LCOV - code coverage report
Current view: top level - msvis/MSVis - MSContinuumSubtractor.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 407 0.0 %
Date: 2024-10-10 19:51:30 Functions: 0 14 0.0 %

          Line data    Source code
       1             : //# MSContinuumSubtractor.cc:  Subtract continuum from spectral line data
       2             : //# Copyright (C) 2004
       3             : //# Associated Universities, Inc. Washington DC, USA.
       4             : //#
       5             : //# This library is free software; you can redistribute it and/or modify it
       6             : //# under the terms of the GNU Library General Public License as published by
       7             : //# the Free Software Foundation; either version 2 of the License, or (at your
       8             : //# option) any later version.
       9             : //#
      10             : //# This library is distributed in the hope that it will be useful, but WITHOUT
      11             : //# ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
      12             : //# FITNESS FOR A PARTICULAR PURPOSE.  See the GNU Library General Public
      13             : //# License for more details.
      14             : //#
      15             : //# You should have received a copy of the GNU Library General Public License
      16             : //# along with this library; if not, write to the Free Software Foundation,
      17             : //# Inc., 675 Massachusetts Ave, Cambridge, MA 02139, USA.
      18             : //#
      19             : //# Correspondence concerning AIPS++ should be addressed as follows:
      20             : //#        Internet email: casa-feedback@nrao.edu.
      21             : //#        Postal address: AIPS++ Project Office
      22             : //#                        National Radio Astronomy Observatory
      23             : //#                        520 Edgemont Road
      24             : //#                        Charlottesville, VA 22903-2475 USA
      25             : //#
      26             : //# $Id$
      27             : //#
      28             : #include <msvis/MSVis/MSContinuumSubtractor.h>
      29             : 
      30             : #include <casacore/casa/Quanta/QuantumHolder.h>
      31             : #include <casacore/casa/Containers/RecordFieldId.h>
      32             : #include <casacore/measures/Measures/Stokes.h>
      33             : #include <casacore/ms/MeasurementSets/MSColumns.h>
      34             : #include <casacore/ms/MeasurementSets/MeasurementSet.h>
      35             : #include <casacore/ms/MSSel/MSSelector.h>
      36             : #include <casacore/ms/MSSel/MSSelection.h>
      37             : #include <casacore/ms/MSSel/MSSelectionTools.h>
      38             : #include <msvis/MSVis/VisSet.h>
      39             : #include <msvis/MSVis/VisibilityIteratorImpl2.h>
      40             : #include <msvis/MSVis/ViFrequencySelection.h>
      41             : #include <msvis/MSVis/IteratingParameters.h>
      42             : #include <msvis/MSVis/AveragingVi2Factory.h>
      43             : #include <msvis/MSVis/LayeredVi2Factory.h>
      44             : #include <casacore/scimath/Fitting/LinearFit.h>
      45             : #include <casacore/scimath/Functionals/Polynomial.h>
      46             : #include <casacore/casa/Arrays/ArrayLogical.h>
      47             : #include <casacore/casa/Arrays/ArrayMath.h>
      48             : #include <casacore/casa/Arrays/ArrayUtil.h>
      49             : #include <casacore/casa/Containers/Record.h>
      50             : #include <casacore/casa/Exceptions/Error.h>
      51             : #include <casacore/casa/Logging/LogIO.h>
      52             : #include <casacore/tables/TaQL/TableParse.h>
      53             : #include <iostream>
      54             : 
      55             : using namespace casacore;
      56             : namespace casa { //# NAMESPACE CASA - BEGIN
      57             : 
      58             : //
      59             : // Constructor assigns pointer (if MS goes out of scope you will get rubbish)
      60           0 : MSContinuumSubtractor::MSContinuumSubtractor (MeasurementSet& ms)
      61           0 :   : ms_p(&ms),itsSolInt(0.0),itsOrder(0),itsMode("subtract")
      62             : {
      63             : 
      64             :   // Make a VisSet so scratch columns are created
      65           0 :   Block<Int> nosort(0);
      66           0 :   Matrix<Int> noselection;
      67           0 :   Double timeInterval=0.0;
      68           0 :   Bool compress(False);
      69           0 :   VisSet vs(ms,nosort,noselection,timeInterval,compress);
      70             : 
      71           0 :   nSpw_= vs.numberSpw();
      72             : 
      73           0 : }
      74             : 
      75             : 
      76             : //
      77             : // Assignment operator
      78             : //
      79           0 : MSContinuumSubtractor& MSContinuumSubtractor::operator=(MSContinuumSubtractor& other)
      80             : {
      81           0 :   if (this==&other) return *this;
      82           0 :   ms_p = other.ms_p;
      83           0 :   return *this;
      84             : }
      85             : 
      86             : 
      87             : //
      88             : // Destructor does nothing
      89             : //
      90           0 : MSContinuumSubtractor::~MSContinuumSubtractor()
      91           0 : {}
      92             : 
      93             : // Set the required field Ids
      94           0 : void MSContinuumSubtractor::setField(const String& field)
      95             : {
      96             : 
      97           0 :   MSSelection mssel;
      98           0 :   mssel.setFieldExpr(field);
      99           0 :   Vector<Int> fldlist;
     100           0 :   fldlist=mssel.getFieldList(ms_p);
     101             : 
     102           0 :   setFields(fldlist);
     103             : 
     104           0 : }
     105             : 
     106           0 : void MSContinuumSubtractor::setFields(const Vector<Int>& fieldIds)
     107             : {
     108           0 :   itsFieldIds = fieldIds;
     109           0 : }
     110             : 
     111             : 
     112             : // Set the channels to use in the fit
     113           0 : void MSContinuumSubtractor::setFitSpw(const String& fitspw)
     114             : {
     115             :   // NB: this method assumes spwids == ddids!
     116             : 
     117             :   // Using MSSelection  
     118           0 :   MSSelection mssel;
     119           0 :   mssel.setSpwExpr(fitspw);
     120           0 :   Vector<Int> spwlist;
     121           0 :   spwlist=mssel.getSpwList(ms_p);
     122             : 
     123           0 :   if (spwlist.nelements()==0) {
     124           0 :     spwlist.resize(nSpw_);
     125           0 :     indgen(spwlist);
     126             :   }
     127             : 
     128           0 :   setDataDescriptionIds(spwlist);
     129             : 
     130           0 :   itsFitChans= mssel.getChanList(ms_p);
     131             : 
     132           0 : }
     133             : 
     134             : // Set the channels from which the fit should be subtracted
     135           0 : void MSContinuumSubtractor::setSubSpw(const String& subspw)
     136             : {
     137             :   // Using MSSelection  
     138           0 :   MSSelection mssel;
     139           0 :   mssel.setSpwExpr(subspw);
     140           0 :   itsSubChans= mssel.getChanList(ms_p);
     141             : 
     142           0 : }
     143             : 
     144           0 : void MSContinuumSubtractor::setDataDescriptionIds(const Vector<Int>& ddIds)
     145             : {
     146           0 :   itsDDIds = ddIds;
     147           0 : }
     148             : 
     149             : // Set the solution interval in seconds, the value zero implies scan averaging
     150           0 : void MSContinuumSubtractor::setSolutionInterval(Float solInt)
     151             : {
     152           0 :   itsSolInt = solInt;
     153           0 : }
     154             : 
     155             : // Set the solution interval in seconds, the value zero implies scan averaging
     156           0 : void MSContinuumSubtractor::setSolutionInterval(String solInt)
     157             : {
     158             : 
     159           0 :   LogIO os(LogOrigin("MSContinuumSubtractor","setSolutionInterval"));
     160             : 
     161           0 :   os << LogIO::NORMAL << "Fitting continuum on ";
     162             : 
     163           0 :   if (upcase(solInt).contains("INF")) {
     164             :     // ~Infinite (this actually means per-scan in UV contsub)
     165           0 :     solInt="inf";
     166           0 :     itsSolInt=0.0;  
     167           0 :     os <<"per-scan ";
     168             :   }
     169           0 :   else if (upcase(solInt).contains("INT")) {
     170             :     // Per integration
     171           0 :     itsSolInt=-1.0;
     172           0 :     os << "per-integration ";
     173             :   }
     174             :   else {
     175             :     // User-selected timescale
     176           0 :     QuantumHolder qhsolint;
     177           0 :     String error;
     178           0 :     Quantity qsolint;
     179           0 :     qhsolint.fromString(error,solInt);
     180           0 :     if (error.length()!=0)
     181           0 :       throw(AipsError("Unrecognized units for solint."));
     182             : 
     183           0 :     qsolint=qhsolint.asQuantumDouble();
     184             : 
     185           0 :     if (qsolint.isConform("s"))
     186           0 :       itsSolInt=qsolint.get("s").getValue();
     187             :     else {
     188             :       // assume seconds
     189           0 :       itsSolInt=qsolint.getValue();
     190             :     }
     191             : 
     192           0 :     os << itsSolInt <<"-second (per scan) ";
     193           0 :   }
     194             : 
     195           0 :   os << "timescale." << LogIO::POST;
     196             :     
     197           0 : }
     198             : 
     199             : 
     200             : 
     201             : // Set the order of the fit (1=linear)
     202           0 : void MSContinuumSubtractor::setOrder(Int order)
     203             : {
     204           0 :   itsOrder = order;
     205           0 : }
     206             : 
     207             : // Set the processing mode: subtract, model or replace
     208           0 : void MSContinuumSubtractor::setMode(const String& mode)
     209             : {
     210           0 :   itsMode = mode;
     211           0 : }
     212             : 
     213             : // Do the subtraction (or save the model)
     214           0 : void MSContinuumSubtractor::subtract()
     215             : {
     216             :   
     217           0 :   LogIO os(LogOrigin("MSContinuumSubtractor","subtract"));
     218             :   os << LogIO::NORMAL<< "MSContinuumSubtractor::subtract() - parameters:"
     219             :      << "ddIds="<<itsDDIds<<", fieldIds="<<itsFieldIds
     220             :      << ", order="<<itsOrder
     221           0 :      << ", mode="<<itsMode<<LogIO::POST;
     222             : 
     223           0 :   if (itsFitChans.nelements()>0) {
     224           0 :     os<<"fit channels: " << LogIO::POST;
     225           0 :     for (uInt i=0;i<itsFitChans.nrow();++i)
     226           0 :       os<<" spw="<<itsFitChans.row(i)(0)
     227           0 :         <<": "<<itsFitChans.row(i)(1)<<"~"<<itsFitChans.row(i)(2)
     228           0 :         << LogIO::POST;
     229             :   }
     230             : 
     231           0 :   ostringstream select;
     232           0 :   select <<"select from $1 where ANTENNA1!=ANTENNA2";
     233           0 :   if (itsFieldIds.nelements()>0) {
     234           0 :     select<<" && FIELD_ID IN ["<<itsFieldIds(0);
     235           0 :     for (uInt j=1; j<itsFieldIds.nelements(); j++) select<<", "<<itsFieldIds(j);
     236           0 :     select<<"]";
     237             :   }
     238           0 :   if (itsDDIds.nelements()>0) {
     239           0 :     select<<" && DATA_DESC_ID IN ["<<itsDDIds(0);
     240           0 :     for (uInt j=1; j<itsDDIds.nelements(); j++) select<<", "<<itsDDIds(j);
     241           0 :     select<<"]";
     242             :   }
     243             :   //os <<"Selection string: "<<select.str()<<LogIO::POST;
     244             :   //os <<" nrow="<<ms_p->nrow()<<LogIO::POST;
     245           0 :   MeasurementSet selectedMS(tableCommand(select,*ms_p).table());
     246           0 :   MSSelector msSel(selectedMS);
     247             :   //os <<" nrow="<<msSel.nrow()<<LogIO::POST;
     248           0 :   MSColumns msc(selectedMS);
     249           0 :   if (itsDDIds.nelements()>1) {
     250           0 :     cout<<"Processing "<<itsDDIds.nelements()<<" spectral windows"<<endl;
     251             :   }
     252           0 :   for (uInt iDD=0; iDD<itsDDIds.nelements(); iDD++) {
     253           0 :     Vector<Int> ddIDs(1,itsDDIds(iDD));
     254           0 :     msSel.initSelection(ddIDs);
     255             :     //os <<" nrow="<<msSel.nrow()<<LogIO::POST;
     256           0 :     if (msSel.nrow()==0) continue;
     257           0 :     Int nChan=msc.spectralWindow()
     258           0 :                   .numChan()(msc.dataDescription().spectralWindowId()(ddIDs(0)));
     259           0 :     Vector<Int> corrTypes=msc.polarization().
     260           0 :           corrType()(msc.dataDescription().polarizationId()(ddIDs(0)));
     261             : 
     262             : 
     263             :     // default to fit all channels
     264           0 :     Vector<Bool> fitChanMask(nChan,True);
     265             : 
     266             :     // Handle non-trivial channel selection:
     267             : 
     268           0 :     if (itsFitChans.nelements()>0 && anyEQ(itsFitChans.column(0),itsDDIds(iDD))) {
     269             :       // If subset of channels selected, set mask all False...
     270           0 :       fitChanMask=False;
     271             :       
     272           0 :       IPosition blc(1,0);
     273           0 :       IPosition trc(1,0);
     274             : 
     275             :       // ... and set only selected channels True:
     276           0 :       for (uInt i=0;i<itsFitChans.nrow();++i) {
     277           0 :         Vector<Int> chansel(itsFitChans.row(i));
     278             : 
     279             :         // match current spwId/DDid
     280           0 :         if (chansel(0)==itsDDIds(iDD)) {
     281           0 :           blc(0)=chansel(1);
     282           0 :           trc(0)=chansel(2);
     283           0 :           fitChanMask(blc,trc)=True;
     284             :         }
     285           0 :       }
     286           0 :     }
     287             : 
     288             :     //  cout << "fitChanMask = " << fitChanMask << endl;
     289             : 
     290             :     // default to subtract from all channels
     291           0 :     Vector<Bool> subChanMask(nChan,True);
     292           0 :     if (itsSubChans.nelements()>0 && anyEQ(itsSubChans.column(0),itsDDIds(iDD))) {
     293             :       // If subset of channels selected, set sub mask all False...
     294           0 :       subChanMask=False;
     295             :       
     296           0 :       IPosition blc(1,0);
     297           0 :       IPosition trc(1,0);
     298             : 
     299             :       // ... and set only selected sub channels True:
     300           0 :       for (uInt i=0;i<itsSubChans.nrow();++i) {
     301           0 :         Vector<Int> chansel(itsSubChans.row(i));
     302             : 
     303             :         // match current spwId/DDid
     304           0 :         if (chansel(0)==itsDDIds(iDD)) {
     305           0 :           blc(0)=chansel(1);
     306           0 :           trc(0)=chansel(2);
     307           0 :           subChanMask(blc,trc)=True;
     308             :         }
     309           0 :       }
     310           0 :     }
     311             : 
     312             :     // select parallel hand polarizations
     313           0 :     Vector<String> polSel(corrTypes.nelements()); 
     314           0 :     Int nPol = 0;
     315           0 :     for (uInt j=0; j<corrTypes.nelements(); j++) {
     316           0 :       if (corrTypes(j)==Stokes::XX||corrTypes(j)==Stokes::YY||
     317           0 :           corrTypes(j)==Stokes::RR||corrTypes(j)==Stokes::LL) {
     318           0 :         polSel(nPol++)=Stokes::name(Stokes::type(corrTypes(j)));
     319             :       }
     320             :     }
     321           0 :     polSel.resize(nPol,True);
     322           0 :     msSel.selectPolarization(polSel);
     323             : 
     324           0 :     msSel.iterInit(
     325           0 :         stringToVector("ARRAY_ID,DATA_DESC_ID,SCAN_NUMBER,FIELD_ID,TIME"),
     326           0 :         itsSolInt,0,False);
     327           0 :     msSel.iterOrigin();
     328           0 :     Int nIter=1;
     329           0 :     while (msSel.iterNext()) nIter++;
     330           0 :     os<<"Processing "<<nIter<<" slots."<< LogIO::POST;
     331           0 :     msSel.iterOrigin();
     332             :     do {
     333           0 :       Record avRec = msSel.getData(stringToVector("corrected_data"),True,0,1,True);
     334           0 :       Record dataRec = msSel.getData(stringToVector("model_data,corrected_data"),
     335           0 :                                      True,0,1);
     336           0 :       Array<Complex> avCorData(avRec.asArrayComplex("corrected_data"));
     337           0 :       Array<Complex> modelData(dataRec.asArrayComplex("model_data"));
     338           0 :       Array<Complex> correctedData(dataRec.asArrayComplex("corrected_data"));
     339           0 :       Int nTime=modelData.shape()[3];
     340           0 :       Int nIfr=modelData.shape()[2];
     341             : 
     342             :       // fit
     343           0 :       Vector<Float> x(nChan);
     344           0 :       for (Int i=0; i<nChan; i++) x(i)=i;
     345           0 :       LinearFit<Float> fitter;
     346           0 :       Polynomial<AutoDiff<Float> > apoly(itsOrder);
     347           0 :       fitter.setFunction(apoly);
     348           0 :       Polynomial<Float> poly(itsOrder);
     349             :       
     350           0 :       Vector<Float> y1(nChan),y2(nChan);
     351           0 :       Vector<Float> sol(itsOrder+1);
     352           0 :       Vector<Complex> tmp(nChan);
     353           0 :       IPosition start(3,0,0,0),end(3,0,nChan-1,0);
     354           0 :       for (; start[2]<nIfr; start[2]++,end[2]++) {
     355           0 :         for (start[0]=end[0]=0; start[0]<nPol; start[0]++,end[0]++) {
     356           0 :           Vector<Complex> c(avCorData(start,end).nonDegenerate());
     357           0 :           tmp=c; // copy into contiguous storage
     358           0 :           c.set(Complex(0.0));  // zero the input
     359           0 :           real(y1,tmp);
     360           0 :           imag(y2,tmp);
     361           0 :           sol = fitter.fit(x,y1,&fitChanMask);
     362           0 :           poly.setCoefficients(sol);
     363           0 :           y1=x;
     364           0 :           y1.apply(poly);
     365           0 :           sol = fitter.fit(x,y2,&fitChanMask);
     366           0 :           poly.setCoefficients(sol);
     367           0 :           y2=x;
     368           0 :           y2.apply(poly);
     369           0 :           for (Int chn=0; chn<nChan; chn++) 
     370           0 :             if (subChanMask(chn))
     371           0 :               c(chn)=Complex(y1(chn),y2(chn));
     372           0 :         }
     373             :       }
     374             :         
     375           0 :       IPosition start4(4,0,0,0,0),end4(4,nPol-1,nChan-1,nIfr-1,0);
     376           0 :       for (Int iTime=0; iTime<nTime; iTime++,start4[3]++,end4[3]++) {
     377           0 :         if  (itsMode!="replace") {
     378           0 :           Array<Complex> model(modelData(start4,end4).nonDegenerate(3));
     379           0 :           model=avCorData;
     380           0 :         }
     381           0 :         if (itsMode!="model") {
     382           0 :           Array<Complex> corr(correctedData(start4,end4).nonDegenerate(3));
     383           0 :           if (itsMode=="replace") corr=avCorData;
     384           0 :           if (itsMode=="subtract" || itsMode=="sub") corr-=avCorData;
     385           0 :         }
     386             :       }  
     387             :                     
     388           0 :       Record newDataRec;
     389           0 :       if (itsMode=="model"||itsMode=="subtract"||itsMode=="sub") {
     390           0 :         newDataRec.define("model_data",modelData);
     391             :       }
     392           0 :       if (itsMode=="replace"||itsMode=="subtract"||itsMode=="sub") {
     393           0 :         newDataRec.define("corrected_data",correctedData);
     394             :       }
     395           0 :       msSel.putData(newDataRec);
     396             :       
     397           0 :     } while (msSel.iterNext());
     398             :     
     399           0 :   }
     400           0 : }
     401             : 
     402             : // Do the subtraction (or save the model)
     403           0 : void MSContinuumSubtractor::subtract2()
     404             : {
     405             :   // Log selections for subtraction
     406           0 :   LogIO os(LogOrigin("MSContinuumSubtractor","subtract2"));
     407             :   os << LogIO::NORMAL << "parameters:" 
     408           0 :      << LogIO::POST;
     409             :   os << LogIO::NORMAL << "   ddIds=" << itsDDIds
     410             :      << ", fieldIds="<< itsFieldIds
     411             :      << ", order="<< itsOrder
     412           0 :      << ", mode="<< itsMode 
     413           0 :      << LogIO::POST;
     414           0 :   if (itsFitChans.nelements()>0) {
     415           0 :     os << "fit channels: " << LogIO::POST;
     416           0 :     for (uInt i=0; i<itsFitChans.nrow(); ++i)
     417           0 :       os << " spw=" << itsFitChans.row(i)(0)
     418           0 :              << ": " << itsFitChans.row(i)(1) << "~" << itsFitChans.row(i)(2)
     419           0 :              << LogIO::POST;
     420             :   }
     421             : 
     422             :   // Use taQL for selection (no DDiD sel in MSSelection)
     423           0 :   ostringstream select;
     424           0 :   select << "select from $1 where ANTENNA1!=ANTENNA2";
     425           0 :   if (itsFieldIds.nelements() > 0) {
     426           0 :     select << " && FIELD_ID IN [" << itsFieldIds(0);
     427           0 :     for (uInt j=1; j<itsFieldIds.nelements(); j++) 
     428           0 :         select << ", " << itsFieldIds(j);
     429           0 :     select << "]";
     430             :   }
     431           0 :   if (itsDDIds.nelements() > 0) {
     432           0 :     select << " && DATA_DESC_ID IN [" << itsDDIds(0);
     433           0 :     for (uInt j=1; j<itsDDIds.nelements(); j++)
     434           0 :         select << ", " << itsDDIds(j);
     435           0 :     select << "]";
     436             :   }
     437           0 :   MeasurementSet selectedMS(tableCommand(select, *ms_p).table());
     438           0 :   MSColumns msc(selectedMS);
     439           0 :   MSSelection mssel;  // for channel and poln selection
     440             : 
     441           0 :   for (uInt iDD=0; iDD<itsDDIds.nelements(); iDD++) {
     442           0 :     Int thisDDId(itsDDIds(iDD));
     443           0 :     Int nChan = msc.spectralWindow().numChan()
     444           0 :         (msc.dataDescription().spectralWindowId()(thisDDId));
     445           0 :     Vector<Int> corrTypes = msc.polarization().corrType()
     446           0 :         (msc.dataDescription().polarizationId()(thisDDId));
     447             : 
     448             :     // default to fit all channels
     449           0 :     Vector<Bool> fitChanMask(nChan,True);
     450             :     // Handle non-trivial channel selection:
     451           0 :     if (itsFitChans.nelements()>0 && anyEQ(itsFitChans.column(0),thisDDId)) {
     452             :       // If subset of channels selected, set fit mask all False...
     453           0 :       fitChanMask = False;
     454           0 :       IPosition blc(1,0);
     455           0 :       IPosition trc(1,0);
     456             :       // ... and set only selected fit channels True:
     457           0 :       for (uInt i=0; i<itsFitChans.nrow(); ++i) {
     458           0 :             Vector<Int> chansel(itsFitChans.row(i));  // [spw, startChan, endChan]
     459             :             // match current spwId/DDid
     460           0 :             if (chansel(0) == thisDDId) {
     461           0 :                 blc(0) = chansel(1);
     462           0 :                 trc(0) = chansel(2);
     463           0 :                 fitChanMask(blc,trc) = True;
     464             :             }
     465           0 :       }
     466           0 :     }
     467             : 
     468             :     // default to subtract from all channels
     469           0 :     Vector<Bool> subChanMask(nChan,True);
     470             :     // Handle non-trivial channel selection:
     471           0 :     if (itsSubChans.nelements()>0 && anyEQ(itsSubChans.column(0),thisDDId)) {
     472             :       // If subset of channels selected, set sub mask all False...
     473           0 :       subChanMask = False;
     474           0 :       IPosition blc(1,0);
     475           0 :       IPosition trc(1,0);
     476             :       // ... and set only selected sub channels True:
     477           0 :       for (uInt i=0; i<itsSubChans.nrow(); ++i) {
     478           0 :             Vector<Int> chansel(itsSubChans.row(i));
     479             :             // match current spwId/DDid
     480           0 :             if (chansel(0) == thisDDId) {
     481           0 :                 blc(0) = chansel(1);
     482           0 :                 trc(0) = chansel(2);
     483           0 :                 subChanMask(blc,trc) = True;
     484             :             }
     485           0 :       }
     486           0 :     }
     487             : 
     488             :     // select parallel hand polarizations with MSSelection
     489           0 :     Vector<String> polSel(corrTypes.nelements()); 
     490           0 :     Int nPol = 0;
     491           0 :     for (uInt j=0; j<corrTypes.nelements(); j++) {
     492           0 :       if (corrTypes(j)==Stokes::XX || corrTypes(j)==Stokes::YY ||
     493           0 :           corrTypes(j)==Stokes::RR || corrTypes(j)==Stokes::LL) {
     494           0 :         polSel(nPol++) = Stokes::name(Stokes::type(corrTypes(j)));
     495             :       }
     496             :     }
     497           0 :     polSel.resize(nPol,True);
     498           0 :     String polnExpr("");
     499           0 :     if (nPol > 0) {
     500           0 :         polnExpr = polSel[0];
     501           0 :         for (Int np=1; np<nPol; ++np) {
     502           0 :             polnExpr += "," + polSel[np];
     503             :         }
     504             :     }
     505             :     // apply selection to get correlation slices
     506           0 :     String spwExpr = String::toString(thisDDId);
     507           0 :     MeasurementSet spwSelMS(selectedMS);
     508           0 :     Vector<Vector<Slice> > chansel;
     509           0 :     Vector<Vector<Slice> > corrsel;
     510           0 :     mssel.clear();
     511           0 :     mssSetData(selectedMS, spwSelMS, chansel, corrsel,
     512             :                "", "", "", "", spwExpr, "", "",
     513             :                polnExpr, "", "", "", "", 1, &mssel);
     514             : 
     515           0 :     casacore::Float chunkInt(itsSolInt);
     516           0 :     if (chunkInt < 0.0) {
     517           0 :         MSMainColumns msmain(spwSelMS);
     518           0 :         chunkInt = msmain.interval().getColumn()(0);
     519           0 :     }
     520             : 
     521             :     // Set up FrequencySelection with chansel and corrsel for VisibilityIterator2
     522           0 :     vi::FrequencySelectionUsingChannels freqSel = vi::FrequencySelectionUsingChannels();
     523           0 :     freqSel.add(mssel, &spwSelMS);
     524           0 :     freqSel.addCorrelationSlices(corrsel);
     525             : 
     526             :     // Sort Columns
     527           0 :     Block<Int> columns(5);
     528           0 :     Int i(0);
     529           0 :     columns[i++] = MS::ARRAY_ID;
     530           0 :     columns[i++] = MS::DATA_DESC_ID;
     531           0 :     columns[i++] = MS::SCAN_NUMBER;
     532           0 :     columns[i++] = MS::FIELD_ID;
     533           0 :     columns[i++] = MS::TIME;
     534           0 :     vi::SortColumns sortcols(columns, false);
     535             :       
     536             :     // Set up averaged non-calibrating vi
     537           0 :     vi::IteratingParameters iterpar(chunkInt, sortcols);
     538             :     vi::AveragingOptions avgopt(vi::AveragingOptions::AverageCorrected |
     539           0 :             vi::AveragingOptions::CorrectedWeightAvgFromWEIGHT);
     540           0 :     vi::AveragingParameters avgpar(1e8, 0.0, sortcols, avgopt);
     541           0 :     vi::LayeredVi2Factory factory(&spwSelMS, &iterpar, &avgpar);
     542           0 :     vi::VisibilityIterator2* vi2 = new vi::VisibilityIterator2(factory);
     543           0 :     vi2->setFrequencySelection(freqSel);
     544           0 :     vi::VisBuffer2* vb2 = vi2->getVisBuffer();
     545           0 :     vi2->originChunks();
     546           0 :     vi2->origin();
     547             : 
     548             :     // Get continuum model
     549             :     // fit
     550           0 :     Vector<Float> x(nChan);
     551           0 :     for (Int i=0; i<nChan; i++) x(i)=i;
     552           0 :     LinearFit<Float> fitter;
     553           0 :     Polynomial<AutoDiff<Float> > apoly(itsOrder);
     554           0 :     fitter.setFunction(apoly);
     555           0 :     Polynomial<Float> poly(itsOrder);
     556           0 :     Vector<Float> y1(nChan),y2(nChan);
     557           0 :     Vector<Float> sol(itsOrder+1);
     558           0 :     Vector<Complex> tmp(nChan);
     559           0 :     Cube<Complex> avgCorrData;
     560             :     // map is <scan, fit model>
     561           0 :     map<Int, Cube<Complex>> fitCorrData;
     562           0 :     map<Int, Vector<Int>> fitCorrIfr;
     563           0 :     Int nIter(0);
     564           0 :     IPosition start(3,0,0,0), end(3,0,nChan-1,0);
     565           0 :     for (vi2->originChunks(); vi2->moreChunks(); vi2->nextChunk()){
     566           0 :         for (vi2->origin(); vi2->more(); vi2->next()){
     567           0 :             avgCorrData.resize();
     568           0 :             avgCorrData = vb2->visCubeCorrected();
     569           0 :             for (start[2]=end[2]=0; start[2]<avgCorrData.shape()[2];
     570           0 :                     start[2]++,end[2]++) {
     571           0 :                 for (start[0]=end[0]=0; start[0]<nPol; start[0]++,end[0]++) {
     572           0 :                     Vector<Complex> c(avgCorrData(start,end).nonDegenerate());
     573           0 :                     tmp=c; // copy into contiguous storage
     574           0 :                     c.set(Complex(0.0));  // zero the input
     575           0 :                     real(y1,tmp);
     576           0 :                     imag(y2,tmp);
     577           0 :                     sol = fitter.fit(x,y1,&fitChanMask);
     578           0 :                     poly.setCoefficients(sol);
     579           0 :                     y1=x;
     580           0 :                     y1.apply(poly);
     581           0 :                     sol = fitter.fit(x,y2,&fitChanMask);
     582           0 :                     poly.setCoefficients(sol);
     583           0 :                     y2=x;
     584           0 :                     y2.apply(poly);
     585           0 :                     for (Int chn=0; chn<nChan; chn++) {
     586           0 :                         if (subChanMask(chn))
     587           0 :                             c(chn)=Complex(y1(chn),y2(chn));
     588             :                     }
     589           0 :                 }
     590             :             }
     591           0 :             fitCorrData[nIter] = avgCorrData;
     592           0 :             Vector<Int> ant1 = vb2->antenna1();
     593           0 :             Vector<Int> ant2 = vb2->antenna2();
     594           0 :             fitCorrIfr[nIter] = ant1*1000 + ant2;
     595           0 :             nIter++;
     596           0 :         }
     597             :     }
     598           0 :     os << "Processing " << nIter << " slots for ddId " << iDD << LogIO::POST;
     599           0 :     delete vi2;
     600             : 
     601             :     // unaveraged non-calibrating vi
     602           0 :     vi::LayeredVi2Factory factory2(&spwSelMS, &iterpar);
     603           0 :     vi2 = new vi::VisibilityIterator2(factory2);
     604           0 :     vi2->setFrequencySelection(freqSel);
     605           0 :     vb2 = vi2->getVisBuffer();
     606           0 :     vi2->originChunks();
     607           0 :     vi2->origin();
     608           0 :     Cube<Complex> modelData, correctedData, fitModel;
     609           0 :     nIter=0;
     610           0 :     for (vi2->originChunks(); vi2->moreChunks(); vi2->nextChunk()){
     611           0 :         for (vi2->origin(); vi2->more(); vi2->next()){
     612             :             // get model and corrected data with poln selection applied
     613           0 :             modelData.resize();
     614           0 :             modelData = vb2->visCubeModel();
     615           0 :             correctedData.resize();
     616           0 :             correctedData = vb2->visCubeCorrected();
     617           0 :             IPosition datashape = correctedData.shape();
     618           0 :             fitModel.resize();
     619           0 :             fitModel = fitCorrData[nIter];
     620             : 
     621             :             // Unaveraged data may have different shape
     622           0 :             if (fitModel.shape() != datashape) {
     623             :                 // only use baselines in this chunk
     624           0 :                 Cube<Complex> newFitModel(datashape);
     625           0 :                 Vector<Int> ant1 = vb2->antenna1();
     626           0 :                 Vector<Int> ant2 = vb2->antenna2();
     627           0 :                 Vector<Int> ifrs = ant1*1000 + ant2;
     628           0 :                 Vector<Int> fitIfr = fitCorrIfr[nIter];
     629           0 :                 IPosition start(3,0,0,0), start2(3,0,0,0);
     630           0 :                 Int nPol(datashape[0]), nChan(datashape[1]), nIfr(datashape[2]);
     631           0 :                 IPosition end(3, nPol-1, nChan-1, nIfr-1);
     632           0 :                 IPosition end2(3, nPol-1, nChan-1, nIfr-1);
     633           0 :                 for (uInt i=0; i<ifrs.size(); ++i) {
     634           0 :                     start[2] = end[2] = i;
     635           0 :                     Int ifr = ifrs[i];
     636             :                     // now find ifr in fitIfr
     637           0 :                     for (uInt j=0; j<fitIfr.size(); ++j) {
     638           0 :                         if (fitIfr[j]==ifr) {
     639           0 :                             start2[2] = end2[2] = j;
     640           0 :                             newFitModel(start,end) = fitModel(start2,end2);
     641           0 :                             break;
     642             :                         }
     643             :                     }
     644             :                 }
     645           0 :                 fitModel.resize(datashape);
     646           0 :                 fitModel = newFitModel;
     647           0 :             }
     648             : 
     649             :             // write out cubes to MS
     650           0 :             if (itsMode=="subtract" || itsMode=="model" || itsMode=="sub") {
     651           0 :                 modelData = fitModel;
     652           0 :                 vi2->getImpl()->writeVisModel(modelData);
     653             :             }
     654           0 :             if (itsMode=="replace") {
     655           0 :                 correctedData = fitModel;
     656           0 :                 vi2->getImpl()->writeVisCorrected(correctedData);
     657             :             }
     658           0 :             if (itsMode=="subtract" || itsMode=="sub") {
     659           0 :                 correctedData -= fitModel;
     660           0 :                 vi2->getImpl()->writeVisCorrected(correctedData);
     661             :             }
     662           0 :         }
     663           0 :         nIter++;
     664             :     }
     665           0 :     delete vi2;
     666           0 :   } // end DDId loop
     667           0 : }
     668             : 
     669             : 
     670             : } //# NAMESPACE CASA - END
     671             : 

Generated by: LCOV version 1.16