LCOV - code coverage report
Current view: top level - alma/ASDMBinaries - BaselinesSet.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 215 0.0 %
Date: 2024-10-28 15:53:10 Functions: 0 20 0.0 %

          Line data    Source code
       1             : #include <vector>
       2             : #include <iostream>
       3             : 
       4             : #include <alma/ASDMBinaries/Error.h>
       5             : #include <alma/ASDMBinaries/BaselinesSet.h>
       6             : 
       7             : using namespace asdm;
       8             : using namespace sdmbin;
       9             : using namespace std;
      10             : 
      11             : using namespace AxisNameMod;
      12             : using namespace BasebandNameMod;
      13             : using namespace CorrelationModeMod;
      14             : using namespace DataContentMod;
      15             : 
      16             : // constructors
      17           0 : BaselinesSet::BaselinesSet(){
      18           0 :   bool coutest=false;
      19           0 :   if(coutest)cout<<"Constructor vide BaselinesSet" <<endl; 
      20           0 : }
      21             : 
      22           0 : BaselinesSet::BaselinesSet( vector<Tag>               v_antennaIdArray, 
      23             :                             vector<int>               v_feedIdArray,
      24             :                             vector<int>               v_phasedArrayList,
      25             :                             vector<bool>              v_antennaUsedArray,
      26             :                             DataDescriptionsSet       &dataDescriptionsSet
      27           0 :                            ):
      28             :   DataDescriptionsSet(dataDescriptionsSet),
      29           0 :   v_AntennaIdArray_(v_antennaIdArray),
      30           0 :   v_FeedIdArray_(v_feedIdArray),
      31           0 :   v_PhasedArrayList_(v_phasedArrayList)
      32             : {
      33           0 :   bool coutest=false;
      34           0 :   if(coutest)cout << "Constructor BaselinesSet" << endl;
      35           0 :   if(coutest)cout << "v_AntennaIdArray_.size=" << v_AntennaIdArray_.size() << endl;
      36           0 :       numAntennas_ = v_antennaIdArray.size();              if(coutest)cout << "numAntennas_=" << numAntennas_ << endl;
      37           0 :       numFeeds_    = v_feedIdArray.size()/numAntennas_;    if(coutest)cout << "numFeeds_=   " << numFeeds_    << endl;
      38             : 
      39             : 
      40           0 :   for(unsigned int na=0; na<numAntennas_; na++)
      41           0 :     if(v_antennaUsedArray[na])
      42           0 :       v_effAntennaIdArray_.push_back(v_antennaIdArray[na]);
      43           0 :   numEffAntennas_ = v_effAntennaIdArray_.size();
      44             : 
      45           0 :   if(coutest)cout << "numEffAntennas_=" << numEffAntennas_ << endl;
      46           0 :   numBaselines_     = (numAntennas_*(numAntennas_-1))/2;          // number of cross-correlation baselines
      47           0 :   if(coutest)cout << "numBaselines_=" << numBaselines_ << endl;
      48           0 :   numEffBaselines_  = (numEffAntennas_*(numEffAntennas_-1))/2;    // number of effective cross-correlation baselines
      49           0 :   if(coutest)cout << "numEffBaselines_=" << numEffBaselines_ << endl;
      50           0 : }
      51             : 
      52           0 : BaselinesSet::BaselinesSet(const BaselinesSet & a) : DataDescriptionsSet(a) {
      53           0 :   cout << "Copy constructor BaselinesSet" << endl;
      54             : 
      55             :   // attributes inherited from the class SwitchCyclesList:
      56           0 :   m_bn_v_scId_              = a.m_bn_v_scId_;
      57           0 :   m_bn_v_numBin_            = a.m_bn_v_numBin_;
      58           0 :   vv_numBin_                = a.vv_numBin_;
      59           0 :   v_numBin_                 = a.v_numBin_;
      60           0 :   datasetPtr_               = a.datasetPtr_;
      61           0 :   vv_switchCycleId_         = a.vv_switchCycleId_;
      62           0 :   v_switchCycleId_          = a.v_switchCycleId_;
      63             : 
      64             :   // attributes inherited from the class DataDescriptionsSet:
      65           0 :   v_numPol_                 = a.v_numPol_;
      66           0 :   v_spwId_                  = a.v_spwId_;
      67           0 :   v_numChan_                = a.v_numChan_;
      68           0 :   v_basebandName_           = a.v_basebandName_;
      69           0 :   vv_nsp_                   = a.vv_nsp_;
      70             : 
      71           0 :   m_bn_v_ddp_               = a.m_bn_v_ddp_;
      72           0 :   m_ddid_bbn_               = a.m_ddid_bbn_;
      73             :   //cout << "1" << endl;
      74           0 :   numApc_                   = a.numApc_;
      75           0 :   numDataDescription_       = a.numDataDescription_;
      76           0 :   e_cm_                     = a.e_cm_;
      77           0 :   correlationMode_          = a.correlationMode_;
      78           0 :   es_apc_                   = a.es_apc_;
      79           0 :   v_atmPhaseCorrection_     = a.v_atmPhaseCorrection_;
      80             :   //cout << "2" << endl;
      81           0 :   sumMetaDataIndex_         = a.sumMetaDataIndex_;
      82           0 :   sumAutoSize_              = a.sumAutoSize_;
      83           0 :   sumCrossSize_             = a.sumCrossSize_;
      84             :   //cout << "3" << endl;
      85           0 :   v_metaDataIndex_          = a.v_metaDataIndex_;
      86           0 :   v_cumulAutoSize_          = a.v_cumulAutoSize_; 
      87           0 :   v_cumulCrossSize_         = a.v_cumulCrossSize_;
      88           0 :   v_numAutoData_            = a.v_numAutoData_;
      89           0 :   v_numCrossData_           = a.v_numCrossData_;
      90           0 :   v_autoSize_               = a.v_autoSize_;
      91           0 :   v_crossSize_              = a.v_crossSize_;
      92             :   //cout << "4" << endl;
      93           0 :   v_dataDescriptionIdArray_ = a.v_dataDescriptionIdArray_;
      94           0 :   v_crossDataDescriptionId_ = a.v_crossDataDescriptionId_;
      95           0 :   v_autoDataDescriptionId_  = a.v_autoDataDescriptionId_;
      96           0 :   v_basebandSet_            = a.v_basebandSet_;
      97           0 :   v_numSpwPerBb_            = a.v_numSpwPerBb_;
      98             : 
      99             :   // attribute in the present BaselinesSet class:
     100           0 :   v_AntennaIdArray_         = a.v_AntennaIdArray_;
     101           0 :   v_FeedIdArray_            = a.v_FeedIdArray_;
     102           0 :   v_PhasedArrayList_        = a.v_PhasedArrayList_;
     103           0 :   numAntennas_              = a.numAntennas_;
     104           0 :   numFeeds_                 = a.numFeeds_;
     105           0 :   numEffAntennas_           = a.numEffAntennas_;
     106           0 :   numBaselines_             = a.numBaselines_;
     107           0 :   numEffBaselines_          = a.numEffBaselines_;
     108           0 :   v_effAntennaIdArray_      = a.v_effAntennaIdArray_;
     109           0 : }
     110             : 
     111           0 : BaselinesSet::~BaselinesSet(){}
     112             : 
     113           0 : unsigned int BaselinesSet::getNumAntennas(){ return numAntennas_; }
     114             : 
     115           0 : unsigned int BaselinesSet::getNumEffAntennas(){ return numEffAntennas_; }
     116             : 
     117           0 : Tag BaselinesSet::getEffAntennaId(unsigned int na) {
     118           0 :   if(na>=v_effAntennaIdArray_.size())
     119           0 :     Error(SERIOUS,
     120             :           (char *) "The antenna index, %d, exceeds the maximum limit of %d",
     121           0 :           na,v_effAntennaIdArray_.size()-1); 
     122           0 :   return v_effAntennaIdArray_[na];
     123             : }
     124             : 
     125           0 : int BaselinesSet::getFeedId(unsigned int na, unsigned int nfe) {
     126           0 :   if(na>=v_effAntennaIdArray_.size())
     127           0 :     Error(SERIOUS,
     128             :           (char *) "The antenna index, %d, exceeds the maximum limit of %d",
     129           0 :           na,v_effAntennaIdArray_.size()-1);
     130           0 :   if(nfe>=numFeeds_)
     131           0 :     Error(SERIOUS,
     132             :           (char *) "The feed index, %d, exceeds the maximum limit of %d deriving from the number of feeds in the configuration",
     133           0 :           nfe,numFeeds_-1); 
     134           0 :   return v_FeedIdArray_[na*numFeeds_+nfe];
     135             : }
     136             : 
     137           0 : unsigned int BaselinesSet::getNumBaselines(){ return numBaselines_; }
     138             : 
     139           0 : unsigned int BaselinesSet::getNumEffBaselines(){ return numEffBaselines_; }
     140             : 
     141           0 : unsigned int BaselinesSet::baselineIndex( Tag antennaId1, Tag antennaId2) {
     142             : //   int iNum = 0;          // iNum will be the (1 based) antennaNum in the list for antennaId1 
     143             : //   int jNum = 0;          // jNum will be the (1 based) antennaNum in the list for antennaId2 
     144             : //   for(int n=0; n<numEffAntennas_; n++)if(v_effAntennaIdArray_[n]==antennaId1)iNum=n+1; if(iNum==0)return 0;
     145             : //   for(int n=0; n<numEffAntennas_; n++)if(v_effAntennaIdArray_[n]==antennaId2)jNum=n+1; if(jNum==0)return 0;
     146             : 
     147           0 :   unsigned int m = 0;
     148           0 :   unsigned int iIdx=baselineIndex(antennaId1);
     149           0 :   unsigned int jIdx=baselineIndex(antennaId2);
     150           0 :   if(iIdx>jIdx){
     151           0 :     m=jIdx; jIdx=iIdx; iIdx=m;
     152             :   }
     153           0 :   m = 0;
     154           0 :   for(unsigned int n=0; n<jIdx; n++)m=m+n;
     155           0 :   return m+iIdx;
     156             : }
     157             : 
     158           0 : unsigned int BaselinesSet::baselineIndex( Tag antennaId ) {
     159           0 :   for(unsigned int n=0; n<numEffAntennas_; n++)
     160           0 :     if(v_effAntennaIdArray_[n]==antennaId)return n;
     161           0 :   Error(FATAL,(char *) "No baseline index for antennaId=%s",antennaId.toString().c_str());
     162           0 :   return 0;
     163             : }
     164             : 
     165             : 
     166             : // unsigned int BaselinesSet::baselineIndex( unsigned int na1, unsigned int na2) {
     167             : 
     168             : //   // if(na1>=v_effAntennaIdArray_.size()){
     169             : //   //   Error(FATAL,"The antenna index, %d, exceeds the limit of %d",
     170             : //   //           na1,v_effAntennaIdArray_.size()-1);
     171             : //   //   return 0;
     172             : //   // }
     173             : //   // if(na2>=v_effAntennaIdArray_.size()){
     174             : //   //   Error(FATAL,"The antenna index, %d, exceeds the limit of %d",
     175             : //   //           na2,v_effAntennaIdArray_.size()-1);
     176             : //   //   return 0;
     177             : //   // }
     178             : 
     179             : //   unsigned int iIdx = min (na1, na2);
     180             : //   unsigned int jIdx = max (na1, na2);
     181             : //   /*
     182             : //   if(na1<na2){
     183             : //     iIdx = na1;
     184             : //     jIdx = na2;
     185             : //   }else{
     186             : //     iIdx = na2;
     187             : //     jIdx = na1;
     188             : //   }
     189             : //   unsigned int m = 0;
     190             : //   for(unsigned int n=0; n<jIdx; n++)m=m+n;
     191             : //   */
     192             : //   return jIdx * (jIdx - 1) / 2 + iIdx;
     193             : // }
     194             : 
     195             : 
     196           0 : unsigned int BaselinesSet::antenna1( unsigned int baselineIdx)  {
     197             :   unsigned int iIdx;
     198             :   unsigned int jIdx;
     199             :   unsigned int m;
     200           0 :   for(unsigned int na1=0; na1<numEffAntennas_; na1++){
     201           0 :     for(unsigned int na2=na1; na2<numEffAntennas_; na2++){
     202           0 :       iIdx = na1;
     203           0 :       jIdx = na2;
     204           0 :       m    = 0;
     205           0 :       for(unsigned int n=0; n<jIdx; n++)m += n;
     206           0 :       if((m+iIdx)==baselineIdx)return na1;
     207             :     }
     208             :   }
     209           0 :   Error(FATAL,(char *) "No antenna1 index for the requested baseline index %d",baselineIdx);
     210           0 :   return 0;
     211             : }
     212             : 
     213           0 : unsigned int BaselinesSet::antenna2( unsigned int baselineIdx)  {
     214             :   unsigned int iIdx;
     215             :   unsigned int jIdx;
     216             :   unsigned int m;
     217           0 :   if(baselineIdx==0)return 0;
     218           0 :   for(unsigned int na1=0; na1<numEffAntennas_; na1++){
     219           0 :     for(unsigned int na2=na1; na2<numEffAntennas_; na2++){
     220           0 :       iIdx = na1;
     221           0 :       jIdx = na2;
     222           0 :       m = 0;
     223           0 :       for(unsigned int n=0; n<jIdx; n++)m += n;
     224           0 :       if((m+iIdx)==baselineIdx)return na2;
     225             :     }
     226             :   }
     227           0 :   Error(FATAL,(char *) "No antenna2 index for the requested baseline index %d",baselineIdx);
     228           0 :   return 0;
     229             : }
     230             : 
     231           0 : unsigned int BaselinesSet::feedIndex(Tag antId, int feedId) {
     232           0 :   int na  = -1;
     233           0 :   for(unsigned int n=0; n<numAntennas_; n++)if(antId==v_AntennaIdArray_[n])na=n;
     234           0 :   if(na<0){
     235           0 :     Error(FATAL,
     236             :           (char *) "Antenna with identifier %s  not in the configuration",
     237           0 :           antId.toString().c_str()); 
     238           0 :     return 0;
     239             :   }
     240           0 :   int nfe = -2;
     241           0 :   for(unsigned int n=0; n<numFeeds_; n++)if(feedId==v_FeedIdArray_[na*numFeeds_+n])nfe=n;
     242           0 :   if(nfe<0){
     243           0 :     Error(FATAL,
     244             :           (char *) "Feed identifier %d for antenna with the identifier %s not in the configuration",
     245           0 :           feedId,antId.toString().c_str()); 
     246           0 :     return nfe;
     247             :   }
     248           0 :   return (unsigned int) nfe;
     249             : }
     250             : 
     251           0 :  unsigned int BaselinesSet::getNumPDTvalue(Enum<DataContent> e_dc, EnumSet<AxisName> es_an, bool effective){
     252             : 
     253           0 :    unsigned int nAntennas =1; if(es_an[ANT])nAntennas = numAntennas_;  if(e_dc[CROSS_DATA])nAntennas =0;
     254           0 :    unsigned int nBaselines=1; if(es_an[BAL])nBaselines= numBaselines_; if(e_dc[AUTO_DATA]) nBaselines=0;
     255             :    // nBaseband is not currently used
     256             :    // unsigned int nBaseband =1; if(es_an[BAB])nBaseband = numBaseband();
     257           0 :    unsigned int nBin      =1;
     258           0 :    unsigned int nApc      =1; if(es_an[APC])nApc      = es_apc_.count();
     259           0 :    unsigned int nSpp      =1;
     260           0 :    unsigned int nPol      =1;
     261             :    unsigned int npv;
     262           0 :    unsigned int nv1=0, nv2=0;
     263             : 
     264             :    // The concept of having in the binary the data only for those actualy producing data has been dropped
     265             :    // Hence, in practice effective should be alway set to false with the consequence that nAntennas and
     266             :    // nBaselines in general will reflect what has been actually scheduled in antenna resource to do the
     267             :    // observations. 
     268           0 :    if(effective && e_dc[FLAGS]==false){
     269           0 :      if(es_an[ANT])nAntennas = numEffAntennas_;; if(e_dc[CROSS_DATA])nAntennas =0;
     270           0 :      if(es_an[BAL])nBaselines= numEffBaselines_; if(e_dc[AUTO_DATA]) nBaselines=0;
     271             :    }
     272             : 
     273             :    map<BasebandName,vector<DataDescParams> >::iterator 
     274           0 :      itbnddp, 
     275           0 :      itbnddpb=m_bn_v_ddp_.begin(), 
     276           0 :      itbnddpe=m_bn_v_ddp_.end();
     277           0 :    for(itbnddp=itbnddpb;itbnddp!=itbnddpe; ++itbnddp){
     278           0 :      for(unsigned int nspw=0; nspw<itbnddp->second.size(); nspw++){
     279           0 :        if(es_an[POL]){
     280           0 :          nPol = itbnddp->second[nspw].numCorr;
     281           0 :          if(e_dc[FLAGS]||e_dc[ZERO_LAGS])if(nPol>2)nPol=2;
     282             :        }
     283           0 :        npv = nPol;
     284           0 :        if(e_dc[AUTO_DATA]){
     285           0 :          if(nPol==3)npv=4;  // XX XY YY    ==> 4 primitive values, 3 real values and 1 imaginary value
     286           0 :          if(nPol==4)npv=6;  // XX XY YX YY ==> 6 primitive values (use-case not expected for ALMA)
     287             :        }
     288           0 :        if(e_dc[CROSS_DATA]){
     289           0 :          npv *=2;             // 2 primitive values, all the data being complex numbers
     290             :        }
     291           0 :        if(es_an[SPP])nSpp=itbnddp->second[nspw].numChan;
     292           0 :        if(es_an[BIN])nBin=itbnddp->second[nspw].numBin;
     293           0 :        nv1 += npv*nBin*nSpp;
     294             :      }
     295             :    }
     296           0 :    if(e_cm_[AUTO_ONLY]){     // (multi) single-dish use-case
     297           0 :      nv1 = nv1*nAntennas*nApc;
     298           0 :      return nv1;
     299             :    }
     300           0 :    if(e_cm_[CROSS_ONLY]){    // non-standard use-case for ALMA, standard use-case for EVLA
     301           0 :      nv1 = nv1*nBaselines*nApc;
     302           0 :      return nv1;
     303             :    }
     304           0 :    if(e_dc[ZERO_LAGS]){      // these auxiliary data can be only antenna-based
     305           0 :      nv1 = nv1*nAntennas*nApc;
     306           0 :      return nv1;
     307             :    }
     308             : 
     309             :    // From here we are now only in the use-case CROSS_AND_AUTO (standard and almost always used for ALMA)
     310           0 :    unsigned int nv=0;
     311             : 
     312             :    // Comments about structural constraints:
     313             :    // FLAGS:
     314             :    //    For the FLAGS meta-data the POL axis, if any, corresponds effectively to a PolarizationType 
     315             :    // axis; the size of this POL axis must be the same for both the non-zero and zero baselines.
     316             :    // APC axis: 
     317             :    //    The following implementation assumes that the APC axis has a size which is the same for
     318             :    // the baseline-based and the antenna-based parts of the metadata (i.e. of ACTUAL_TIMES or
     319             :    // ACTUAL_DURATION or WEIGHTS or FLAGS). In practice we do not expect an APC axis for these
     320             :    // metadata. Would one WVRadiometer have a problem for one antenna, this will be known by looking
     321             :    // at the nature of the flags set in FLAGS; In such situations, for all the baselines which involve 
     322             :    // the antenna(s) with WVR problems, the filler will retrieve ONLY the uncorrected data.
     323             :    // The implication is that actualTimes, actualDurations, weights and flags ARE NOT EXPECTED TO
     324             :    // HAVE "APC" IN THEIR SEQUENCE OF AXES in order to concisely describe the data. 
     325           0 :    if(e_dc[FLAGS]){
     326           0 :      if(es_an[BAL])nv = nv1*nBaselines*nApc;
     327           0 :      if(es_an[ANT])nv += nv1*nAntennas*nApc;
     328           0 :      return nv;
     329             :    }
     330             : 
     331           0 :    if(e_dc[CROSS_DATA]){       // the query is for the size of crossData 
     332           0 :      return nv1*nBaselines*nApc;
     333             :    }
     334             : 
     335             :    // From here we must also account for the implicit numPol of the zero-baselines because, when in the 
     336             :    // case of CROSS_AND_AUTO, only the numPol for the non-zero baselines are explicit.
     337           0 :    nSpp=1;
     338           0 :    nBin=1;
     339           0 :    nPol=1;
     340           0 :    for(itbnddp=itbnddpb;itbnddp!=itbnddpe; ++itbnddp){
     341           0 :      for(unsigned int nspw=0; nspw<itbnddp->second.size(); nspw++){
     342           0 :        if(es_an[SPP])nSpp=itbnddp->second[nspw].numChan;
     343           0 :        if(es_an[BIN])nBin=itbnddp->second[nspw].numBin;
     344           0 :        if(es_an[POL])nPol=numPol(itbnddp->second[nspw].ddIdx); 
     345           0 :        npv = nPol;
     346           0 :        if(es_an[POL] && e_dc[AUTO_DATA]){
     347           0 :          if(nPol==3)npv=4;  // XX XY YY    ==> 4 primitive values, 3 real values and 1 imaginary value
     348           0 :          if(nPol==4)npv=6;  // XX XY YX YY ==> 6 primitive values (use-case not expected for ALMA)
     349             :        }
     350           0 :        nv2 += npv*nBin*nSpp;
     351             :      }
     352             :    }
     353           0 :    nv2 *= nAntennas*nApc;
     354           0 :    if(e_dc[AUTO_DATA])       // the query is for the size of autoData 
     355           0 :      return nv2;
     356             : 
     357           0 :    if(es_an[BAL])nv += nv1;
     358           0 :    if(es_an[ANT])nv += nv2;
     359           0 :    return nv;                 // the query is for the size of actualTimes or actualDurations
     360             : 
     361             :  }
     362             :  
     363             :  
     364             : 
     365             : 
     366           0 : unsigned int BaselinesSet::transferId(unsigned int na, unsigned int ndd, unsigned int nbin){
     367           0 :   unsigned int nfe=0;
     368           0 :   return transferId(na,nfe,ndd,nbin);
     369             : }
     370             : 
     371           0 : unsigned int BaselinesSet::transferId(unsigned int na, unsigned int nfe, unsigned int ndd, unsigned int nbin){
     372           0 :   unsigned int v_cumulAutoSize_ndd=0; 
     373           0 :   if(v_cumulAutoSize_.size()!=0)v_cumulAutoSize_ndd=v_cumulAutoSize_[ndd];
     374           0 :   unsigned int v_autoSize_ndd=0;
     375           0 :   if(v_autoSize_.size()!=0)v_autoSize_ndd=v_autoSize_[ndd];
     376             :   return 
     377           0 :     na*numFeeds_*sumAutoSize_ +                                     // /antenna
     378           0 :     nfe*sumAutoSize_ +                                              // /antenna/feed
     379             :     v_cumulAutoSize_ndd +                                           // /antenna/feed/datadesc
     380           0 :     nbin*(v_autoSize_ndd/numBin(ndd));                              // /antenna/feed/datadesc/bin
     381             : }
     382             : 
     383             : 
     384             : 
     385           0 : unsigned int BaselinesSet::transferId(unsigned int na1, unsigned int na2, unsigned int ndd, unsigned int nbin, unsigned int napc){
     386           0 :   unsigned int nfe=0;
     387           0 :   return transferId(na1,na2, nfe, ndd, nbin, napc);
     388             : }

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