigned << endl;
    1824           0 :             while ( !assigned ) {
    1825           0 :                 rank = casa::applicator.nextProcessDone ( cmc, allDone );
    1826             :                 //cerr << "while rank " << rank << endl;
    1827             :                 Bool status;
    1828           0 :                 Record returnRec;
    1829           0 :                 casa::applicator.get(returnRec);
    1830           0 :                 casa::applicator.get ( status );
    1831           0 :                 retvals(indexofretval)=status;
    1832           0 :                 if(dopsf)
    1833           0 :                   updateImageBeamSet(returnRec);
    1834           0 :                 if(returnRec.isDefined("tempfilenames")){
    1835           0 :                   std::vector<String> b=returnRec.asArrayString("tempfilenames").tovector();
    1836           0 :                   tempFileNames_p.insert(std::end(tempFileNames_p), std::begin(b), std::end(b));
    1837           0 :                 }
    1838             :                   
    1839           0 :                 ++indexofretval;
    1840           0 :                 if ( status )
    1841             :                   //cerr << k << " rank " << rank << " successful " << endl;
    1842           0 :                   cerr << "" ;
    1843             :                 else
    1844           0 :                     logger << LogIO::SEVERE << k << " rank " << rank << " failed " << LogIO::POST;
    1845           0 :                 assigned = casa::applicator.nextAvailProcess ( cmc, rank );
    1846             : 
    1847           0 :             }
    1848             : 
    1849             :             ///send process info
    1850             :             // put data sel params #1
    1851           0 :             applicator.put ( vecSelParsRec );
    1852             :             // put image sel params #2
    1853           0 :             applicator.put ( vecImParsRec );
    1854             :             // put gridders params #3
    1855           0 :             applicator.put ( vecGridParsRec );
    1856             :             // put which channel to process #4
    1857           0 :                         vecRange(0)=startchan(k);
    1858           0 :                         vecRange(1)=endchan(k);
    1859           0 :             applicator.put ( vecRange );
    1860             :             // psf or residual CubeMajorCycleAlgorithm #5
    1861           0 :             applicator.put ( dopsf );
    1862             :             // store modelvis and other controls #6
    1863           0 :             applicator.put ( controlRecord );
    1864             :                         // weighting scheme #7
    1865           0 :                         applicator.put( weightParams_p);
    1866             :             /// Tell worker to process it
    1867           0 :             applicator.apply ( cmc );
    1868             : 
    1869             :         }
    1870             :         // Wait for all outstanding processes to return
    1871           0 :         rank = casa::applicator.nextProcessDone ( cmc, allDone );
    1872           0 :         while ( !allDone ) {
    1873             :             Bool status;
    1874           0 :             Record returnRec;
    1875           0 :             casa::applicator.get(returnRec);
    1876           0 :             casa::applicator.get ( status );
    1877           0 :             if(dopsf)
    1878           0 :               updateImageBeamSet(returnRec);
    1879           0 :             if(returnRec.isDefined("tempfilenames")){
    1880           0 :               std::vector<String> b=returnRec.asArrayString("tempfilenames").tovector();
    1881           0 :               tempFileNames_p.insert(std::end(tempFileNames_p), std::begin(b), std::end(b));
    1882           0 :             }
    1883           0 :             retvals(indexofretval)=status;
    1884           0 :             ++indexofretval;
    1885           0 :             if ( status )
    1886             :               //cerr << "remainder rank " << rank << " successful " << endl;
    1887           0 :               cerr << "";
    1888             :             else
    1889           0 :                 logger << LogIO::SEVERE << "remainder rank " << rank << " failed " << LogIO::POST;
    1890             : 
    1891           0 :             rank = casa::applicator.nextProcessDone ( cmc, allDone );
    1892           0 :                         if(casa::applicator.isSerial())
    1893           0 :                                 allDone=true;
    1894           0 :         }
    1895           0 :         if(anyEQ(retvals, False)){
    1896             :           //cerr << retvals << endl;
    1897           0 :           ostringstream oss;
    1898             :           oss << "One or more  of the cube section failed in de/gridding. Return values for "
    1899           0 :               "the sections: " << retvals;
    1900           0 :           throw(AipsError(oss));
    1901           0 :         }
    1902           0 :         if(!dopsf && normpars_p.isDefined("pblimit") && (normpars_p.asFloat("pblimit") > 0.0) ){
    1903             :           try{
    1904           0 :             SIImageStore::copyMask(itsMappers.imageStore(0)->pb(), itsMappers.imageStore(0)->residual());
    1905           0 :             (itsMappers.imageStore(0))->residual()->unlock();
    1906             :             //(itsMappers.imageStore(0)->pb())->pixelMask().unlock();
    1907           0 :             (itsMappers.imageStore(0))->pb()->unlock();
    1908             :           }
    1909           0 :           catch(AipsError &x) {
    1910           0 :             if(!String(x.getMesg()).contains("T/F"))
    1911           0 :               throw(AipsError(x.getMesg()));
    1912             :             else{
    1913           0 :               logger << LogIO::WARN << "Error : " << x.getMesg() << LogIO::POST;
    1914             :               //cout << "x.getMesg() " << endl;
    1915             :             }
    1916             :             ///ignore copy mask error and proceed as this happens with interactive
    1917           0 :           }
    1918             :         }
    1919             :         else{
    1920           0 :           LatticeLocker lock1 (*(itsMappers.imageStore(0)->psf()), FileLocker::Write);
    1921           0 :           itsMappers.imageStore(0)->psf()->setImageInfo(cubePsfImageInfo_p);
    1922           0 :           itsMappers.imageStore(0)->psf()->unlock();
    1923           0 :           (itsMappers.imageStore(0))->pb()->unlock();
    1924           0 :         }
    1925             : 
    1926           0 :         }  
    1927             :           
    1928             :   
    1929           0 :         return true;
    1930             :   
    1931           0 :   }
    1932             :   /////////////////////////
    1933           0 :   void SynthesisImagerVi2::predictModel(){
    1934           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","predictModel ",WHERE) );
    1935             : 
    1936           0 :     os << "---------------------------------------------------- Predict Model ---------------------------------------------" << LogIO::POST;
    1937             :     
    1938           0 :     Bool savemodelcolumn = !readOnly_p && useScratch_p;
    1939           0 :     Bool savevirtualmodel = !readOnly_p && !useScratch_p;
    1940             :     //os<<"PREDICTMODEL: readOnly_p=="<<readOnly_p<<" useScratch_p=="<<useScratch_p<<LogIO::POST;
    1941           0 :     if( savemodelcolumn ) os << "Saving model column" << LogIO::POST;
    1942           0 :     if( savevirtualmodel ) os << "Saving virtual model" << LogIO::POST;
    1943             : 
    1944           0 :     itsMappers.checkOverlappingModels("blank");
    1945             : 
    1946             : 
    1947             :     {
    1948           0 :       vi::VisBuffer2* vb = vi_p->getVisBuffer();;
    1949           0 :       vi_p->originChunks();
    1950           0 :       vi_p->origin();
    1951           0 :       Double numberCoh=0;
    1952           0 :       for (uInt k=0; k< mss_p.nelements(); ++k)
    1953           0 :         numberCoh+=Double(mss_p[k]->nrow());
    1954             : 
    1955           0 :       ProgressMeter pm(1.0, numberCoh, "Predict Model", "","","",true);
    1956           0 :       rownr_t cohDone=0;
    1957             : 
    1958           0 :       itsMappers.initializeDegrid(*vb);
    1959           0 :       for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    1960             :         {
    1961             :           
    1962           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    1963             :             {
    1964             :               //if (SynthesisUtilMethods::validate(*vb)==SynthesisUtilMethods::NOVALIDROWS) break; //No valid rows in this MS
    1965             :               //if !usescratch ...just save
    1966           0 :               vb->setVisCubeModel(Complex(0.0, 0.0));
    1967           0 :               itsMappers.degrid(*vb, savevirtualmodel);
    1968             : 
    1969           0 :               if(savemodelcolumn && writeAccess_p ){
    1970             : 
    1971           0 :                 const_cast<MeasurementSet& >((vi_p->ms())).lock(true);
    1972             : 
    1973           0 :                 vi_p->writeVisModel(vb->visCubeModel());
    1974             : 
    1975             :               //cerr << "nRows "<< vb->nRows() << "   " << max(vb->visCubeModel()) <<  endl;
    1976           0 :                 const_cast<MeasurementSet& >((vi_p->ms())).unlock();
    1977             :               }
    1978             : 
    1979           0 :               cohDone += vb->nRows();
    1980           0 :               pm.update(Double(cohDone));
    1981             : 
    1982             :             }
    1983             :         }
    1984           0 :       itsMappers.finalizeDegrid(*vb);
    1985           0 :     }
    1986             : 
    1987           0 :     itsMappers.checkOverlappingModels("restore");
    1988           0 :     itsMappers.releaseImageLocks();
    1989           0 :     unlockMSs();
    1990             :    
    1991           0 :   }// end of predictModel
    1992             : 
    1993             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    1994           0 :   void SynthesisImagerVi2::makeSdImage(Bool dopsf)
    1995             :   {
    1996           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","makeSdImage",WHERE) );
    1997             : 
    1998             :     // Bool dopsf=false;
    1999           0 :     if(datacol_p==FTMachine::PSF) dopsf=true;
    2000             : 
    2001             :     {
    2002           0 :       vi::VisBuffer2* vb = vi_p->getVisBuffer();;
    2003           0 :       vi_p->originChunks();
    2004           0 :       vi_p->origin();
    2005             : 
    2006           0 :       Double numberCoh=0;
    2007           0 :       for (uInt k=0; k< mss_p.nelements(); ++k)
    2008           0 :         numberCoh+=Double(mss_p[k]->nrow());
    2009             : 
    2010           0 :       ProgressMeter pm(1.0, numberCoh, "Predict Model", "","","",true);
    2011           0 :       rownr_t cohDone=0;
    2012             : 
    2013           0 :       itsMappers.initializeGrid(*vi_p,dopsf);
    2014           0 :       for (vi_p->originChunks(); vi_p->moreChunks(); vi_p->nextChunk())
    2015             :       {
    2016           0 :         if (vi_p->getImpl()->isNewMs()) {
    2017           0 :           itsMappers.handleNewMs(vi_p->ms());
    2018             :         }
    2019           0 :         for (vi_p->origin(); vi_p->more(); vi_p->next())
    2020             :         {
    2021           0 :           itsMappers.grid(*vb, dopsf, (refim::FTMachine::Type)datacol_p);
    2022           0 :           cohDone += vb->nRows();
    2023           0 :           pm.update(Double(cohDone));
    2024             :         }
    2025             :       }
    2026           0 :       itsMappers.finalizeGrid(*vb, dopsf);
    2027             : 
    2028           0 :     }
    2029             : 
    2030           0 :     unlockMSs();
    2031             : 
    2032           0 :   }// end makeSDImage
    2033             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2034           0 :   void SynthesisImagerVi2::makeImage(String type, const String& imagename, const String& complexImage, const Int whichModel)
    2035             :   {
    2036           0 :     LogIO os( LogOrigin("SynthesisImager","makeImage",WHERE) );
    2037             : 
    2038             :     
    2039           0 :     refim::FTMachine::Type seType(refim::FTMachine::OBSERVED);
    2040           0 :     if(type=="observed") {
    2041           0 :       seType=refim::FTMachine::OBSERVED;
    2042             :       os << LogIO::NORMAL // Loglevel INFO
    2043             :          << "Making dirty image from " << type << " data "
    2044           0 :          << LogIO::POST;
    2045             :     }
    2046           0 :     else if (type=="model") {
    2047           0 :       seType=refim::FTMachine::MODEL;
    2048             :       os << LogIO::NORMAL // Loglevel INFO
    2049             :          << "Making dirty image from " << type << " data "
    2050           0 :          << LogIO::POST;
    2051             :     }
    2052           0 :     else if (type=="corrected") {
    2053           0 :       seType=refim::FTMachine::CORRECTED;
    2054             :       os << LogIO::NORMAL // Loglevel INFO
    2055             :          << "Making dirty image from " << type << " data "
    2056           0 :          << LogIO::POST;
    2057             :     }
    2058           0 :     else if (type=="psf") {
    2059           0 :       seType=refim::FTMachine::PSF;
    2060             :       os << "Making point spread function "
    2061           0 :          << LogIO::POST;
    2062             :     }
    2063           0 :     else if (type=="residual") {
    2064           0 :       seType=refim::FTMachine::RESIDUAL;
    2065             :       os << LogIO::NORMAL // Loglevel INFO
    2066             :          << "Making dirty image from " << type << " data "
    2067           0 :          << LogIO::POST;
    2068             :     }
    2069           0 :     else if (type=="singledish-observed") {
    2070           0 :       seType=refim::FTMachine::OBSERVED;
    2071             :       os << LogIO::NORMAL 
    2072           0 :          << "Making single dish image from observed data" << LogIO::POST;
    2073             :     }
    2074           0 :     else if (type=="singledish") {
    2075           0 :       seType=refim::FTMachine::CORRECTED;
    2076             :       os << LogIO::NORMAL 
    2077           0 :          << "Making single dish image from corrected data" << LogIO::POST;
    2078             :     }
    2079           0 :     else if (type=="coverage") {
    2080           0 :       seType=refim::FTMachine::COVERAGE;
    2081             :       os << LogIO::NORMAL 
    2082             :          << "Making single dish coverage function "
    2083           0 :          << LogIO::POST;
    2084             :     }
    2085           0 :     else if (type=="holography") {
    2086           0 :       seType=refim::FTMachine::CORRECTED;
    2087             :       os << LogIO::NORMAL
    2088             :          << "Making complex holographic image from corrected data "
    2089           0 :          << LogIO::POST;
    2090             :     }
    2091           0 :     else if (type=="holography-observed") {
    2092           0 :       seType=refim::FTMachine::OBSERVED;
    2093             :       os << LogIO::NORMAL 
    2094             :          << "Making complex holographic image from observed data "
    2095           0 :          << LogIO::POST;
    2096             :     }
    2097             : 
    2098           0 :     String imageName=(itsMappers.imageStore(whichModel))->getName();
    2099           0 :     String cImageName(complexImage);
    2100           0 :     if(complexImage=="") {
    2101           0 :       cImageName=imageName+".compleximage";
    2102             :     }
    2103           0 :     Bool keepComplexImage=(complexImage!="")||(type.contains("holography"));
    2104             :     //cerr << "name " << (itsMappers.getFTM2(whichModel))->name() << endl;
    2105           0 :  if(((itsMappers.getFTM2(whichModel))->name())!="MultiTermFTNew"){
    2106             :    ////Non multiterm case    
    2107             :         //cerr << "whichModel " << whichModel << " itsMappers num " << itsMappers.nMappers() << " shape " << (itsMappers.imageStore(whichModel))->getShape() << endl;
    2108             :         ///the SIImageStore sometimes return 0 shape...
    2109           0 :         CoordinateSystem csys=itsMaxCoordSys;
    2110           0 :         IPosition shp=itsMaxShape;
    2111           0 :         if((itsMappers.imageStore(whichModel))->getShape().product()!=0 ){
    2112           0 :                 csys=   (itsMappers.imageStore(whichModel))->getCSys();
    2113           0 :                 shp=(itsMappers.imageStore(whichModel))->getShape();
    2114             :         }
    2115           0 :         itsMappers.releaseImageLocks();
    2116           0 :     PagedImage<Float> theImage( shp, csys, imagename);
    2117           0 :     PagedImage<Complex> cImageImage(theImage.shape(),
    2118             :                                     theImage.coordinates(),
    2119           0 :                                     cImageName);
    2120           0 :     if(!keepComplexImage)
    2121           0 :       cImageImage.table().markForDelete();
    2122             : 
    2123             : 
    2124           0 :     Matrix<Float> weight;
    2125           0 :     if(cImageImage.shape()[3] > 1){
    2126           0 :                 cImageImage.set(Complex(0.0));
    2127           0 :                 cImageImage.tempClose();
    2128           0 :                 makeComplexCubeImage(cImageName, seType, whichModel);
    2129             :         }
    2130             :         else{
    2131           0 :     (itsMappers.getFTM2(whichModel))->makeImage(seType, *vi_p, cImageImage, weight);
    2132             :         }
    2133           0 :     if(seType==refim::FTMachine::PSF){
    2134           0 :        StokesImageUtil::ToStokesPSF(theImage, cImageImage);
    2135           0 :        StokesImageUtil::normalizePSF(theImage);
    2136             :     }
    2137             :     else{
    2138           0 :       StokesImageUtil::To(theImage, cImageImage);
    2139             :     }
    2140           0 :  }
    2141             :  else{
    2142             :    ///Multiterm
    2143             :    //refim::MultiTermFTNew *theft=static_cast<refim::MultiTermFTNew *>( (itsMappers.getFTM2(whichModel))->cloneFTM());
    2144           0 :    refim::MultiTermFTNew *theft=static_cast<refim::MultiTermFTNew *>( (itsMappers.getFTM2(whichModel)).get());
    2145           0 :    Int ntaylor= seType==refim::FTMachine::PSF ? theft->psfNTerms() : theft->nTerms();
    2146           0 :    if(ntaylor<2)
    2147           0 :      throw(AipsError("some issue with muti term setting "));
    2148           0 :    Vector<CountedPtr<ImageInterface<Float> > >theImage(ntaylor);
    2149           0 :    Vector<CountedPtr<ImageInterface<Complex> > >cImageImage(ntaylor);
    2150           0 :    Vector<CountedPtr<Matrix<Float> > >weight(ntaylor);
    2151           0 :    for (Int taylor=0; taylor < ntaylor; ++taylor){
    2152           0 :      theImage[taylor]=new PagedImage<Float>((itsMappers.imageStore(whichModel))->getShape(), (itsMappers.imageStore(whichModel))->getCSys(), imagename+".tt"+String::toString(taylor));
    2153           0 :      cImageImage[taylor]=new PagedImage<Complex> (theImage[taylor]->shape(),
    2154           0 :                                                   theImage[taylor]->coordinates(),
    2155           0 :                                                   cImageName+".tt"+String::toString(taylor));
    2156           0 :       if(!keepComplexImage)
    2157           0 :         static_cast<PagedImage<Complex> *> (cImageImage[taylor].get())->table().markForDelete();
    2158           0 :       weight[taylor]=new Matrix<Float>();
    2159             : 
    2160             :    }
    2161           0 :    theft->makeMTImages(seType, *vi_p, cImageImage, weight);
    2162           0 :    Float maxpsf=1.0;
    2163           0 :    for (Int taylor=0; taylor < ntaylor; ++taylor){
    2164           0 :      if(seType==refim::FTMachine::PSF){
    2165           0 :        StokesImageUtil::ToStokesPSF(*(theImage[taylor]), *(cImageImage[taylor]));
    2166           0 :        if(taylor==0){
    2167           0 :          maxpsf=StokesImageUtil::normalizePSF(*theImage[taylor]);
    2168             :          //cerr << "maxpsf " << maxpsf << endl;
    2169             :        }
    2170             :        else{
    2171             :          ///divide by max;
    2172           0 :          (*theImage[taylor]).copyData((LatticeExpr<Float>)((*theImage[taylor])/maxpsf));
    2173             :        }
    2174             :     }
    2175             :     else{
    2176           0 :       StokesImageUtil::To(*(theImage[taylor]), *(cImageImage[taylor]));
    2177             :     }
    2178             :    }
    2179             :    //delete theft;
    2180             :      
    2181           0 :  }
    2182           0 :     unlockMSs();
    2183             : 
    2184           0 :   }// end makeImage
    2185             :   /////////////////////////////////////////////////////
    2186             : 
    2187           0 : void SynthesisImagerVi2::makeComplexCubeImage(const String& cimage, const refim::FTMachine::Type imtype, const Int whichmodel){
    2188           0 :         CubeMakeImageAlgorithm *cmi=new CubeMakeImageAlgorithm();
    2189             :         // Dummies for using the right signature for init
    2190           0 :         Path cimpath(cimage);
    2191           0 :         String cimname=cimpath.absoluteName();
    2192             :         //cerr << "ABSOLUTE path " << cimname << endl;
    2193           0 :         Int argc = 1;
    2194           0 :         char **argv = nullptr;
    2195           0 :         casa::applicator.init(argc, argv);
    2196           0 :         if(applicator.isController())
    2197             :     {
    2198           0 :                 Record vecSelParsRec;
    2199           0 :                 for (uInt k = 0; k < dataSel_p.nelements(); ++k) {
    2200           0 :                         Record selparsRec = dataSel_p[k].toRecord();
    2201           0 :                         vecSelParsRec.defineRecord(String::toString(k), selparsRec);
    2202           0 :                 }
    2203           0 :                 Record imparsRec = imparsVec_p[whichmodel].toRecord();
    2204             :                 //cerr << "which model " << whichmodel << " record " << imparsRec << endl;
    2205           0 :                 Record gridparsRec = gridparsVec_p[whichmodel].toRecord();
    2206             :         ///Break things into chunks for parallelization or memory availabbility
    2207           0 :         Vector<Int> startchan;
    2208           0 :         Vector<Int> endchan;
    2209             :         Int numchunks;
    2210           0 :         Int fudge_factor = 15;
    2211           0 :         if ((itsMappers.getFTM2(0))->name()=="MosaicFTNew") {
    2212           0 :             fudge_factor = 20;
    2213             :         }
    2214           0 :         else if ((itsMappers.getFTM2(0))->name()=="GridFT") {
    2215           0 :             fudge_factor = 9;
    2216             :         }
    2217           0 :         TcleanProcessingInfo  procInfo;
    2218           0 :         std::tie(procInfo, startchan, endchan)=nSubCubeFitInMemory(fudge_factor, itsMaxShape, gridpars_p.padding);
    2219           0 :         numchunks = procInfo.chnchnks;
    2220             :         
    2221           0 :                 Int imageType=Int(imtype);
    2222           0 :                 Int rank(0);
    2223             :                 Bool assigned; 
    2224           0 :                 Bool allDone(false);
    2225           0 :                 Vector<Int> chanRange(2);
    2226           0 :                 for (Int k=0; k < numchunks; ++k) {
    2227           0 :                         assigned=casa::applicator.nextAvailProcess ( *cmi, rank );
    2228             :             //cerr << "assigned "<< assigned << endl;
    2229           0 :             while ( !assigned ) {
    2230           0 :                 rank = casa::applicator.nextProcessDone ( *cmi, allDone );
    2231             :                 //cerr << "while rank " << rank << endl;
    2232             :                 Bool status;
    2233           0 :                 casa::applicator.get(status);
    2234             :                 /*if ( status )
    2235             :                   cerr << k << " rank " << rank << " successful " << endl;
    2236             :                 else
    2237             :                     cerr << k << " rank " << rank << " failed " << endl;
    2238             :                 */
    2239           0 :                 assigned = casa::applicator.nextAvailProcess ( *cmi, rank );
    2240             : 
    2241             :             }
    2242           0 :             applicator.put(vecSelParsRec);
    2243             :                         // put image sel params #2
    2244           0 :                         applicator.put(imparsRec);
    2245             :                         // put gridder params #3
    2246           0 :                         applicator.put(gridparsRec);
    2247             :                         // put which channel to process #4
    2248           0 :                         chanRange(0)=startchan(k);
    2249           0 :                         chanRange(1)=endchan(k);
    2250           0 :                         applicator.put(chanRange);
    2251             :                         //Type of image #5
    2252           0 :                         applicator.put(imageType);
    2253             :                         // weighting parameters #6
    2254           0 :                         applicator.put( weightParams_p);
    2255             :                         // complex imagename #7
    2256           0 :                         applicator.put(cimname);
    2257           0 :                         applicator.apply(*cmi);
    2258             :                 }
    2259             :                 // Wait for all outstanding processes to return
    2260           0 :         rank = casa::applicator.nextProcessDone(*cmi, allDone);
    2261           0 :         while (!allDone) {
    2262             :             Bool status;
    2263           0 :             casa::applicator.get(status);
    2264             :             /*
    2265             :             if(status)
    2266             :                 cerr << "remainder rank " << rank << " successful " << endl;
    2267             :             else
    2268             :                 cerr << "remainder rank " << rank << " failed " << endl;
    2269             :             */
    2270           0 :             rank = casa::applicator.nextProcessDone(*cmi, allDone);
    2271           0 :                         if(casa::applicator.isSerial())
    2272           0 :                                 allDone=true;
    2273             :         }
    2274           0 :     }//applicator controller section
    2275           0 : }
    2276             : 
    2277             : 
    2278             : 
    2279           0 : CountedPtr<SIMapper> SynthesisImagerVi2::createSIMapper(String mappertype,  
    2280             :                                                            CountedPtr<SIImageStore> imagestore,
    2281             :                                                         CountedPtr<refim::FTMachine> ftmachine,
    2282             :                                                         CountedPtr<refim::FTMachine> iftmachine,
    2283             :                                                        uInt /*ntaylorterms*/)
    2284             :   {
    2285           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","createSIMapper",WHERE) );
    2286             :     
    2287           0 :     CountedPtr<SIMapper> localMapper;
    2288             : 
    2289             :     try
    2290             :       {
    2291             :         
    2292           0 :         if( mappertype == "default" || mappertype == "multiterm" )
    2293             :           {
    2294           0 :             localMapper = new SIMapper( imagestore, ftmachine, iftmachine );
    2295             :           }
    2296           0 :         else if( mappertype == "imagemosaic") // || mappertype == "mtimagemosaic" )
    2297             :           {
    2298           0 :             localMapper = new SIMapperImageMosaic( imagestore, ftmachine, iftmachine );
    2299             :           }
    2300             :         else
    2301             :           {
    2302           0 :             throw(AipsError("Unknown mapper type : " + mappertype));
    2303             :           }
    2304             : 
    2305             :       }
    2306           0 :     catch(AipsError &x) {
    2307           0 :         throw(AipsError("Error in createSIMapper : " + x.getMesg() ) );
    2308           0 :       }
    2309           0 :     return localMapper;
    2310           0 :   }
    2311             :   
    2312           0 : void SynthesisImagerVi2::lockMS(MeasurementSet& thisms){
    2313           0 :   thisms.lock(!readOnly_p);
    2314           0 :     thisms.antenna().lock(false);
    2315           0 :         thisms.dataDescription().lock(false);
    2316           0 :     thisms.feed().lock(false);
    2317           0 :     thisms.field().lock(false);
    2318           0 :     thisms.observation().lock(false);
    2319           0 :     thisms.polarization().lock(false);
    2320           0 :     thisms.processor().lock(false);
    2321           0 :         thisms.spectralWindow().lock(false);
    2322           0 :     thisms.state().lock(false);
    2323           0 :     if(!thisms.doppler().isNull())
    2324           0 :       thisms.doppler().lock(false);
    2325           0 :     if(!thisms.flagCmd().isNull())
    2326           0 :       thisms.flagCmd().lock(false);
    2327           0 :     if(!thisms.freqOffset().isNull())
    2328           0 :       thisms.freqOffset().lock(false);
    2329             :         //True here as we can write in that
    2330           0 :     if(!thisms.history().isNull())
    2331             :     // thisms.history().lock(!readOnly_p);
    2332           0 :       thisms.history().lock(false);
    2333           0 :     if(!thisms.pointing().isNull())
    2334           0 :       thisms.pointing().lock(false);
    2335             :         //we write virtual model here
    2336           0 :     if(!thisms.source().isNull())
    2337           0 :       thisms.source().lock(!readOnly_p);
    2338           0 :     if(!thisms.sysCal().isNull())
    2339           0 :       thisms.sysCal().lock(false);
    2340           0 :     if(!thisms.weather().isNull())
    2341           0 :       thisms.weather().lock(false);
    2342             :         
    2343           0 : }
    2344             : ///////////////////////
    2345             :   
    2346           0 :   Vector<SynthesisParamsSelect> SynthesisImagerVi2::tuneSelectData(){
    2347           0 :     vi_p->originChunks();
    2348           0 :     vi_p->origin();
    2349           0 :     vi::VisBuffer2* vb=vi_p->getVisBuffer();
    2350           0 :     Int spwnow=vb->spectralWindows()[0];
    2351           0 :     Int nchaninms=MSColumns(vb->ms()).spectralWindow().numChan()(spwnow);
    2352             :     //For some small number of channels in the ms vi/vb2 retuning the selection
    2353             :     //will sometimes return more channels than what is in the ms...this is a
    2354             :     //kludge here to bypass it...mostly seen in test_tclean
    2355             :     /// write to the test !!  till someboody fixes this is vi2 or wait for cngi
    2356             :     //if savescratch column we have tune...otherwise some channel may be 0
    2357             :     // when chunking or in parallel
    2358             :     //cerr << "nchanims " << nchaninms << endl;
    2359           0 :     if(nchaninms <30 && !(!readOnly_p && useScratch_p))
    2360           0 :       return dataSel_p;
    2361             :     
    2362           0 :     return SynthesisImager::tuneSelectData();
    2363             :   }
    2364             : //////////////////////
    2365           0 :   void SynthesisImagerVi2::lockMSs(){
    2366           0 :     for(uInt i=0;i<mss_p.nelements();i++)
    2367             :       { 
    2368             :        
    2369           0 :         MeasurementSet *ms_l =  const_cast<MeasurementSet* >(mss_p[i]);
    2370           0 :         lockMS(*ms_l);
    2371             :       }
    2372             : 
    2373           0 :   }
    2374           0 : void SynthesisImagerVi2::unlockMSs()
    2375             :   {
    2376           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","unlockMSs",WHERE) );
    2377           0 :     for(uInt i=0;i<mss_p.nelements();i++)
    2378             :       { 
    2379           0 :         os << LogIO::NORMAL2 << "Unlocking : " << (mss_p[i])->tableName() << LogIO::POST;
    2380           0 :         MeasurementSet *ms_l =  const_cast<MeasurementSet* >(mss_p[i]);
    2381           0 :         ms_l->unlock(); 
    2382           0 :         ms_l->antenna().unlock();
    2383           0 :         ms_l->dataDescription().unlock();
    2384           0 :         ms_l->feed().unlock();
    2385           0 :         ms_l->field().unlock();
    2386           0 :         ms_l->observation().unlock();
    2387           0 :         ms_l->polarization().unlock();
    2388           0 :         ms_l->processor().unlock();
    2389           0 :         ms_l->spectralWindow().unlock();
    2390           0 :         ms_l->state().unlock();
    2391             :         //
    2392             :         // Unlock the optional sub-tables as well, if they are present
    2393             :         //
    2394           0 :         if(!(ms_l->source().isNull()))     ms_l->source().unlock();
    2395           0 :         if(!(ms_l->doppler().isNull()))    ms_l->doppler().unlock();
    2396           0 :         if(!(ms_l->flagCmd().isNull()))    ms_l->flagCmd().unlock();
    2397           0 :         if(!(ms_l->freqOffset().isNull())) ms_l->freqOffset().unlock();
    2398           0 :         if(!(ms_l->history().isNull()))    ms_l->history().unlock();
    2399           0 :         if(!(ms_l->pointing().isNull()))   ms_l->pointing().unlock();
    2400           0 :         if(!(ms_l->sysCal().isNull()))     ms_l->sysCal().unlock();
    2401           0 :         if(!(ms_l->weather().isNull()))    ms_l->weather().unlock();
    2402             :       }
    2403           0 :   }
    2404           0 :   void SynthesisImagerVi2::createFTMachine(
    2405             :             CountedPtr<refim::FTMachine>& theFT,
    2406             :             CountedPtr<refim::FTMachine>& theIFT,
    2407             :             const String& ftname,
    2408             :             const uInt nTaylorTerms,
    2409             :             const String mType,
    2410             :             const Int facets,            //=1
    2411             :             //------------------------------
    2412             :             const Int wprojplane,        //=1,
    2413             :             const Float padding,         //=1.0,
    2414             :             const Bool useAutocorr,      //=false,
    2415             :             const Bool useDoublePrec,    //=true,
    2416             :             const String gridFunction,   //=String("SF"),
    2417             :             //------------------------------
    2418             :             const Bool aTermOn,          //= true,
    2419             :             const Bool psTermOn,         //= true,
    2420             :             const Bool mTermOn,          //= false,
    2421             :             const Bool wbAWP,            //= true,
    2422             :             const String cfCache,        //= "",
    2423             :             const Bool usePointing,      //= false,
    2424             :             // const Vector<Float> pointingOffsetSigDev, //= 10.0,
    2425             :             const vector<float> pointingOffsetSigDev, // = {10,10}
    2426             :             const Bool doPBCorr,         //= true,
    2427             :             const Bool conjBeams,        //= true,
    2428             :             const Float computePAStep,   //=360.0
    2429             :             const Float rotatePAStep,    //=5.0
    2430             :             const String interpolation,  //="linear"
    2431             :             const Bool freqFrameValid,   //=true
    2432             :             const Int cache,             //=1000000000,
    2433             :             const Int tile,              //=16
    2434             :             const String stokes,         //=I
    2435             :             const String imageNamePrefix,
    2436             :             //---------------------------
    2437             :             const String &pointingDirCol,
    2438             :             const String &convertFirst,
    2439             :             const Float skyPosThreshold,
    2440             :             const Int convSupport,
    2441             :             const Quantity &truncateSize,
    2442             :             const Quantity &gwidth,
    2443             :             const Quantity &jwidth,
    2444             :             const Float minWeight,
    2445             :             const Bool clipMinMax,
    2446             :             const Bool pseudoI
    2447             :            )
    2448             : 
    2449             :   {
    2450           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","createFTMachine",WHERE));
    2451             : 
    2452             : 
    2453           0 :     if (ftname == "gridft") {
    2454           0 :       if (facets >1) {
    2455             :         theFT = new refim::GridFT(
    2456             :             cache, tile,
    2457           0 :             gridFunction, mLocation_p, phaseCenter_p, padding,
    2458             :             useAutocorr, useDoublePrec
    2459           0 :         );
    2460             :         theIFT = new refim::GridFT(
    2461             :             cache, tile,
    2462           0 :             gridFunction, mLocation_p, phaseCenter_p, padding,
    2463             :             useAutocorr, useDoublePrec
    2464           0 :         );
    2465             :       }
    2466             :       else {
    2467             :         theFT = new refim::GridFT(
    2468             :             cache, tile,
    2469           0 :             gridFunction, mLocation_p, padding,
    2470             :             useAutocorr, useDoublePrec
    2471           0 :         );
    2472             :         theIFT = new refim::GridFT(
    2473             :             cache, tile,
    2474           0 :             gridFunction, mLocation_p, padding,
    2475             :             useAutocorr, useDoublePrec
    2476           0 :         );
    2477             :       }
    2478             :     }
    2479           0 :     else if (ftname == "wprojectft") {
    2480           0 :       Double maxW = -1.0;
    2481           0 :       Double minW = -1.0;
    2482           0 :       Double rmsW = -1.0;
    2483           0 :       if (wprojplane < 1)
    2484           0 :         casa::refim::WProjectFT::wStat(*vi_p, minW, maxW, rmsW);
    2485           0 :       if (facets > 1) {
    2486           0 :         theFT = new refim::WProjectFT(wprojplane, phaseCenter_p, mLocation_p,
    2487           0 :          cache/2, tile, useAutocorr, padding, useDoublePrec, minW, maxW, rmsW);
    2488           0 :         theIFT = new refim::WProjectFT(wprojplane, phaseCenter_p, mLocation_p,
    2489           0 :           cache/2, tile, useAutocorr, padding, useDoublePrec, minW, maxW, rmsW);
    2490             :       }
    2491             :       else {
    2492           0 :         theFT = new refim::WProjectFT(wprojplane, mLocation_p,
    2493           0 :           cache/2, tile, useAutocorr, padding, useDoublePrec, minW, maxW, rmsW);
    2494           0 :         theIFT = new refim::WProjectFT(wprojplane, mLocation_p,
    2495           0 :           cache/2, tile, useAutocorr, padding, useDoublePrec, minW, maxW, rmsW);
    2496             :       }
    2497             :       CountedPtr<refim::WPConvFunc> sharedconvFunc =
    2498           0 :         static_cast<refim::WProjectFT &>(*theFT).getConvFunc();
    2499             :       //static_cast<WProjectFT &>(*theFT).setConvFunc(sharedconvFunc);
    2500           0 :       static_cast<refim::WProjectFT &>(*theIFT).setConvFunc(sharedconvFunc);
    2501           0 :     }
    2502             : 
    2503           0 :     else if ( ftname == "mosaic" || ftname== "mosft" || ftname == "mosaicft" || ftname== "MosaicFT" || ftname == "awp2"){
    2504             : 
    2505           0 :       createMosFTMachine(theFT, theIFT, padding, useAutocorr, useDoublePrec, rotatePAStep, stokes, conjBeams);
    2506             :     } 
    2507           0 :     else if ((ftname.at(0,3)=="awp") || (ftname== "mawprojectft") || (ftname == "protoft")) {
    2508           0 :       createAWPFTMachine(theFT, theIFT, ftname, facets, wprojplane, 
    2509             :                          padding, useAutocorr, useDoublePrec, gridFunction,
    2510             :                          aTermOn, psTermOn, mTermOn, wbAWP, cfCache, 
    2511             :                          usePointing, pointingOffsetSigDev, doPBCorr, conjBeams, computePAStep,
    2512             :                          rotatePAStep, cache,tile,imageNamePrefix);
    2513             :     }
    2514             : 
    2515           0 :     else if ( ftname == "mosaic" or
    2516           0 :               ftname == "mosft" or
    2517           0 :               ftname == "mosaicft" or
    2518           0 :               ftname == "MosaicFT" ) {
    2519           0 :       createMosFTMachine(
    2520             :         theFT, theIFT,
    2521             :         padding, useAutocorr, useDoublePrec, rotatePAStep, stokes, conjBeams
    2522             :       );
    2523             :     }
    2524           0 :     else if ( ftname == "sd" ) {
    2525           0 :       createSDFTMachine(
    2526             :         theFT, theIFT,
    2527             :         pointingDirCol, convertFirst,
    2528             :         skyPosThreshold, doPBCorr, rotatePAStep,
    2529             :         gridFunction, convSupport, truncateSize, gwidth, jwidth,
    2530             :         minWeight, clipMinMax, cache, tile, stokes
    2531             :       );
    2532             :     }
    2533             :     else {
    2534           0 :       throw( AipsError( "Invalid FTMachine name : " + ftname ) );
    2535             :     }
    2536             : 
    2537             :     // Now, clone and pack the chosen FT into a MultiTermFT if needed.
    2538           0 :     if( mType == "multiterm" ) {
    2539           0 :       AlwaysAssert( nTaylorTerms>=1 , AipsError );
    2540             : 
    2541             :       CountedPtr<refim::FTMachine> theMTFT =
    2542           0 :         new refim::MultiTermFTNew( theFT, nTaylorTerms, true /*forward*/ );
    2543             :       CountedPtr<refim::FTMachine> theMTIFT =
    2544           0 :         new refim::MultiTermFTNew( theIFT, nTaylorTerms, false /*forward*/ );
    2545             : 
    2546           0 :       theFT = theMTFT;
    2547           0 :       theIFT = theMTIFT;
    2548           0 :     }
    2549             : 
    2550             :     // Now, set the SkyJones if needed, and if not internally generated.
    2551           0 :     if ( mType == "imagemosaic" and
    2552           0 :         ( ftname != "awprojectft" and
    2553           0 :           ftname != "mawprojectft" and
    2554           0 :           ftname != "proroft" ) ) {
    2555           0 :       CountedPtr<refim::SkyJones> vp;
    2556           0 :       MSColumns msc(*(mss_p[0]));
    2557           0 :       Quantity parang(0.0,"deg");
    2558           0 :       Quantity skyposthreshold(0.0,"deg");
    2559           0 :       vp = new refim::VPSkyJones(
    2560             :         msc, true,  parang, BeamSquint::NONE, skyposthreshold
    2561           0 :       );
    2562             : 
    2563           0 :       Vector<CountedPtr<refim::SkyJones> > skyJonesList(1);
    2564           0 :       skyJonesList(0) = vp;
    2565           0 :       theFT->setSkyJones( skyJonesList );
    2566           0 :       theIFT->setSkyJones( skyJonesList );
    2567           0 :     }
    2568             : 
    2569             :     // For mode=cubedata, set the freq frame to invalid.
    2570             :     // get this info from buildCoordSystem
    2571             :     // theFT->setSpw( tspws, false );
    2572             :     // theIFT->setSpw( tspws, false );
    2573           0 :     theFT->setFrameValidity( freqFrameValid );
    2574           0 :     theIFT->setFrameValidity( freqFrameValid );
    2575             : 
    2576             :     // Set interpolation mode
    2577           0 :     theFT->setFreqInterpolation( interpolation );
    2578           0 :     theIFT->setFreqInterpolation( interpolation );
    2579             : 
    2580             :     // Set tracking of moving source if any
    2581           0 :     if (movingSource_p != "") {
    2582           0 :       theFT->setMovingSource(movingSource_p);
    2583           0 :       theIFT->setMovingSource(movingSource_p);
    2584             :     }
    2585             :     /* vi_p has chanselection now
    2586             :     //channel selections from spw param
    2587             :     theFT->setSpwChanSelection(chanSel_p);
    2588             :     theIFT->setSpwChanSelection(chanSel_p);
    2589             :     */
    2590             : 
    2591             :     // Set pseudo-I if requested.
    2592           0 :     if (pseudoI == true) {
    2593           0 :       os << "Turning on Pseudo-I gridding" << LogIO::POST;
    2594           0 :       theFT->setPseudoIStokes(true);
    2595           0 :       theIFT->setPseudoIStokes(true);
    2596             :     }
    2597             : 
    2598           0 :   }
    2599             : 
    2600             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2601             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2602           0 :   void SynthesisImagerVi2::createAWPFTMachine(CountedPtr<refim::FTMachine>& theFT, CountedPtr<refim::FTMachine>& theIFT, 
    2603             :                                               const String& ftmName,
    2604             :                                               const Int,// facets,            //=1
    2605             :                                               //------------------------------
    2606             :                                               const Int wprojPlane,        //=1,
    2607             :                                               const Float,// padding,         //=1.0,
    2608             :                                               const Bool,// useAutocorr,      //=false,
    2609             :                                               const Bool useDoublePrec,    //=true,
    2610             :                                               const String,// gridFunction,   //=String("SF"),
    2611             :                                               //------------------------------
    2612             :                                               const Bool aTermOn,          //= true,
    2613             :                                               const Bool psTermOn,         //= true,
    2614             :                                               const Bool mTermOn,          //= false,
    2615             :                                               const Bool wbAWP,            //= true,
    2616             :                                               const String cfCache,        //= "",
    2617             :                                               const Bool usePointing,       //= false,
    2618             :                                               const vector<Float> pointingOffsetSigDev,//={10,10},
    2619             :                                               const Bool doPBCorr,         //= true,
    2620             :                                               const Bool conjBeams,        //= true,
    2621             :                                               const Float computePAStep,   //=360.0
    2622             :                                               const Float rotatePAStep,    //=5.0
    2623             :                                               const Int cache,             //=1000000000,
    2624             :                                               const Int tile,               //=16
    2625             :                                               const String imageNamePrefix
    2626             :                                               )
    2627             : 
    2628             :   {
    2629           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","createAWPFTMachine",WHERE));
    2630             : 
    2631           0 :     if (wprojPlane<=1)
    2632             :       {
    2633             :         os << LogIO::NORMAL
    2634             :            << "You are using wprojplanes=1. Doing co-planar imaging (no w-projection needed)" 
    2635           0 :            << LogIO::POST;
    2636           0 :         os << LogIO::NORMAL << "Performing WBA-Projection" << LogIO::POST; // Loglevel PROGRESS
    2637             :       }
    2638             :     // if((wprojPlane>1)&&(wprojPlane<64)) 
    2639             :     //   {
    2640             :     //  os << LogIO::WARN
    2641             :     //     << "No. of w-planes set too low for W projection - recommend at least 128"
    2642             :     //     << LogIO::POST;
    2643             :     //  os << LogIO::NORMAL << "Performing WBAW-Projection" << LogIO::POST; // Loglevel PROGRESS
    2644             :     //   }
    2645             : 
    2646             :     // CountedPtr<ATerm> apertureFunction = createTelescopeATerm(mss4vi_p[0], aTermOn);
    2647             :     // CountedPtr<PSTerm> psTerm = new PSTerm();
    2648             :     // CountedPtr<WTerm> wTerm = new WTerm();
    2649             :     
    2650             :     // //
    2651             :     // // Selectively switch off CFTerms.
    2652             :     // //
    2653             :     // if (aTermOn == false) {apertureFunction->setOpCode(CFTerms::NOOP);}
    2654             :     // if (psTermOn == false) psTerm->setOpCode(CFTerms::NOOP);
    2655             : 
    2656             :     // //
    2657             :     // // Construct the CF object with appropriate CFTerms.
    2658             :     // //
    2659             :     // CountedPtr<ConvolutionFunction> tt;
    2660             :     // tt = AWProjectFT::makeCFObject(aTermOn, psTermOn, true, mTermOn, wbAWP);
    2661             :     // CountedPtr<ConvolutionFunction> awConvFunc;
    2662             :     // //    awConvFunc = new AWConvFunc(apertureFunction,psTerm,wTerm, !wbAWP);
    2663             :     // if ((ftmName=="mawprojectft") || (mTermOn))
    2664             :     //   awConvFunc = new AWConvFuncEPJones(apertureFunction,psTerm,wTerm,wbAWP);
    2665             :     // else
    2666             :     //   awConvFunc = new AWConvFunc(apertureFunction,psTerm,wTerm,wbAWP);
    2667             : 
    2668           0 :     MSObservationColumns msoc((mss_p[0])->observation());
    2669           0 :     String telescopeName=msoc.telescopeName()(0);
    2670             :     CountedPtr<refim::ConvolutionFunction> awConvFunc = refim::AWProjectFT::makeCFObject(telescopeName, 
    2671             :                                                                            aTermOn,
    2672             :                                                                            psTermOn, (wprojPlane > 1),
    2673           0 :                                                                            mTermOn, wbAWP, conjBeams);
    2674             : 
    2675             :     //
    2676             :     // Construct the appropriate re-sampler.
    2677             :     //
    2678           0 :     CountedPtr<refim::VisibilityResamplerBase> visResampler;
    2679             :     //    if (ftmName=="protoft") visResampler = new ProtoVR();
    2680             :     //elsef
    2681           0 :     visResampler = new refim::AWVisResampler();
    2682             :     //    CountedPtr<VisibilityResamplerBase> visResampler = new VisibilityResampler();
    2683             : 
    2684             :     //
    2685             :     // Construct and initialize the CF cache object.
    2686             :     //
    2687             : 
    2688             : 
    2689             :     // CountedPtr<CFCache> cfCacheObj = new CFCache();
    2690             :     // cfCacheObj->setCacheDir(cfCache.data());
    2691             :     // //    cerr << "Setting wtImagePrefix to " << imageNamePrefix.c_str() << endl;
    2692             :     // cfCacheObj->setWtImagePrefix(imageNamePrefix.c_str());
    2693             :     // cfCacheObj->initCache2();
    2694             : 
    2695           0 :     CountedPtr<refim::CFCache> cfCacheObj;
    2696             :       
    2697             : 
    2698             :     //
    2699             :     // Finally construct the FTMachine with the CFCache, ConvFunc and
    2700             :     // Re-sampler objects.  
    2701             :     //
    2702           0 :     Float pbLimit_l=1e-3;
    2703             : 
    2704           0 :     theFT = new refim::AWProjectWBFT(wprojPlane, cache/2, 
    2705             :                               cfCacheObj, awConvFunc, 
    2706             :                               visResampler,
    2707             :                                         /*true */usePointing, pointingOffsetSigDev ,doPBCorr, 
    2708             :                               tile, computePAStep, pbLimit_l, true,conjBeams,
    2709           0 :                               useDoublePrec);
    2710             :     
    2711           0 :     cfCacheObj = new refim::CFCache();
    2712           0 :     cfCacheObj->setCacheDir(cfCache.data());
    2713             :     // Get the LAZYFILL setting from the user configuration.  If not
    2714             :     // found, default to False.
    2715             :     //
    2716             :     // With lazy fill ON, CFCache loads the required CFs on-demand
    2717             :     // from the disk.  And periodically triggers garbage collection to
    2718             :     // release CFs that aren't required immediately.
    2719           0 :     if(impars_p.mode.contains("cube")){
    2720           0 :       cfCacheObj->setLazyFill(False);
    2721             :     }
    2722             :     else
    2723           0 :       cfCacheObj->setLazyFill(refim::SynthesisUtils::getenv("CFCache.LAZYFILL",1)==1);
    2724             :     //    cerr << "Setting wtImagePrefix to " << imageNamePrefix.c_str() << endl;
    2725           0 :     cfCacheObj->setWtImagePrefix(imageNamePrefix.c_str());
    2726           0 :     cfCacheObj->initCache2(CFC_VERBOSE);
    2727             : 
    2728           0 :     theFT->setCFCache(cfCacheObj);
    2729             :     
    2730             : 
    2731           0 :     Quantity rotateOTF(rotatePAStep,"deg");
    2732           0 :     static_cast<refim::AWProjectWBFT &>(*theFT).setObservatoryLocation(mLocation_p);
    2733           0 :     static_cast<refim::AWProjectWBFT &>(*theFT).setPAIncrement(Quantity(computePAStep,"deg"),rotateOTF);
    2734             : 
    2735             :     // theIFT = new AWProjectWBFT(wprojPlane, cache/2, 
    2736             :     //                         cfCacheObj, awConvFunc, 
    2737             :     //                         visResampler,
    2738             :     //                         /*true */usePointing, doPBCorr, 
    2739             :     //                         tile, computePAStep, pbLimit_l, true,conjBeams,
    2740             :     //                         useDoublePrec);
    2741             : 
    2742             :     // static_cast<AWProjectWBFT &>(*theIFT).setObservatoryLocation(mLocation_p);
    2743             :     // static_cast<AWProjectWBFT &>(*theIFT).setPAIncrement(Quantity(computePAStep,"deg"),rotateOTF);
    2744             : 
    2745           0 :     theIFT = new refim::AWProjectWBFT(static_cast<refim::AWProjectWBFT &>(*theFT));
    2746             : 
    2747           0 :     os << "Sending frequency selection information " <<  mssFreqSel_p  <<  " to AWP FTM." << LogIO::POST;
    2748           0 :     theFT->setSpwFreqSelection( mssFreqSel_p );
    2749           0 :     theIFT->setSpwFreqSelection( mssFreqSel_p );
    2750             :     
    2751             : 
    2752           0 :   }
    2753             : 
    2754             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2755             : 
    2756             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2757             : 
    2758             : 
    2759             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2760             : 
    2761           0 :   void SynthesisImagerVi2:: createMosFTMachine(CountedPtr<refim::FTMachine>& theFT,CountedPtr<refim::FTMachine>&  theIFT, const Float /*padding*/, const Bool useAutoCorr, const Bool useDoublePrec, const Float rotatePAStep, const String stokes, const Bool doConjBeams){
    2762             :     
    2763           0 :     LogIO os(LogOrigin("SynthesisImagerVi2", "createMosFTMachine",WHERE));
    2764             :    
    2765           0 :     MSColumns msc(vi_p->ms());
    2766           0 :     String telescop=msc.observation().telescopeName()(0);
    2767           0 :     Bool multiTel=False;
    2768           0 :     Int msid=0;
    2769           0 :      for(vi_p->originChunks(); vi_p->moreChunks(); vi_p->nextChunk()){
    2770           0 :        if(((vi_p->getVisBuffer())->msId() != msid) && telescop !=  MSColumns(vi_p->ms()).observation().telescopeName()(0)){
    2771           0 :          msid=(vi_p->getVisBuffer())->msId();
    2772           0 :          multiTel=True;
    2773             :        }
    2774             :      }
    2775           0 :     vi_p->originChunks();
    2776             :   
    2777             :   
    2778             : 
    2779             :     PBMath::CommonPB kpb;
    2780           0 :     Record rec;
    2781           0 :     getVPRecord( rec, kpb, telescop );
    2782             :    
    2783             : 
    2784           0 :     if(rec.empty()){os << LogIO::SEVERE << "Cannot proceed with mosaicft gridder without a valid PB model" << LogIO::POST; }
    2785             :     
    2786             :     /*
    2787             :    VPManager *vpman=VPManager::Instance();
    2788             :     PBMath::CommonPB kpb;
    2789             :     PBMath::enumerateCommonPB(telescop, kpb);
    2790             :     Record rec;
    2791             :     vpman->getvp(rec, telescop);
    2792             :     */
    2793             : 
    2794           0 :    refim::VPSkyJones* vps= nullptr;
    2795             :    //cerr << "rec " << rec << " kpb " << kpb << endl;
    2796             :    //cerr <<  "createMOs ftname " <<  gridpars_p.ftmachine <<  endl;
    2797           0 :    if (!gridpars_p.ftmachine.contains("mos")) {
    2798           0 :      cerr <<  "PASTERP " <<  rotatePAStep <<  "   " <<  gridpars_p.computePAStep <<  endl;
    2799           0 :      bool dosquint = (gridpars_p.computePAStep < 180);       //anything beneath 180 deg ...you are not serious about squint correction  
    2800             :     //  TESTOO
    2801           0 :     dosquint = False;
    2802             :     ///////
    2803             :     
    2804           0 :     cerr <<  "Doing AWPLPG" <<   " wprojplanes " << gridpars_p.wprojplanes << endl;
    2805           0 :      theFT = new refim::AWPLPG(vps , gridpars_p.wprojplanes, dosquint, rotatePAStep*(C::pi)/180.0, mLocation_p, stokes, useAutoCorr, useDoublePrec, gridpars_p.usePointing);
    2806           0 :      theIFT = new refim::AWPLPG(vps , gridpars_p.wprojplanes, dosquint, rotatePAStep*(C::pi)/180.0, mLocation_p, stokes, useAutoCorr, useDoublePrec, gridpars_p.usePointing);
    2807           0 :      CountedPtr<refim::SimplePBConvFunc> mospb=new refim::HetArrayConvFunc();
    2808           0 :       static_cast<refim::AWPLPG &>(*theFT).setConvFunc(mospb);
    2809           0 :       static_cast<refim::AWPLPG &>(*theIFT).setConvFunc(mospb);
    2810             :       
    2811           0 :    }
    2812             :    else{
    2813           0 :     if(rec.asString("name")=="COMMONPB" && kpb !=PBMath::UNKNOWN ){
    2814           0 :       vps= new refim::VPSkyJones(msc, true, Quantity(rotatePAStep, "deg"), BeamSquint::GOFIGURE, Quantity(360.0, "deg"));
    2815             :       /////Don't know which parameter has pb threshold cutoff that the user want 
    2816             :       ////leaving at default
    2817             :       ////vps.setThreshold(minPB);
    2818             :       
    2819             :     }
    2820             :     else{
    2821           0 :       PBMath myPB(rec);
    2822           0 :       String whichPBMath;
    2823           0 :       PBMathInterface::namePBClass(myPB.whichPBClass(), whichPBMath);
    2824           0 :       os  << "Using the PB defined by " << whichPBMath << " for beam calculation for telescope " << telescop << LogIO::POST;
    2825           0 :       vps= new refim::VPSkyJones(telescop, myPB, Quantity(rotatePAStep, "deg"), BeamSquint::GOFIGURE, Quantity(360.0, "deg"));
    2826             :       //kpb=PBMath::DEFAULT;
    2827           0 :     }
    2828             :    
    2829           0 :     theFT = new refim::MosaicFTNew(vps, mLocation_p, stokes, 1000000000, 16, useAutoCorr, 
    2830           0 :                                    useDoublePrec, doConjBeams, gridpars_p.usePointing);
    2831           0 :     PBMathInterface::PBClass pbtype=((kpb==PBMath::EVLA) || multiTel)? PBMathInterface::COMMONPB: PBMathInterface::AIRY;
    2832           0 :     if(rec.asString("name")=="IMAGE")
    2833           0 :        pbtype=PBMathInterface::IMAGE;
    2834             :     ///Use Heterogenous array mode for the following
    2835           0 :     if((kpb == PBMath::UNKNOWN) || (kpb==PBMath::OVRO) || (kpb==PBMath::ACA)
    2836           0 :        || (kpb==PBMath::ALMA) || (kpb==PBMath::EVLA) || multiTel){
    2837           0 :       CountedPtr<refim::SimplePBConvFunc> mospb=new refim::HetArrayConvFunc(pbtype, itsVpTable);
    2838           0 :       static_cast<refim::MosaicFTNew &>(*theFT).setConvFunc(mospb);
    2839           0 :     }
    2840             :     ///////////////////make sure both FTMachine share the same conv functions.
    2841           0 :     theIFT= new refim::MosaicFTNew(static_cast<refim::MosaicFTNew &>(*theFT));
    2842             :    }
    2843           0 :   }
    2844             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2845             : 
    2846           0 :   void SynthesisImagerVi2::createSDFTMachine(CountedPtr<refim::FTMachine>& theFT,
    2847             :       CountedPtr<refim::FTMachine>& theIFT,
    2848             :       const String &pointingDirCol,
    2849             :       const String &convertFirst,
    2850             :       const Float skyPosThreshold,
    2851             :       const Bool /*doPBCorr*/,
    2852             :       const Float rotatePAStep,
    2853             :       const String& gridFunction,
    2854             :       const Int convSupport,
    2855             :       const Quantity& truncateSize,
    2856             :       const Quantity& gwidth,
    2857             :       const Quantity& jwidth,
    2858             :       const Float minWeight,
    2859             :       const Bool clipMinMax,
    2860             :       const Int cache,
    2861             :       const Int tile,
    2862             :       const String &stokes,
    2863             :       const Bool pseudoI) {
    2864             : //    // member variable itsVPTable is VP table name
    2865           0 :     LogIO os(LogOrigin("SynthesisImagerVi2", "createSDFTMachine", WHERE));
    2866             :     os << LogIO::NORMAL // Loglevel INFO
    2867           0 :        << "Performing single dish gridding..." << LogIO::POST;
    2868             :     os << LogIO::NORMAL1 // gridFunction is too cryptic for most users.
    2869           0 :        << "with convolution function " << gridFunction << LogIO::POST;
    2870             : 
    2871             :     // Now make the Single Dish Gridding
    2872             :     os << LogIO::NORMAL // Loglevel INFO
    2873           0 :        << "Gridding will use specified common tangent point:" << LogIO::POST;
    2874           0 :     os << LogIO::NORMAL << SynthesisUtilMethods::asComprehensibleDirectionString(phaseCenter_p)
    2875           0 :         << LogIO::POST; // Loglevel INFO
    2876           0 :     String const gridfunclower = downcase(gridFunction);
    2877           0 :     if(gridfunclower=="pb") {
    2878           0 :       refim::SkyJones *vp = nullptr;
    2879           0 :       MSColumns msc(*mss_p[0]);
    2880             :       // todo: NONE is OK?
    2881           0 :       BeamSquint::SquintType squintType = BeamSquint::NONE;
    2882           0 :       Quantity skyPosThresholdQuant((Double)skyPosThreshold+180.0, "deg");
    2883           0 :       Quantity parAngleStepQuant((Double)rotatePAStep, "deg");
    2884           0 :       if (itsVpTable.empty()) {
    2885             :         os << LogIO::NORMAL // Loglevel INFO
    2886           0 :             << "Using defaults for primary beams used in gridding" << LogIO::POST;
    2887           0 :         vp=new refim::VPSkyJones(msc, true, parAngleStepQuant, squintType,
    2888           0 :             skyPosThresholdQuant);
    2889             :       } else {
    2890             :         os << LogIO::NORMAL // Loglevel INFO
    2891           0 :             << "Using VP as defined in " << itsVpTable <<  LogIO::POST;
    2892           0 :         Table vpTable( itsVpTable );
    2893           0 :         vp=new refim::VPSkyJones(msc, vpTable, parAngleStepQuant, squintType,
    2894           0 :             skyPosThresholdQuant);
    2895           0 :       }
    2896           0 :       theFT = new refim::SDGrid(mLocation_p, *vp, cache/2, tile, gridfunclower,
    2897           0 :           convSupport, minWeight, clipMinMax);
    2898           0 :       theIFT = new refim::SDGrid(mLocation_p, *vp, cache/2, tile, gridfunclower,
    2899           0 :           convSupport, minWeight, clipMinMax);
    2900           0 :     } else if (gridfunclower=="gauss" || gridfunclower=="gjinc") {
    2901           0 :       DirectionCoordinate dirCoord = itsMaxCoordSys.directionCoordinate();
    2902           0 :       Vector<String> units = dirCoord.worldAxisUnits();
    2903           0 :       Vector<Double> increments = dirCoord.increment();
    2904           0 :       Quantity cellx(increments[0], units[0]);
    2905           0 :       Quantity celly(increments[1], units[1]);
    2906           0 :       if (cellx != celly &&
    2907           0 :           ((!truncateSize.getUnit().empty()||truncateSize.getUnit()=="pixel")
    2908           0 :               || (!gwidth.getUnit().empty()||gwidth.getUnit()=="pixel")
    2909           0 :               || (!jwidth.getUnit().empty()||jwidth.getUnit()=="pixel"))) {
    2910             :         os << LogIO::WARN
    2911             :             << "The " << gridFunction << " gridding doesn't support non-square grid." << endl
    2912           0 :             << "Result may be wrong." << LogIO::POST;
    2913             :       }
    2914             :       Float truncateValue, gwidthValue, jwidthValue;
    2915           0 :       if (truncateSize.getUnit().empty() || truncateSize.getUnit()=="pixel")
    2916           0 :         truncateValue = truncateSize.getValue();
    2917             :       else
    2918           0 :         truncateValue = truncateSize.getValue("rad")/celly.getValue("rad");
    2919           0 :       if (gwidth.getUnit().empty() || gwidth.getUnit()=="pixel")
    2920           0 :         gwidthValue = gwidth.getValue();
    2921             :       else
    2922           0 :         gwidthValue = gwidth.getValue("rad")/celly.getValue("rad");
    2923           0 :       if (jwidth.getUnit().empty() || jwidth.getUnit()=="pixel")
    2924           0 :         jwidthValue = jwidth.getValue();
    2925             :       else
    2926           0 :         jwidthValue = jwidth.getValue("rad")/celly.getValue("rad");
    2927           0 :       theFT = new refim::SDGrid(mLocation_p, cache/2, tile, gridfunclower,
    2928           0 :                         truncateValue, gwidthValue, jwidthValue, minWeight, clipMinMax);
    2929           0 :       theIFT = new refim::SDGrid(mLocation_p, cache/2, tile, gridfunclower,
    2930           0 :                         truncateValue, gwidthValue, jwidthValue, minWeight, clipMinMax);
    2931           0 :     }
    2932             :     else {
    2933           0 :       theFT = new refim::SDGrid(mLocation_p, cache/2, tile, gridfunclower,
    2934           0 :                         convSupport, minWeight, clipMinMax);
    2935           0 :       theIFT = new refim::SDGrid(mLocation_p, cache/2, tile, gridfunclower,
    2936           0 :                         convSupport, minWeight, clipMinMax);
    2937             :     }
    2938           0 :     theFT->setPointingDirColumn(pointingDirCol);
    2939           0 :     static_cast<refim::SDGrid*>(theFT.get())->setConvertFirst(convertFirst);
    2940           0 :     static_cast<refim::SDGrid*>(theIFT.get())->setConvertFirst(convertFirst);
    2941             : 
    2942             :     // turn on Pseudo Stokes mode if necessary
    2943           0 :     if (pseudoI || stokes == "XX" || stokes == "YY" || stokes == "XXYY"
    2944           0 :         || stokes == "RR" || stokes == "LL" || stokes == "RRLL") {
    2945           0 :       theFT->setPseudoIStokes(True);
    2946           0 :       theIFT->setPseudoIStokes(True);
    2947             :     }
    2948           0 :   }
    2949             :   
    2950             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2951             :   //// Get/Set Weight Grid.... write to disk and read
    2952             : 
    2953             :   /// todo : do for full mapper list, and taylor terms.
    2954             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2955             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    2956           0 :   Bool SynthesisImagerVi2::setWeightDensity( const String& weightimagename)
    2957             :   {
    2958           0 :     LogIO os(LogOrigin("SynthesisImagerVi2", "setWeightDensity()", WHERE));
    2959             :     try
    2960             :       {
    2961           0 :         if(weightimagename.size() !=0){
    2962           0 :           Table::isReadable(weightimagename, True);
    2963           0 :           PagedImage<Float> im(weightimagename);
    2964           0 :           imwgt_p=VisImagingWeight(im);
    2965           0 :           im.unlock();
    2966           0 :         }
    2967             :         else{
    2968             :           ////In memory weight densities is being deprecated...we should get rid of this bit
    2969           0 :           Int ndensities=1;
    2970           0 :           if((itsMappers.imageStore(0)->gridwt()->nelements())==5)
    2971           0 :             ndensities=(itsMappers.imageStore(0)->gridwt())->shape()[4];
    2972           0 :           Int nx=(itsMappers.imageStore(0)->gridwt())->shape()[0];
    2973           0 :           Int ny=(itsMappers.imageStore(0)->gridwt())->shape()[1];
    2974           0 :           Block<Matrix<Float> > densitymatrices(ndensities);
    2975           0 :           if(((itsMappers.imageStore(0)->gridwt())->shape().nelements())==5){
    2976           0 :             IPosition blc(Vector<Int>(5,0));
    2977           0 :             for (uInt fid=0;fid<densitymatrices.nelements();fid++)
    2978             :               {
    2979           0 :                 densitymatrices[fid].resize();
    2980           0 :                 Array<Float> lala;
    2981           0 :                 blc[4]=fid;
    2982           0 :                 itsMappers.imageStore(0)->gridwt()->getSlice(lala, blc, IPosition(5, nx, ny,1,1,1), True);
    2983           0 :                 densitymatrices[fid].reference( lala.reform(IPosition(2, nx, ny)));
    2984           0 :               }
    2985           0 :           }
    2986             :           else{
    2987           0 :             Array<Float> lala;
    2988           0 :             itsMappers.imageStore(0)->gridwt()->get(lala, True);
    2989           0 :             densitymatrices[0].reference( lala.reform(IPosition(2, nx, ny)));
    2990           0 :           }
    2991           0 :           imwgt_p.setWeightDensity( densitymatrices );
    2992           0 :         }
    2993             : 
    2994           0 :         vi_p->useImagingWeight(imwgt_p);
    2995           0 :         itsMappers.releaseImageLocks();
    2996             : 
    2997             :       }
    2998           0 :     catch (AipsError &x)
    2999             :       {
    3000           0 :         throw(AipsError("In setWeightDensity : "+x.getMesg()));
    3001           0 :       }
    3002           0 :     return true;
    3003           0 :   }
    3004             :   
    3005             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3006             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3007             : 
    3008             : 
    3009             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3010             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3011           0 :   void SynthesisImagerVi2::createVisSet(const Bool /*writeAccess*/)
    3012             :   {
    3013           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","createVisSet",WHERE) );
    3014             :     //cerr << "mss_p num" << mss_p.nelements() <<  " sel  " << fselections_p->size() << endl;
    3015           0 :     lockMSs();
    3016           0 :     if(mss_p.nelements() > uInt(fselections_p->size()) && (fselections_p->size() !=0)){
    3017           0 :       throw(AipsError("Discrepancy between Number of MSs and Frequency selections"));
    3018             :     }
    3019           0 :     vi_p=new vi::VisibilityIterator2(mss_p, vi::SortColumns(), true); //writeAccess);
    3020             : 
    3021           0 :     if(fselections_p->size() !=0){
    3022           0 :       CountedPtr<vi::FrequencySelections> tmpfselections=new FrequencySelections();
    3023             :       //Temporary fix till we get rid of old vi and we can get rid of tuneSelect
    3024           0 :       if(uInt(fselections_p->size()) > mss_p.nelements()){
    3025           0 :         for(uInt k=0 ; k <  mss_p.nelements(); ++k){
    3026           0 :           tmpfselections->add(fselections_p->get(k));
    3027             :         }
    3028             :       }
    3029             :       else{
    3030           0 :         tmpfselections=fselections_p;
    3031             :       }
    3032             :       ////end of fix for tuneSelectdata 
    3033           0 :       vi_p->setFrequencySelection (*tmpfselections);
    3034             : 
    3035           0 :     }
    3036             :     //
    3037           0 :     vi_p->originChunks();
    3038           0 :     vi_p->origin();
    3039             :     ////make sure to use the latest imaging weight scheme
    3040           0 :     vi_p->useImagingWeight(imwgt_p);
    3041           0 :     unlockMSs();
    3042           0 :   }// end of createVisSet
    3043             : 
    3044             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3045             :   // Method to run the AWProjectFT machine to seperate the CFCache
    3046             :   // construction from imaging.  This is done by splitting the
    3047             :   // operation in two steps: (1) run the FTM in "dry" mode to create a
    3048             :   // "blank" CFCache, and (2) re-load the "blank" CFCache and "fill"
    3049             :   // it.
    3050             :   //
    3051             :   // If someone can get me (SB) out of the horrible statc_casts in the
    3052             :   // code below, I will be most grateful (we are out of it! :-)).
    3053             :   //
    3054           0 :   void SynthesisImagerVi2::dryGridding(const Vector<String>& cfList)
    3055             :   {
    3056           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","dryGridding",WHERE) );
    3057             : 
    3058           0 :     rownr_t cohDone=0;
    3059           0 :     Int whichFTM=0;
    3060             :     (void)cfList;
    3061             :     // If not an AWProject-class FTM, make this call a NoOp.  Might be
    3062             :     // useful to extend it to other projection FTMs -- but later.
    3063           0 :     String ftmName = ((*(itsMappers.getFTM2(whichFTM)))).name();
    3064             : 
    3065           0 :     if (!((itsMappers.getFTM2(whichFTM,true))->isUsingCFCache())) return;
    3066             : 
    3067           0 :     os << "---------------------------------------------------- Dry Gridding ---------------------------------------------" << LogIO::POST;
    3068             : 
    3069             :     //
    3070             :     // Go through the entire MS in "dry" mode to set up a "blank"
    3071             :     // CFCache.  This is done by setting the AWPWBFT in dryrun mode
    3072             :     // and gridding.  The process of gridding emits CFCache, which
    3073             :     // will be "blank" in a dry run.
    3074             :     {
    3075           0 :       vi::VisBuffer2* vb=vi_p->getVisBuffer();
    3076           0 :       vi_p->originChunks();
    3077           0 :       vi_p->origin();
    3078           0 :       Double numberCoh=0;
    3079           0 :       for (uInt k=0; k< mss_p.nelements(); ++k)
    3080           0 :         numberCoh+=Double(mss_p[k]->nrow());
    3081             : 
    3082           0 :       ProgressMeter pm(1.0, numberCoh, "dryGridding", "","","",true);
    3083             : 
    3084           0 :       itsMappers.initializeGrid(*vi_p);
    3085             :     
    3086             :       // Set the gridder (iFTM) to run in dry-gridding mode
    3087           0 :       (itsMappers.getFTM2(whichFTM,true))->setDryRun(true);
    3088             : 
    3089           0 :       Bool aTermIsOff=False;
    3090             :       {
    3091           0 :         CountedPtr<refim::FTMachine> ftm=itsMappers.getFTM2(whichFTM,True);
    3092           0 :         CountedPtr<refim::ConvolutionFunction> cf=ftm->getAWConvFunc();
    3093           0 :         aTermIsOff = cf->getTerm("ATerm")->isNoOp();
    3094           0 :       }
    3095             : 
    3096             :       os << "Making a \"blank\" CFCache"
    3097             :          << (aTermIsOff?" (without the A-Term)":"")
    3098           0 :          << LogIO::WARN << LogIO::POST;
    3099             : 
    3100             :       // Step through the MS.  This triggers the logic in the Gridder
    3101             :       // to determine all the CFs that will be required.  These empty
    3102             :       // CFs are written to the CFCache which can then be filled via
    3103             :       // a call to fillCFCache().
    3104           0 :       for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    3105             :         {
    3106           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    3107             :             {
    3108           0 :               if (SynthesisUtilMethods::validate(*vb)!=SynthesisUtilMethods::NOVALIDROWS) 
    3109             :                 {
    3110           0 :                   itsMappers.grid(*vb, true, refim::FTMachine::OBSERVED, whichFTM);
    3111           0 :                   cohDone += vb->nRows();
    3112           0 :                   pm.update(Double(cohDone));
    3113             :                   // If there is no term that depends on time, don't iterate over the entire data base
    3114           0 :                   if (aTermIsOff) break;
    3115             :                 }
    3116             :             }
    3117             :         }
    3118           0 :     }
    3119           0 :     if (cohDone == 0) os << "No valid rows found in dryGridding." << LogIO::EXCEPTION << LogIO::POST;
    3120             :     // Unset the dry-gridding mode.
    3121           0 :     (itsMappers.getFTM2(whichFTM,true))->setDryRun(false);
    3122             : 
    3123             :     //itsMappers.checkOverlappingModels("restore");
    3124           0 :     unlockMSs();
    3125             :     //fillCFCache(cfList);
    3126           0 :   }
    3127             :   //
    3128             :   // Re-load the CFCache from the disk using the supplied list of CFs
    3129             :   // (as cfList).  Then extract the ConvFunc object (which was setup
    3130             :   // in the FTM) and call it's makeConvFunction2() to fill the CF.
    3131             :   // Finally, unset the dry-run mode of the FTM.
    3132             :   //
    3133           0 :   void SynthesisImagerVi2::fillCFCache(const Vector<String>& cfList,
    3134             :                                        const String& ftmName,
    3135             :                                        const String& cfcPath,
    3136             :                                        const Bool& psTermOn,
    3137             :                                        const Bool& aTermOn,
    3138             :                                        const Bool& conjBeams)
    3139             :     {
    3140           0 :       LogIO os( LogOrigin("SynthesisImagerVi2","fillCFCache",WHERE) );
    3141             :       // If not an AWProject-class FTM, make this call a NoOp.  Might be
    3142             :       // useful to extend it to other projection FTMs -- but later.
    3143             :       // String ftmName = ((*(itsMappers.getFTM(whichFTM)))).name();
    3144             : 
    3145           0 :       if (!ftmName.contains("awproject") and
    3146           0 :           !ftmName.contains("multitermftnew")) return;
    3147             :       //if (!ftmName.contains("awproject")) return;
    3148             :       
    3149           0 :       os << "---------------------------------------------------- fillCFCache ---------------------------------------------" << LogIO::POST;
    3150             : 
    3151             :       //String cfcPath = itsMappers.getFTM(whichFTM)->getCacheDir();
    3152             :       //String imageNamePrefix=itsMappers.getFTM(whichFTM)->getCFCache()->getWtImagePrefix();
    3153             : 
    3154             :       //cerr << "Path = " << path << endl;
    3155             : 
    3156             :       // CountedPtr<AWProjectWBFTNew> tmpFT = new AWProjectWBFTNew(static_cast<AWProjectWBFTNew &> (*(itsMappers.getFTM(whichFTM))));
    3157             : 
    3158             : 
    3159           0 :       Float dPA=360.0,selectedPA=2*360.0;
    3160           0 :       if (cfList.nelements() > 0)
    3161             :         {
    3162           0 :           CountedPtr<refim::CFCache> cfCacheObj = new refim::CFCache();
    3163             :           //Vector<String> wtCFList; wtCFList.resize(cfList.nelements());
    3164             :           //for (Int i=0; i<wtCFList.nelements(); i++) wtCFList[i] = "WT"+cfList[i];
    3165             :           //Directory dir(path);
    3166           0 :           Vector<String> cfList_p=cfList;//dir.find(Regex(Regex::fromPattern("CFS*")));
    3167           0 :           Vector<String> wtCFList_p;
    3168           0 :           wtCFList_p.resize(cfList_p.nelements());
    3169           0 :           for (Int i=0; i<(Int)wtCFList_p.nelements(); i++) wtCFList_p[i]="WT"+cfList_p[i];
    3170             : 
    3171             :           //cerr << cfList_p << endl;
    3172           0 :           cfCacheObj->setCacheDir(cfcPath.data());
    3173             : 
    3174           0 :           os << "Re-loading the \"blank\" CFCache for filling" << LogIO::WARN << LogIO::POST;
    3175             : 
    3176           0 :           cfCacheObj->initCacheFromList2(cfcPath, cfList_p, wtCFList_p,
    3177             :                                          selectedPA, dPA,CFC_VERBOSE);
    3178             : 
    3179             :           // tmpFT->setCFCache(cfCacheObj);
    3180           0 :           Vector<Double> uvScale, uvOffset;
    3181           0 :           Matrix<Double> vbFreqSelection;
    3182           0 :           CountedPtr<refim::CFStore2> cfs2 = CountedPtr<refim::CFStore2>(&cfCacheObj->memCache2_p[0],false);//new CFStore2;
    3183           0 :           CountedPtr<refim::CFStore2> cfwts2 =  CountedPtr<refim::CFStore2>(&cfCacheObj->memCacheWt2_p[0],false);//new CFStore2;
    3184             : 
    3185             :           //
    3186             :           // Get whichFTM from itsMappers (SIMapperCollection) and
    3187             :           // cast it as AWProjectWBFTNew.  Then get the ConvFunc from
    3188             :           // the FTM and cast it as AWConvFunc.  Finally call
    3189             :           // AWConvFunc::makeConvFunction2().
    3190             :           //
    3191             :           // (static_cast<AWConvFunc &> 
    3192             :           //  (*(static_cast<AWProjectWBFTNew &> (*(itsMappers.getFTM(whichFTM)))).getAWConvFunc())
    3193             :           //  ).makeConvFunction2(String(path), uvScale, uvOffset, vbFreqSelection,
    3194             :           //                   *cfs2, *cfwts2);
    3195             : 
    3196             :           // This is a global methond in AWConvFunc.  Does not require
    3197             :           // FTM to be constructed (which can be expensive in terms of
    3198             :           // memory footprint).
    3199           0 :           refim::AWConvFunc::makeConvFunction2(String(cfcPath), uvScale, uvOffset, vbFreqSelection,
    3200           0 :                                                *cfs2, *cfwts2, psTermOn, aTermOn, conjBeams);
    3201           0 :         }
    3202             :       //cerr << "Mem used = " << itsMappers.getFTM(whichFTM)->getCFCache()->memCache2_p[0].memUsage() << endl;
    3203             :       //(static_cast<AWProjectWBFTNew &> (*(itsMappers.getFTM(whichFTM)))).getCFCache()->initCache2();
    3204           0 :     }
    3205             : 
    3206             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3207           0 :   void SynthesisImagerVi2::reloadCFCache()
    3208             :   {
    3209           0 :       LogIO os( LogOrigin("SynthesisImagerVi2","reloadCFCache",WHERE) );
    3210           0 :       Int whichFTM=0; 
    3211           0 :       CountedPtr<refim::FTMachine> ftm=itsMappers.getFTM2(whichFTM,true);
    3212             : 
    3213             :       // Proceed only if FMTs uses the CFCache mechanism. The first FTM
    3214             :       // in the Mapper is used to make this decision.  Not sure if the
    3215             :       // framework pipes allow other FTMs in SIMapper to be
    3216             :       // fundamentally different. If it does, and if that is
    3217             :       // triggered, the current decision may be insufficient.
    3218           0 :       if (!(ftm->isUsingCFCache())) return; // Better check than checking against FTM name
    3219             :       
    3220           0 :       os << "-------------------------------------------- Re-load CFCache ---------------------------------------------" << LogIO::POST;
    3221             : 
    3222             :       // Following code that distinguishes between MultiTermFTM and
    3223             :       // all others should ideally be replaced with a polymorphic
    3224             :       // solution.  I.e. all FTMs should have a working getFTM2(bool)
    3225             :       // method.  This is required since MultiTermFTM is a container
    3226             :       // FTM and it's getFTM2() returns the internal (per-MTMFS term)
    3227             :       // FTMs.  Non-container FTMs must return a pointer to
    3228             :       // themselves.  The if-else below is because attempts to make
    3229             :       // AWProjectFT::getFTM2() work have failed.
    3230             :       //
    3231             :       // Control reaches this stage only if the isUsingCFCache() test
    3232             :       // above return True.  The only FTMs what will pass that test
    3233             :       // for now are AWProjectFT (and its derivatives) and
    3234             :       // MultiTermFTM if it is constructed with AWP.
    3235             :       //
    3236           0 :       CountedPtr<refim::CFCache> cfc;
    3237           0 :       if (ftm->name().contains("MultiTerm")) cfc = ftm->getFTM2(true)->getCFCache();
    3238           0 :       else                                   cfc = ftm->getCFCache();
    3239           0 :       cfc->setLazyFill((refim::SynthesisUtils::getenv("CFCache.LAZYFILL",1)==1));
    3240           0 :       cfc->initCache2();
    3241             : 
    3242             : 
    3243             :       // String path,imageNamePrefix;
    3244             :       // if (ftm->name().contains("MultiTerm"))
    3245             :       //        {
    3246             :       //          path = ftm->getFTM2(true)->getCacheDir();
    3247             :       //          imageNamePrefix = ftm->getFTM2(true)->getCFCache()->getWtImagePrefix();
    3248             :       //        }
    3249             :       // else
    3250             :       //        {
    3251             :       //          path = ftm->getCacheDir();
    3252             :       //          imageNamePrefix = ftm->getCFCache()->getWtImagePrefix();
    3253             :       //        }
    3254             :         
    3255             : 
    3256             :       // CountedPtr<refim::CFCache> cfCacheObj = new refim::CFCache();
    3257             :       // cfCacheObj->setCacheDir(path.c_str());
    3258             :       // cfCacheObj->setWtImagePrefix(imageNamePrefix.c_str());
    3259             :       // cfCacheObj->setLazyFill((refim::SynthesisUtils::getenv("CFCache.LAZYFILL",1)==1));
    3260             :       // cfCacheObj->initCache2();
    3261             : 
    3262             :       // // This assumes the itsMappers is always SIMapperCollection.
    3263             :       // for (whichFTM = 0; whichFTM < itsMappers.nMappers(); whichFTM++)
    3264             :       //        {
    3265             :       //          CountedPtr<refim::FTMachine> ifftm=itsMappers.getFTM2(whichFTM,true),
    3266             :       //            fftm=itsMappers.getFTM2(whichFTM,false);
    3267             :         
    3268             :       //          ifftm->setCFCache(cfCacheObj,true);
    3269             :       //          fftm->setCFCache(cfCacheObj,true);
    3270             :       //        }
    3271           0 :   }
    3272             :     //////////////////
    3273           0 :    bool  SynthesisImagerVi2::makeMosaicSensitivity(){
    3274             :      ///We will bother with the first image. As A projection style gridding
    3275             :      ///usually is done on that first image.
    3276             :      /// if necessary in the future we will need to migrate this to SIMapper to
    3277             :      /// do it for all fields if multiple fields are A-projected. 
    3278           0 :      if(!itsMappers.getFTM2(0))
    3279           0 :        return False;
    3280             :      /////////////////
    3281           0 :     vi::VisBuffer2* vb=vi_p->getVisBuffer();
    3282           0 :      vi_p->originChunks();
    3283           0 :      vi_p->origin();
    3284           0 :      Double numcoh=0;
    3285           0 :       for (uInt k=0; k< mss_p.nelements(); ++k)
    3286           0 :         numcoh+=Double(mss_p[k]->nrow());
    3287             :       ProgressMeter pm(1.0, numcoh, 
    3288           0 :                           "Gridding Weights for PB", "","","",true);
    3289           0 :       rownr_t cohDone=0;
    3290             :       
    3291             : 
    3292             :       ///This will initialize weight grid too.
    3293           0 :       itsMappers.initializeGrid(*vi_p,True);
    3294           0 :       for (vi_p->originChunks(); vi_p->moreChunks();vi_p->nextChunk())
    3295             :         {
    3296             :           
    3297           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    3298             :             {
    3299           0 :               if (SynthesisUtilMethods::validate(*vb)!=SynthesisUtilMethods::NOVALIDROWS)
    3300             :                     {
    3301           0 :                       itsMappers.getFTM2(0)->gridImgWeights(*vb);
    3302           0 :                       cohDone += vb->nRows();
    3303           0 :                       pm.update(Double(cohDone));
    3304             :                     }
    3305             :                 }
    3306             :         }
    3307             :       //now load the images in weight and sumwt
    3308           0 :       itsMappers.getFTM2(0)-> finalizeToWeightImage(*vb, imageStore(0));  
    3309             :       //cerr << "@@@@@@@MAKING PB " << endl;
    3310           0 :       return True;
    3311             :      
    3312             : 
    3313           0 :    }
    3314             : 
    3315             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3316           0 :   Bool SynthesisImagerVi2::loadMosaicSensitivity(){
    3317           0 :     String ftmname=itsMappers.getFTM2(0)->name();
    3318             :     
    3319           0 :     if(ftmname.contains("Mosaic") || ftmname.contains("AWProjectWB")){
    3320             :       //sumwt has been calcuated
    3321           0 :       Bool donesumwt=(max(itsMappers.imageStore(0)->sumwt()->get()) > 0.0);
    3322             :       //cerr << "Done sumwght " << donesumwt << max(itsMappers.imageStore(0)->sumwt()->get()) << endl;
    3323           0 :       if(donesumwt){
    3324           0 :         IPosition shp=itsMappers.imageStore(0)->weight()->shape();
    3325           0 :         CoordinateSystem cs=itsMappers.imageStore(0)->weight()->coordinates();
    3326           0 :         CountedPtr<TempImage<Float> > wgtim=new TempImage<Float>(shp, cs);
    3327           0 :         wgtim->copyData(*(itsMappers.imageStore(0)->weight()));
    3328           0 :         (static_cast<refim::FTMachine &>( *(itsMappers.getFTM2(0,False)))).setWeightImage(*wgtim);
    3329           0 :         static_cast<refim::FTMachine &>( *(itsMappers.getFTM2(0,True))).setWeightImage(*wgtim);
    3330           0 :         return true;
    3331           0 :       }
    3332             : 
    3333             : 
    3334             :     }
    3335           0 :     return false;
    3336           0 :   }
    3337             :   /////////////////////////////////////////////////
    3338           0 :   Record SynthesisImagerVi2::apparentSensitivity() 
    3339             :   {
    3340           0 :     LogIO os(LogOrigin("SynthesisImagerVi2", "apparentSensitivity()", WHERE));
    3341             :     
    3342           0 :     Record outrec;
    3343             :     try {
    3344             : 
    3345             :       os << LogIO::NORMAL // Loglevel INFO
    3346             :          << "Calculating apparent sensitivity from MS weights, as modified by gridding weight function"
    3347           0 :          << LogIO::POST;
    3348             :       os << LogIO::NORMAL // Loglevel INFO
    3349             :          << "(assuming that MS weights have correct scale and units)"
    3350           0 :          << LogIO::POST;
    3351             :       
    3352           0 :       Double sumNatWt=0.0;
    3353           0 :       Double sumGridWt=0.0;
    3354           0 :       Double sumGridWt2OverNatWt=0.0;
    3355             :     
    3356           0 :       Float iNatWt(0.0),iGridWt(0.0);
    3357             :       
    3358           0 :       vi::VisBuffer2* vb = vi_p->getVisBuffer();
    3359           0 :       vi_p->originChunks();
    3360           0 :       vi_p->origin();
    3361             :       
    3362             :       // Discover if weightSpectrum non-trivially available
    3363           0 :       Bool doWtSp=vi_p->weightSpectrumExists();
    3364             : 
    3365             :       //////
    3366           0 :       for(vi_p->originChunks(); vi_p->moreChunks(); vi_p->nextChunk())
    3367             :         {
    3368           0 :           for (vi_p->origin(); vi_p->more(); vi_p->next())
    3369             :             {
    3370           0 :               auto nRow=vb->nRows();
    3371           0 :               const Vector<Bool>& rowFlags(vb->flagRow());
    3372             : 
    3373           0 :               const Vector<Int>& a1(vb->antenna1()), a2(vb->antenna2());
    3374             : 
    3375             :               // Extract weights correctly (use WEIGHT_SPECTRUM, if available)
    3376           0 :               Int nCorr=vb->nCorrelations();
    3377           0 :               Matrix<Float> wtm;
    3378           0 :               Cube<Float> wtc;
    3379           0 :               if (doWtSp)
    3380             :                 // WS available [nCorr,nChan,nRow]
    3381           0 :                 wtc.reference(vb->weightSpectrum());       
    3382             :               else {
    3383             :                 // WS UNavailable weight()[nCorr,nRow] --> [nCorr,nChan,nRow]
    3384           0 :                 wtc.reference(vb->weight().reform(IPosition(3,nCorr,1,nRow)));  // unchan'd weight as single-chan
    3385             :               }
    3386           0 :               Int nChanWt=wtc.shape()(1);  // Might be 1 (no WtSp)
    3387             : 
    3388           0 :               Cube<Bool> flagCube(vb->flagCube());
    3389           0 :               for (rownr_t row=0; row<nRow; row++) {
    3390           0 :                 if (!rowFlags(row) && a1(row)!=a2(row)) {  // exclude ACs
    3391             : 
    3392           0 :                   for (Int ich=0;ich<vb->nChannels();++ich) {
    3393           0 :                     if( !flagCube(0,ich,row) && !flagCube(nCorr-1,ich,row)) {  // p-hands unflagged
    3394             : 
    3395             :                       // Accumulate relevant info
    3396             : 
    3397             :                       // Simple sum of p-hand for now
    3398           0 :                       iNatWt=wtc(0,ich%nChanWt,row)+wtc(nCorr-1,ich%nChanWt,row);
    3399             : 
    3400           0 :                       iGridWt=2.0f*vb->imagingWeight()(ich,row);
    3401             : 
    3402           0 :                       if (iGridWt>0.0 && iNatWt>0.0) {
    3403           0 :                         sumNatWt+=(iNatWt);
    3404           0 :                         sumGridWt+=(iGridWt);
    3405           0 :                         sumGridWt2OverNatWt+=(iGridWt*iGridWt/iNatWt);
    3406             :                       }
    3407             :                     }
    3408             :                   }
    3409             :                 }
    3410             :               } // row
    3411           0 :             } // vb
    3412             :         } // chunks
    3413             :       
    3414           0 :       if (sumNatWt==0.0) {
    3415           0 :         os << "Cannot calculate sensitivity: sum of selected natural weights is zero" << LogIO::EXCEPTION;
    3416             :       }
    3417           0 :       if (sumGridWt==0.0) {
    3418           0 :         os << "Cannot calculate sensitivity: sum of gridded weights is zero" << LogIO::EXCEPTION;
    3419             :       }
    3420             : 
    3421           0 :       Double effSensitivity = sqrt(sumGridWt2OverNatWt)/sumGridWt;
    3422             : 
    3423           0 :       Double natSensitivity = 1.0/sqrt(sumNatWt);
    3424           0 :       Double relToNat=effSensitivity/natSensitivity;
    3425             : 
    3426             :       os << LogIO::NORMAL << "RMS Point source sensitivity  : " // Loglevel INFO
    3427             :          << effSensitivity      //  << " Jy/beam"       // actually, units are arbitrary
    3428           0 :          << LogIO::POST;
    3429             :       os << LogIO::NORMAL // Loglevel INFO
    3430           0 :          << "Relative to natural weighting : " << relToNat << LogIO::POST;
    3431             : 
    3432             :       // Fill output Record
    3433           0 :       outrec.define("relToNat",relToNat);
    3434           0 :       outrec.define("effSens",effSensitivity);
    3435             : 
    3436           0 :     } catch (AipsError x) {
    3437           0 :       throw(x);
    3438             :       return outrec;
    3439           0 :     } 
    3440           0 :     return outrec;
    3441             : 
    3442           0 :   }
    3443             :   /////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3444             : 
    3445           0 :   Bool SynthesisImagerVi2::makePB()
    3446             :   {
    3447           0 :       LogIO os( LogOrigin("SynthesisImagerVi2","makePB",WHERE) );
    3448             : 
    3449           0 :       if( itsMakeVP==False )
    3450             :         {
    3451           0 :           if( ((itsMappers.getFTM2(0))->name())!="MultiTermFTNew")
    3452           0 :             if(!loadMosaicSensitivity()){
    3453           0 :               if(!makeMosaicSensitivity())
    3454           0 :                 throw(AipsError("Problem with making/loading sensitivity image for A -projection gridder"));
    3455             :             }
    3456             :         }
    3457             :       else
    3458             :         {
    3459           0 :           Bool doDefaultVP = itsVpTable.length()>0 ? False : True;
    3460             : 
    3461           0 :           CoordinateSystem coordsys=itsMappers.imageStore(0)->getCSys();
    3462           0 :           String telescope=coordsys.obsInfo().telescope();
    3463             :           
    3464           0 :           if (doDefaultVP) {
    3465             :             
    3466           0 :             MSAntennaColumns ac(mss_p[0]->antenna());
    3467           0 :             Double dishDiam=ac.dishDiameter()(0);
    3468           0 :             if(!allEQ(ac.dishDiameter().getColumn(), dishDiam))
    3469             :               os << LogIO::WARN
    3470             :                  << "The MS has multiple antenna diameters ..PB could be wrong "
    3471           0 :                  << LogIO::POST;
    3472           0 :             return makePBImage( telescope, False, dishDiam);
    3473           0 :           }
    3474             :           else{
    3475           0 :             return makePBImage(telescope );     
    3476             :           }
    3477             :           
    3478           0 :         }
    3479             :  
    3480           0 :       return False;
    3481           0 :   }
    3482             : 
    3483             : /////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
    3484             : 
    3485           0 :   Bool SynthesisImagerVi2::makePrimaryBeam(PBMath& pbMath)
    3486             :   {
    3487           0 :     LogIO os( LogOrigin("SynthesisImagerVi2","makePrimaryBeam",WHERE) );
    3488             : 
    3489           0 :     os << "vi2 : Evaluating Primary Beam model onto image grid(s)" << LogIO::POST;
    3490             : 
    3491           0 :     itsMappers.initPB();
    3492             : 
    3493           0 :     vi::VisBuffer2* vb = vi_p->getVisBuffer();
    3494           0 :     vi_p->originChunks();
    3495           0 :     vi_p->origin();
    3496           0 :     std::map<Int, std::set<Int>> fieldsDone;
    3497           0 :     VisBufferUtil vbU(*vb);
    3498             :     ///////if tracking a moving source
    3499           0 :     MDirection origMovingDir;
    3500           0 :     MDirection newPhaseCenter;
    3501           0 :     Bool trackBeam=getMovingDirection(*vb, origMovingDir, True);
    3502             :     //////
    3503           0 :     for(vi_p->originChunks(); vi_p->moreChunks(); vi_p->nextChunk())
    3504             :       {
    3505           0 :         for (vi_p->origin(); vi_p->more(); vi_p->next())
    3506             :           {
    3507           0 :             Bool fieldDone=False;
    3508           0 :             if(fieldsDone.count(vb->msId() >0)){
    3509           0 :               fieldDone=fieldDone || (fieldsDone[vb->msId()].count(vb->fieldId()(0)) > 0);
    3510             :             }
    3511             :             else{
    3512           0 :               fieldsDone[vb->msId()]=std::set<int>();
    3513             :             }
    3514           0 :             if(!fieldDone){
    3515           0 :               fieldsDone[vb->msId()].insert(vb->fieldId()(0));
    3516           0 :               if(trackBeam){
    3517           0 :                 MDirection newMovingDir;
    3518           0 :                 getMovingDirection(*vb, newMovingDir);
    3519             :                 //newPhaseCenter=vb->phaseCenter();
    3520           0 :                 newPhaseCenter=vbU.getPhaseCenter(*vb);
    3521           0 :                 newPhaseCenter.shift(MVDirection(-newMovingDir.getAngle()+origMovingDir.getAngle()), False);
    3522           0 :               }
    3523           0 :               itsMappers.addPB(*vb,pbMath, newPhaseCenter, trackBeam);
    3524             :               
    3525             :             }
    3526             :           }
    3527             :       }
    3528           0 :     itsMappers.releaseImageLocks();
    3529           0 :     unlockMSs();
    3530             : 
    3531           0 :     return True;
    3532           0 :   }// end makePB
    3533             : 
    3534           0 :   Bool SynthesisImagerVi2::getMovingDirection(const vi::VisBuffer2& vb,  MDirection& outDir, const Bool useImageEpoch){
    3535           0 :     MDirection movingDir;
    3536           0 :     Bool trackBeam=False;
    3537             :       
    3538           0 :     MeasFrame mFrame(MEpoch(Quantity(vb.time()(0), "s"), MSColumns(vb.ms()).timeMeas()(0).getRef()), mLocation_p);
    3539           0 :     if(useImageEpoch){
    3540           0 :       mFrame.resetEpoch((itsMappers.imageStore(0))->getCSys().obsInfo().obsDate());
    3541             : 
    3542             :     }
    3543           0 :     if(movingSource_p != ""){
    3544             :       MDirection::Types refType;
    3545           0 :       trackBeam=True;
    3546           0 :       if(Table::isReadable(movingSource_p, False)){
    3547             :         //seems to be a table so assuming ephemerides table
    3548           0 :         Table laTable(movingSource_p);
    3549           0 :         Path leSentier(movingSource_p);
    3550           0 :         MeasComet laComet(laTable, leSentier.absoluteName());
    3551           0 :         movingDir.setRefString("COMET");
    3552           0 :         mFrame.set(laComet);
    3553           0 :       }
    3554             :       ///if not a table 
    3555           0 :       else  if(casacore::MDirection::getType(refType, movingSource_p)){
    3556           0 :         if(refType > casacore::MDirection::N_Types && refType < casacore::MDirection:: N_Planets ){
    3557             :           ///A known planet
    3558           0 :           movingDir.setRefString(movingSource_p);
    3559             :         }
    3560             :       }
    3561           0 :       else if(upcase(movingSource_p)=="TRACKFIELD"){
    3562           0 :         VisBufferUtil vbU(vb);
    3563           0 :         movingDir=vbU.getEphemDir(vb, MEpoch(mFrame.epoch()).get("s").getValue());
    3564           0 :       }
    3565             :       else{
    3566           0 :         throw(AipsError("Erroneous tracking direction set to make pb"));
    3567             :       }
    3568           0 :       MDirection::Ref outref1(MDirection::AZEL, mFrame);
    3569           0 :       MDirection tmphazel=MDirection::Convert(movingDir, outref1)();
    3570           0 :       MDirection::Ref outref(vb.phaseCenter().getRef().getType(), mFrame);
    3571           0 :       outDir=MDirection::Convert(tmphazel, outref)();  
    3572           0 :     }
    3573             :     else{
    3574           0 :       outDir=vb.phaseCenter();
    3575           0 :       trackBeam=False;
    3576             :     }
    3577           0 :       return trackBeam;
    3578             : 
    3579             : 
    3580           0 :   }
    3581           0 :   CountedPtr<vi::VisibilityIterator2> SynthesisImagerVi2::getVi(){
    3582           0 :         return vi_p;  
    3583             :   }
    3584           0 :   CountedPtr<refim::FTMachine> SynthesisImagerVi2::getFTM(const Int fid, Bool ift){
    3585           0 :         if(itsMappers.nMappers() <=fid)
    3586           0 :                 throw(AipsError("Mappers have not been set for field "+String::toString(fid)));
    3587           0 :         return (itsMappers.getFTM2(fid, ift));
    3588             :           
    3589             :   }
    3590           0 :   void SynthesisImagerVi2::updateImageBeamSet(Record& returnRec){
    3591           0 :     if(returnRec.isDefined("imageid") && returnRec.asInt("imageid")==0){
    3592             :       //ImageInfo ii=(itsMappers.imageStore(0)->psf())->imageInfo();
    3593           0 :       Vector<Int> chanRange(0);
    3594           0 :       if(returnRec.isDefined("chanrange"))
    3595           0 :         chanRange=returnRec.asArrayInt("chanrange");
    3596           0 :       Int npol=(itsMappers.imageStore(0)->getShape())(2);
    3597           0 :       Int nchan=(itsMappers.imageStore(0)->getShape())(3);
    3598           0 :       if(chanRange.nelements() ==2 && chanRange(1) < nchan){
    3599             : 
    3600           0 :         ImageBeamSet iibeamset=cubePsfImageInfo_p.getBeamSet();
    3601           0 :         Matrix<GaussianBeam> mbeams=iibeamset.getBeams();
    3602           0 :         if(mbeams.nelements()==0){
    3603           0 :           mbeams.resize(itsMappers.imageStore(0)->getShape()(3), itsMappers.imageStore(0)->getShape()(2));
    3604           0 :           mbeams.set(GaussianBeam(Vector<Quantity>(3, Quantity(1e-12, "arcsec"))));
    3605             :         }
    3606           0 :         Cube<Float> recbeams(returnRec.asArrayFloat("beams"));
    3607           0 :         for(Int c=chanRange[0]; c <= chanRange[1]; ++c){
    3608           0 :           for(Int p=0; p < npol; ++p){
    3609           0 :             mbeams(c,p)=GaussianBeam(Quantity(recbeams(c-chanRange[0], p, 0),"arcsec"), Quantity(recbeams(c-chanRange[0], p, 1),"arcsec"), Quantity(recbeams(c-chanRange[0], p, 2),"deg"));
    3610             : 
    3611             :           }
    3612             :         }
    3613           0 :         cubePsfImageInfo_p.setBeams(ImageBeamSet(mbeams));
    3614             : 
    3615           0 :       }
    3616             :       //itsMappers.imageStore(0)->psf()->setImageInfo(ii);
    3617             :       //itsMappers.imageStore(0)->psf()->unlock();
    3618             : 
    3619             :       
    3620           0 :     }
    3621           0 :   }
    3622             : 
    3623             : } //# NAMESPACE CASA - END
    3624             : 

Generated by: LCOV version 1.16