LCOV - code coverage report
Current view: top level - alma/ASDMBinaries - Integration.cc (source / functions) Hit Total Coverage
Test: casacpp_coverage.info Lines: 0 1032 0.0 %
Date: 2024-10-29 13:38:20 Functions: 0 87 0.0 %

          Line data    Source code
       1             : #include <sstream>
       2             : #include <iostream>
       3             : #include <stdlib.h> // for atoi()
       4             : #include <stdint.h>
       5             : 
       6             : #include <alma/ASDMBinaries/Integration.h>
       7             : #include <alma/ASDMBinaries/Error.h>
       8             : 
       9             : using namespace sdmbin;
      10             : using namespace std;
      11             : 
      12             : using namespace AxisNameMod;
      13             : using namespace CorrelationModeMod;
      14             : using namespace NetSidebandMod;
      15             : 
      16             : namespace sdmbin{
      17             : // ============================================================================================
      18             : // DataStructure: the base
      19             : // ============================================================================================
      20             : 
      21           0 :   DataStructure::DataStructure()
      22             :   {
      23           0 :   }
      24             : 
      25           0 :   DataStructure::DataStructure(  uint32_t      numPolProduct, 
      26             :                                  uint32_t      numBin,
      27             :                                  Enum<NetSideband> e_sideband,            
      28             :                                  uint32_t      numBaseband,   
      29             :                                  uint32_t      numAnt,
      30             :                                  CorrelationMode   correlationMode 
      31           0 :                                  )
      32             :   {
      33           0 :     v_numSpectralWindow_.resize(0); 
      34           0 :     vv_numAutoPolProduct_.resize(numBaseband);
      35           0 :     vv_numSpectralPoint_.resize(numBaseband);
      36           0 :     vv_numBin_.resize(numBaseband);
      37           0 :     vv_e_sideband_.resize(numBaseband);
      38           0 :     for(uint32_t nbb=0; nbb<numBaseband; nbb++){
      39           0 :       v_numSpectralWindow_.push_back(1);
      40           0 :       for(uint32_t nspw=0; nspw<numBaseband; nspw++){
      41           0 :         vv_numAutoPolProduct_[nbb].push_back(numPolProduct);
      42           0 :         vv_numSpectralPoint_[nbb].push_back(1);
      43           0 :         vv_numBin_[nbb].push_back(numBin);
      44           0 :         vv_e_sideband_[nbb].push_back(e_sideband);
      45             :       }
      46             :     }
      47           0 :     numApc_          = 1;
      48           0 :     numBaseband_     = numBaseband;
      49           0 :     numAnt_          = numAnt;
      50           0 :     correlationMode_ = correlationMode;
      51           0 :     axisSequence_    = setStructureProperties();
      52           0 :   }
      53             : 
      54           0 :   DataStructure::DataStructure(  uint32_t      numPolProduct,
      55             :                                  uint32_t      numSpectralPoint,
      56             :                                  uint32_t      numBin,
      57             :                                  Enum<NetSideband> e_sideband,
      58             :                                  uint32_t      numBaseband,
      59             :                                  uint32_t      numAnt,
      60           0 :                                  CorrelationMode   correlationMode)
      61             :   {
      62           0 :     v_numSpectralWindow_.resize(0); 
      63           0 :     vv_numAutoPolProduct_.resize(numBaseband);
      64           0 :     vv_numSpectralPoint_.resize(numSpectralPoint);
      65           0 :     vv_numBin_.resize(numBaseband);
      66           0 :     vv_e_sideband_.resize(numBaseband);
      67           0 :     for(uint32_t nbb=0; nbb<numBaseband; nbb++){
      68           0 :       v_numSpectralWindow_.push_back(1);
      69           0 :       for(uint32_t nspw=0; nspw<numBaseband; nspw++){
      70           0 :         vv_numAutoPolProduct_[nbb].push_back(numPolProduct);
      71           0 :         vv_numSpectralPoint_[nbb].push_back(1);
      72           0 :         vv_numBin_[nbb].push_back(numBin);
      73           0 :         vv_e_sideband_[nbb].push_back(e_sideband);
      74             :       }
      75             :     }
      76           0 :     numAnt_          = numAnt;
      77           0 :     numApc_          = 1;
      78           0 :     numBaseband_     = numBaseband;
      79           0 :     correlationMode_ = correlationMode;
      80           0 :     axisSequence_    = setStructureProperties();
      81           0 :   }
      82             : 
      83           0 :   DataStructure::DataStructure( vector<vector<uint32_t> >       vv_numCrossPolProduct,// /bb/spw
      84             :                                 vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
      85             :                                 vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
      86             :                                 vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
      87             :                                 vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
      88             :                                 uint32_t                        numApc,
      89             :                                 vector<uint32_t>                v_numSpectralWindow,  // /bb
      90             :                                 uint32_t                        numBaseband,
      91             :                                 uint32_t                        numAnt,
      92           0 :                                 CorrelationMode                     correlationMode):
      93           0 :     vv_numCrossPolProduct_(vv_numCrossPolProduct),
      94           0 :     vv_numAutoPolProduct_(vv_numAutoPolProduct),
      95           0 :     vv_numSpectralPoint_(vv_numSpectralPoint),
      96           0 :     vv_numBin_(vv_numBin),
      97           0 :     vv_e_sideband_(vv_e_sideband),
      98           0 :     numApc_(numApc),
      99           0 :     v_numSpectralWindow_(v_numSpectralWindow),
     100           0 :     numBaseband_(numBaseband),
     101           0 :     numAnt_(numAnt),
     102           0 :     correlationMode_(correlationMode)
     103             :   {
     104           0 :     axisSequence_ = setStructureProperties();
     105           0 :   }
     106             : 
     107           0 :   DataStructure::DataStructure( vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
     108             :                                 vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
     109             :                                 vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
     110             :                                 vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
     111             :                                 uint32_t                        numApc,
     112             :                                 vector<uint32_t>                v_numSpectralWindow,  // /bb
     113             :                                 uint32_t                        numBaseband,
     114             :                                 uint32_t                        numAnt,
     115           0 :                                 CorrelationMode                     correlationMode):
     116           0 :     vv_numAutoPolProduct_(vv_numAutoPolProduct),
     117           0 :     vv_numSpectralPoint_(vv_numSpectralPoint),
     118           0 :     vv_numBin_(vv_numBin),
     119           0 :     vv_e_sideband_(vv_e_sideband),
     120           0 :     numApc_(numApc),
     121           0 :     v_numSpectralWindow_(v_numSpectralWindow),
     122           0 :     numBaseband_(numBaseband),
     123           0 :     numAnt_(numAnt),
     124           0 :     correlationMode_(correlationMode)
     125             :   {
     126           0 :     vv_numCrossPolProduct_.clear();
     127           0 :     axisSequence_ = setStructureProperties();
     128           0 :   }
     129             : 
     130           0 :   DataStructure::DataStructure( const DataStructure & a)
     131             :   {
     132           0 :     vv_numCrossPolProduct_ = a.vv_numCrossPolProduct_;
     133           0 :     vv_numAutoPolProduct_  = a.vv_numAutoPolProduct_;
     134           0 :     vv_numSpectralPoint_   = a.vv_numSpectralPoint_;
     135           0 :     vv_numBin_             = a.vv_numBin_;
     136           0 :     vv_e_sideband_         = a.vv_e_sideband_;
     137           0 :     numApc_                = a.numApc_;
     138           0 :     v_numSpectralWindow_   = a.v_numSpectralWindow_;
     139           0 :     numBaseband_           = a.numBaseband_;
     140           0 :     numAnt_                = a.numAnt_;
     141           0 :     correlationMode_       = a.correlationMode_;
     142           0 :     axisSequence_          = a.axisSequence_;
     143           0 :     v_minSize_             = a.v_minSize_;
     144           0 :     v_maxSize_             = a.v_maxSize_;
     145           0 :   }
     146             : 
     147           0 :   DataStructure::~DataStructure()
     148             :   {
     149           0 :   }
     150             : 
     151           0 :   string DataStructure::setStructureProperties()
     152             :   {
     153             :     uint32_t  minSize,maxSize;
     154             :     bool          newLevel;
     155           0 :     ostringstream axisSequence;
     156             :   
     157           0 :     newLevel = false;
     158           0 :     minSize  = 100000;
     159           0 :     maxSize  = 0;
     160           0 :     if(vv_numAutoPolProduct_.size()){
     161           0 :       for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     162           0 :         for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     163           0 :           if(vv_numAutoPolProduct_[nbb][nspw]<minSize)minSize=vv_numAutoPolProduct_[nbb][nspw];
     164           0 :           if(vv_numAutoPolProduct_[nbb][nspw]>maxSize)maxSize=vv_numAutoPolProduct_[nbb][nspw];
     165           0 :           if(vv_numAutoPolProduct_[nbb][nspw]>1)newLevel=true;
     166             :         }
     167             :       }
     168             :     }
     169           0 :     if(vv_numCrossPolProduct_.size()){
     170           0 :       for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     171           0 :         for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     172           0 :           if(vv_numCrossPolProduct_[nbb][nspw]<minSize)minSize=vv_numCrossPolProduct_[nbb][nspw];
     173           0 :           if(vv_numCrossPolProduct_[nbb][nspw]>maxSize)maxSize=vv_numCrossPolProduct_[nbb][nspw];
     174           0 :           if(vv_numCrossPolProduct_[nbb][nspw]>1)newLevel=true;
     175             :         }
     176             :       }
     177             :     }
     178           0 :     if( newLevel ){
     179           0 :       v_minSize_.push_back(minSize);
     180           0 :       v_maxSize_.push_back(maxSize);
     181           0 :       axisSequence << "1";
     182             :     }
     183             : 
     184           0 :     newLevel=false;
     185           0 :     minSize  = 1000000;
     186           0 :     maxSize  = 0;
     187           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     188           0 :       for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     189           0 :         if(vv_numSpectralPoint_[nbb][nspw]<minSize)minSize=vv_numSpectralPoint_[nbb][nspw];
     190           0 :         if(vv_numSpectralPoint_[nbb][nspw]>maxSize)maxSize=vv_numSpectralPoint_[nbb][nspw];
     191           0 :         if(vv_numSpectralPoint_[nbb][nspw]>1)newLevel=true;
     192             :       }
     193             :     }
     194           0 :     if( newLevel ){
     195           0 :       v_minSize_.push_back(minSize);
     196           0 :       v_maxSize_.push_back(maxSize);
     197           0 :       axisSequence << "2";
     198             :     }
     199             : 
     200           0 :     if( numApc_>1 ){
     201           0 :       v_minSize_.push_back(numApc_);
     202           0 :       v_maxSize_.push_back(numApc_);
     203           0 :       axisSequence << "3";
     204             :     }
     205             : 
     206           0 :     newLevel=false;
     207           0 :     minSize  = 100000;
     208           0 :     maxSize  = 0;
     209           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     210           0 :       for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     211           0 :         if(vv_numBin_[nbb][nspw]<minSize)minSize=vv_numBin_[nbb][nspw];
     212           0 :         if(vv_numBin_[nbb][nspw]>maxSize)maxSize=vv_numBin_[nbb][nspw];
     213           0 :         if(vv_numBin_[nbb][nspw]>1)newLevel=true;
     214             :       }
     215             :     }
     216           0 :     if( newLevel ){
     217           0 :       v_minSize_.push_back(minSize);
     218           0 :       v_maxSize_.push_back(maxSize);
     219           0 :       axisSequence << "4";
     220             :     }
     221             : 
     222           0 :     newLevel=false;
     223           0 :     minSize  = 100000;
     224           0 :     maxSize  = 0;
     225           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     226           0 :       if(v_numSpectralWindow_[nbb]<minSize)minSize=v_numSpectralWindow_[nbb];
     227           0 :       if(v_numSpectralWindow_[nbb]>maxSize)maxSize=v_numSpectralWindow_[nbb];
     228           0 :       if(v_numSpectralWindow_[nbb]>1)newLevel=true;
     229             :     }
     230           0 :     if( newLevel ){
     231           0 :       v_minSize_.push_back(minSize);
     232           0 :       v_maxSize_.push_back(maxSize);
     233           0 :       axisSequence << "5";
     234             :     }
     235             : 
     236           0 :     if( numBaseband_>1 ){
     237           0 :       v_minSize_.push_back(numBaseband_);
     238           0 :       v_maxSize_.push_back(numBaseband_);
     239           0 :       axisSequence << "6";
     240             :     }
     241             : 
     242           0 :     if(correlationMode_!=AUTO_ONLY){
     243           0 :       v_minSize_.push_back(numAnt_);
     244           0 :       v_maxSize_.push_back(numAnt_);
     245           0 :       axisSequence << "7";
     246             :     }
     247             : 
     248           0 :     if(correlationMode_!=CROSS_ONLY){
     249           0 :       v_minSize_.push_back(numAnt_);
     250           0 :       v_maxSize_.push_back(numAnt_);
     251           0 :       axisSequence << "8";
     252             :     }
     253             : 
     254           0 :     return axisSequence.str();
     255             : 
     256           0 :   }
     257             : 
     258           0 :   vector<vector<uint32_t> >       DataStructure::numCrossPolProducts(){ return vv_numCrossPolProduct_; }
     259             : 
     260           0 :   vector<vector<uint32_t> >       DataStructure::numAutoPolProducts() { return vv_numAutoPolProduct_;  }
     261             : 
     262           0 :   vector<vector<uint32_t> >       DataStructure::numSpectralPoints()  { return vv_numSpectralPoint_;   }
     263             : 
     264           0 :   vector<vector<uint32_t> >       DataStructure::numBins()            { return vv_numBin_;             }
     265             : 
     266           0 :   vector<vector<Enum<NetSideband> > > DataStructure::sidebands()          { return vv_e_sideband_;         }
     267             : 
     268           0 :   uint32_t                        DataStructure::numApc()             { return numApc_;                }
     269             : 
     270           0 :   vector<uint32_t>                DataStructure::numSpectralWindows() { return v_numSpectralWindow_;   }
     271             : 
     272           0 :   uint32_t                        DataStructure::numBaseband()        { return numBaseband_;           }
     273             : 
     274           0 :   uint32_t                        DataStructure::numAnt()             { return  numAnt_;               }
     275             : 
     276           0 :   CorrelationMode                     DataStructure::correlationMode()    { return correlationMode_;       }
     277             : 
     278             : 
     279           0 :   vector<uint32_t> DataStructure::leafAxisSizes(){
     280           0 :     if(!isIndexible()){
     281           0 :       vector<uint32_t> las;
     282           0 :       return las;
     283           0 :     }
     284           0 :     return leafAxisSizes(0,0);
     285             :   }
     286             : 
     287           0 :   vector<uint32_t> DataStructure::leafAxisSizes(uint32_t basebandIndex, uint32_t spectralWindowIndex){
     288           0 :     vector<uint32_t> las;
     289           0 :     if(vv_numBin_[basebandIndex][spectralWindowIndex]!=1)
     290           0 :       las.push_back(vv_numBin_[basebandIndex][spectralWindowIndex]);
     291           0 :     if(numApc_!=1)
     292           0 :       las.push_back(numApc_);
     293           0 :     if(vv_numSpectralPoint_[basebandIndex][spectralWindowIndex]!=1)
     294           0 :       las.push_back(vv_numSpectralPoint_[basebandIndex][spectralWindowIndex]);
     295           0 :     if(vv_numAutoPolProduct_[basebandIndex][spectralWindowIndex]!=1)
     296           0 :       las.push_back(vv_numAutoPolProduct_[basebandIndex][spectralWindowIndex]);
     297           0 :     return las;
     298           0 :   }
     299             : 
     300           0 :   vector<uint32_t> DataStructure::leafAxisSizes(uint32_t ndd){
     301           0 :     vector<uint32_t> las;
     302           0 :     if(ndd==0){
     303           0 :       return leafAxisSizes(0,0);
     304             :     }else{
     305           0 :       uint32_t k=0;
     306             :       uint32_t nb;
     307           0 :       uint32_t nspw=0;
     308           0 :       for(nb=0; nb<numBaseband_; nb++){
     309           0 :         for(nspw=0; nspw<v_numSpectralWindow_[nb]; nspw++){
     310           0 :           if(k==ndd)break;
     311           0 :           k++;
     312             :         }
     313             :       }
     314           0 :       return leafAxisSizes(nb,nspw);
     315             :     }
     316           0 :   }
     317             : 
     318             : 
     319           0 :   uint32_t DataStructure::isIndexible() const
     320             :   {
     321           0 :     uint32_t multidim=0;
     322           0 :     for(uint32_t n=0; n<v_minSize_.size(); n++)
     323           0 :       if(v_minSize_[n]==v_maxSize_[n])multidim++;
     324           0 :     if(multidim==v_minSize_.size())return multidim;
     325           0 :     return 0;
     326             :   }
     327             : 
     328             :   // todo
     329           0 :   vector<uint32_t> DataStructure::eAxisSizes() const
     330             :   {
     331           0 :     vector<uint32_t> v_size;
     332           0 :     if(!isIndexible())return v_size;         // 
     333             :     // 12345678 
     334             :     //v_size.push_back(vv_numCrossPolProduct_[0][0]);
     335           0 :     v_size.push_back(vv_numAutoPolProduct_[0][0]);
     336           0 :     v_size.push_back(vv_numSpectralPoint_[0][0]);
     337           0 :     v_size.push_back(numApc_);
     338           0 :     v_size.push_back(vv_numBin_[0][0]);
     339           0 :     v_size.push_back(v_numSpectralWindow_[0]);
     340           0 :     v_size.push_back(numBaseband_);
     341           0 :     if(correlationMode_!=AUTO_ONLY) v_size.push_back((numAnt_*(numAnt_-1))/2); 
     342           0 :     if(correlationMode_!=CROSS_ONLY)v_size.push_back(numAnt_);
     343           0 :     return v_size;
     344           0 :   }
     345             : 
     346             :   // todo
     347           0 :   vector<uint32_t> DataStructure::axisSizes() const
     348             :   {
     349           0 :     vector<uint32_t> v_size;
     350           0 :     for(uint32_t n=0; n<v_minSize_.size(); n++)
     351           0 :       if(v_minSize_[n]==v_maxSize_[n])v_size.push_back(v_minSize_[n]);     
     352           0 :     return v_size;
     353           0 :   }
     354             : 
     355           0 :   uint32_t DataStructure::dimension() const
     356             :   {
     357           0 :     return (uint32_t)axisSequence_.length();
     358             :   }
     359             : 
     360           0 :   vector<uint32_t> DataStructure::minAxSize() const
     361             :   {
     362           0 :     return v_minSize_;
     363             :   }
     364             : 
     365           0 :   vector<uint32_t> DataStructure::maxAxSize() const
     366             :   {
     367           0 :     return v_maxSize_;
     368             :   }
     369             : 
     370           0 :   uint32_t DataStructure::numCrossData() const
     371             :   {
     372           0 :     uint32_t numCrossData = 1;
     373           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     374           0 :       for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     375           0 :         numCrossData *= 
     376           0 :           vv_numBin_[nbb][nspw] *
     377           0 :           vv_numSpectralPoint_[nbb][nspw] *
     378           0 :           vv_numCrossPolProduct_[nbb][nspw]; 
     379             :       }
     380             :     }
     381           0 :     return numCrossData;
     382             :   }
     383             : 
     384           0 :   uint32_t DataStructure::numAutoData() const
     385             :   {
     386           0 :     uint32_t numAutoData = 1;
     387           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     388           0 :       for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     389           0 :         numAutoData *= 
     390           0 :           vv_numBin_[nbb][nspw] *
     391           0 :           vv_numSpectralPoint_[nbb][nspw] *
     392           0 :           vv_numAutoPolProduct_[nbb][nspw]; 
     393             :       }
     394             :     }
     395             : 
     396             :     //   if( numBaseline_>1 ){
     397             :     //     v_minSize_.push_back(numBaseline_);
     398             :     //     v_maxSize_.push_back(numBaseline_);
     399             :     //     axisSequence << "7";
     400             :     //   }
     401             :     //   numData *= numApc_*numAnt_;         // for total power only!
     402             : 
     403           0 :     return numAutoData;
     404             :   }
     405             : 
     406           0 :   string DataStructure::axisSequence() const
     407             :   {
     408           0 :     return axisSequence_;
     409             :   }
     410             : 
     411           0 :   void DataStructure::summary() const
     412             :   {
     413           0 :     cout<<"Data for "<<numAnt_<<" antenna."<<endl;
     414           0 :     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
     415           0 :       cout<<"  Baseband "<<nbb+1
     416           0 :           <<" has "<<v_numSpectralWindow_[nbb]
     417           0 :           <<" spectral windows."<<endl;
     418           0 :       for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
     419           0 :         cout<<"    Spectral window "<<nspw+1
     420           0 :             <<"  num spectral points: "<<vv_numSpectralPoint_[nbb][nspw]
     421           0 :             <<"  num bins: "<<vv_numBin_[nbb][nspw];
     422           0 :         if(vv_numAutoPolProduct_.size())
     423           0 :           if(vv_numAutoPolProduct_[nbb].size())
     424           0 :             cout<<"  num sd pol.: "<<vv_numAutoPolProduct_[nbb][nspw];
     425           0 :         if(vv_numCrossPolProduct_.size())
     426           0 :           if(vv_numCrossPolProduct_[nbb].size())
     427           0 :             cout<<"  num cross pol.: "<<vv_numCrossPolProduct_[nbb][nspw];
     428           0 :         cout<<endl;
     429             :       }
     430             :     }
     431           0 :     uint32_t multidim = isIndexible();
     432           0 :     if( multidim ){
     433           0 :       cout<<"The data structure is  multi-dimensional with the dimensionality "
     434           0 :           <<multidim<<endl;
     435           0 :       cout<<"  axis order: "<<axisSequence_<<endl;
     436           0 :       vector<uint32_t>v_size=axisSizes();
     437           0 :       ostringstream os; 
     438           0 :       for(uint32_t n=0; n<v_size.size()-1; n++)os<<v_size[n]<<",";
     439           0 :       os<<v_size[v_size.size()-1];
     440           0 :       cout<<"  axis sizes: "<<os.str()<<endl;;
     441           0 :     }
     442           0 :   }
     443             : 
     444             :   // ============================================================================================
     445             :   // DataDump -> DataStructure
     446             :   // ============================================================================================
     447             : 
     448           0 :   DataDump::DataDump()
     449             :   {
     450             :     //cout<<"Default constructor DataDump"<<endl;
     451           0 :   }
     452             : 
     453           0 :   DataDump::DataDump( uint32_t      numPolProduct,
     454             :                       uint32_t      numBin,
     455             :                       Enum<NetSideband> e_sideband,
     456             :                       uint32_t      numBaseband,
     457             :                       uint32_t      numAnt,
     458             :                       CorrelationMode   correlationMode,
     459             :                       uint64_t         time,
     460             :                       uint64_t         timeCentroid,
     461             :                       uint64_t         interval, 
     462             :                       uint64_t         exposure, 
     463           0 :                       const float*      floatData):
     464             :     DataStructure( numPolProduct,
     465             :                    numBin,
     466             :                    e_sideband,
     467             :                    numBaseband,
     468             :                    numAnt,
     469             :                    correlationMode),
     470           0 :     cuintFlagsPtr_(NULL),
     471           0 :     clonlonActualTimesPtr_(NULL),
     472           0 :     clonlonActualDurationsPtr_(NULL),
     473           0 :     cfloatWeightsPtr_(NULL),
     474           0 :     cfloatZeroLagsPtr_(NULL),
     475           0 :     cfloatAutoDataPtr_(floatData),
     476           0 :     cshortCrossDataPtr_(NULL),
     477           0 :     cintCrossDataPtr_(NULL),
     478           0 :     cfloatCrossDataPtr_(NULL)
     479             :   {
     480           0 :     integrationNum_    = 0;
     481           0 :     subintegrationNum_ = 0;
     482           0 :     time_         = time;
     483           0 :     timeCentroid_ = timeCentroid;
     484           0 :     interval_     = interval;
     485           0 :     exposure_     = exposure;
     486             : 
     487           0 :     uintFlagsPtr_             = NULL;
     488           0 :     lonlonActualTimesPtr_     = NULL;
     489           0 :     lonlonActualDurationsPtr_ = NULL;
     490           0 :     floatWeightsPtr_          = NULL;
     491           0 :     floatZeroLagsPtr_         = NULL;
     492           0 :     floatAutoDataPtr_         = NULL;
     493           0 :     shortCrossDataPtr_        = NULL;
     494           0 :     intCrossDataPtr_          = NULL;
     495           0 :     floatCrossDataPtr_        = NULL;
     496             : 
     497           0 :   }
     498             : 
     499             : 
     500           0 :   DataDump::DataDump( uint32_t      numPolProduct,
     501             :                       uint32_t      numSpectralPoint,
     502             :                       uint32_t      numBin,
     503             :                       Enum<NetSideband> e_sideband,
     504             :                       uint32_t      numBaseband,
     505             :                       uint32_t      numAnt,
     506             :                       CorrelationMode   correlationMode,
     507             :                       uint64_t         time,
     508             :                       uint64_t         timeCentroid, 
     509             :                       uint64_t         interval,
     510             :                       uint64_t         exposure,
     511             :                       const float*             floatData, 
     512           0 :                       const uint32_t* dataFlags):
     513             :     DataStructure( numPolProduct,
     514             :                    numSpectralPoint,
     515             :                    numBin,
     516             :                    e_sideband,
     517             :                    numBaseband,
     518             :                    numAnt,
     519             :                    correlationMode),
     520           0 :     cuintFlagsPtr_(dataFlags),
     521           0 :     clonlonActualTimesPtr_(NULL),
     522           0 :     clonlonActualDurationsPtr_(NULL),
     523           0 :     cfloatWeightsPtr_(NULL),
     524           0 :     cfloatZeroLagsPtr_(NULL),
     525           0 :     cfloatAutoDataPtr_(floatData),
     526           0 :     cshortCrossDataPtr_(NULL),
     527           0 :     cintCrossDataPtr_(NULL),
     528           0 :     cfloatCrossDataPtr_(NULL)
     529             :   {   
     530           0 :     integrationNum_    = 0;
     531           0 :     subintegrationNum_ = 0;
     532           0 :     time_              = time;
     533           0 :     timeCentroid_      = timeCentroid;  cout<<"timeCentroid="<<timeCentroid<<endl;
     534           0 :     interval_          = interval;       
     535           0 :     exposure_          = exposure;
     536             : 
     537           0 :     uintFlagsPtr_             = NULL;
     538           0 :     lonlonActualTimesPtr_     = NULL;
     539           0 :     lonlonActualDurationsPtr_ = NULL;
     540           0 :     floatWeightsPtr_          = NULL;
     541           0 :     floatZeroLagsPtr_         = NULL;
     542           0 :     floatAutoDataPtr_         = NULL;
     543           0 :     shortCrossDataPtr_        = NULL;
     544           0 :     intCrossDataPtr_          = NULL;
     545           0 :     floatCrossDataPtr_        = NULL;
     546           0 :   }
     547             : 
     548           0 :   DataDump::DataDump( vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
     549             :                       vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
     550             :                       vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
     551             :                       vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
     552             :                       uint32_t                        numApc,
     553             :                       vector<uint32_t>                v_numSpectralWindow,  // /bb
     554             :                       uint32_t                        numBaseband,
     555             :                       uint32_t                        numAnt,
     556             :                       CorrelationMode                     correlationMode,
     557             :                       uint64_t                           time,
     558             :                       uint64_t                           timeCentroid,  
     559             :                       uint64_t                           interval,
     560             :                       uint64_t                           exposure,  
     561             :                       const float*                        floatData, 
     562           0 :                       const uint32_t*                 dataFlags):
     563             :     DataStructure( vv_numAutoPolProduct,
     564             :                    vv_numSpectralPoint,
     565             :                    vv_numBin,
     566             :                    vv_e_sideband,
     567             :                    numApc,
     568             :                    v_numSpectralWindow,
     569             :                    numBaseband,
     570             :                    numAnt,
     571             :                    correlationMode),
     572           0 :     integrationNum_(0),
     573           0 :     subintegrationNum_(0),
     574           0 :     time_(time),
     575           0 :     timeCentroid_(timeCentroid),
     576           0 :     interval_(interval),
     577           0 :     exposure_(exposure),
     578           0 :     cuintFlagsPtr_(dataFlags),
     579           0 :     clonlonActualTimesPtr_(NULL),
     580           0 :     clonlonActualDurationsPtr_(NULL),
     581           0 :     cfloatWeightsPtr_(NULL),
     582           0 :     cfloatZeroLagsPtr_(NULL),
     583           0 :     cfloatAutoDataPtr_(floatData),
     584           0 :     cshortCrossDataPtr_(NULL),
     585           0 :     cintCrossDataPtr_(NULL),
     586           0 :     cfloatCrossDataPtr_(NULL)
     587             :   {
     588           0 :     uintFlagsPtr_             = NULL;
     589           0 :     lonlonActualTimesPtr_     = NULL;
     590           0 :     lonlonActualDurationsPtr_ = NULL;
     591           0 :     floatWeightsPtr_          = NULL;
     592           0 :     floatZeroLagsPtr_         = NULL;
     593           0 :     floatAutoDataPtr_         = NULL;
     594           0 :     shortCrossDataPtr_        = NULL;
     595           0 :     intCrossDataPtr_          = NULL;
     596           0 :     floatCrossDataPtr_        = NULL;
     597           0 :   }
     598             : 
     599           0 :   DataDump::DataDump( vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
     600             :                       vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
     601             :                       vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
     602             :                       vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
     603             :                       uint32_t                        numApc,
     604             :                       vector<uint32_t>                v_numSpectralWindow,  // /bb
     605             :                       uint32_t                        numBaseband,
     606             :                       uint32_t                        numAnt,
     607             :                       CorrelationMode                     correlationMode,
     608             :                       uint64_t                           time,
     609             :                       uint64_t                           timeCentroid,  
     610             :                       uint64_t                           interval,
     611             :                       uint64_t                           exposure,  
     612           0 :                       const float*                        floatData):
     613             :     DataStructure( vv_numAutoPolProduct,    
     614             :                    vv_numSpectralPoint,
     615             :                    vv_numBin,
     616             :                    vv_e_sideband,
     617             :                    numApc,
     618             :                    v_numSpectralWindow,
     619             :                    numBaseband,
     620             :                    numAnt,
     621             :                    correlationMode),
     622           0 :     integrationNum_(0),
     623           0 :     subintegrationNum_(0),
     624           0 :     time_(time),
     625           0 :     timeCentroid_(timeCentroid),
     626           0 :     interval_(interval),
     627           0 :     exposure_(exposure),
     628           0 :     cuintFlagsPtr_(NULL),
     629           0 :     clonlonActualTimesPtr_(NULL),
     630           0 :     clonlonActualDurationsPtr_(NULL),
     631           0 :     cfloatWeightsPtr_(NULL),
     632           0 :     cfloatZeroLagsPtr_(NULL),
     633           0 :     cfloatAutoDataPtr_(floatData),
     634           0 :     cshortCrossDataPtr_(NULL),
     635           0 :     cintCrossDataPtr_(NULL),
     636           0 :     cfloatCrossDataPtr_(NULL)
     637             :   {
     638           0 :     uintFlagsPtr_             = NULL;
     639           0 :     lonlonActualTimesPtr_     = NULL;
     640           0 :     lonlonActualDurationsPtr_ = NULL;
     641           0 :     floatWeightsPtr_          = NULL;
     642           0 :     floatZeroLagsPtr_         = NULL;
     643           0 :     floatAutoDataPtr_         = NULL;
     644           0 :     shortCrossDataPtr_        = NULL;
     645           0 :     intCrossDataPtr_          = NULL;
     646           0 :     floatCrossDataPtr_        = NULL;
     647           0 :   }
     648             : 
     649           0 :   DataDump::DataDump( vector<vector<uint32_t> >       vv_numCrossPolProduct,// /bb/spw
     650             :                       vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
     651             :                       vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
     652             :                       vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
     653             :                       vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
     654             :                       uint32_t                        numApc,
     655             :                       vector<uint32_t>                v_numSpectralWindow,  // /bb
     656             :                       uint32_t                        numBaseband,
     657             :                       uint32_t                        numAnt,
     658             :                       CorrelationMode                     correlationMode,
     659             :                       uint64_t                           time,
     660             :                       uint64_t                           timeCentroid,  
     661             :                       uint64_t                           interval, 
     662           0 :                       uint64_t                           exposure):
     663             :     DataStructure( vv_numCrossPolProduct,
     664             :                    vv_numAutoPolProduct,
     665             :                    vv_numSpectralPoint,
     666             :                    vv_numBin,
     667             :                    vv_e_sideband,
     668             :                    numApc,
     669             :                    v_numSpectralWindow,
     670             :                    numBaseband,
     671             :                    numAnt,
     672             :                    correlationMode),
     673           0 :     integrationNum_(0),
     674           0 :     subintegrationNum_(0),
     675           0 :     time_(time),
     676           0 :     timeCentroid_(timeCentroid),
     677           0 :     interval_(interval),
     678           0 :     exposure_(exposure),
     679           0 :     es_flagsAxes_(), 
     680           0 :     es_actualTimesAxes_(),   
     681           0 :     es_actualDurationsAxes_(),   
     682           0 :     es_weightsAxes_(), 
     683           0 :     es_zeroLagsAxes_(), 
     684           0 :     es_autoDataAxes_(), 
     685           0 :     es_crossDataAxes_(),
     686           0 :     numFlags_(0),     
     687           0 :     numActualTimes_(0), 
     688           0 :     numActualDurations_(0), 
     689           0 :     numWeights_(0),     
     690           0 :     numZeroLags_(0),     
     691           0 :     numAutoData_(0),     
     692           0 :     numCrossData_(0),
     693           0 :     cuintFlagsPtr_(NULL),
     694           0 :     clonlonActualTimesPtr_(NULL),
     695           0 :     clonlonActualDurationsPtr_(NULL),
     696           0 :     cfloatWeightsPtr_(NULL),
     697           0 :     cfloatZeroLagsPtr_(NULL),
     698           0 :     cfloatAutoDataPtr_(NULL),
     699           0 :     cshortCrossDataPtr_(NULL),
     700           0 :     cintCrossDataPtr_(NULL),
     701           0 :     cfloatCrossDataPtr_(NULL)
     702             :   {
     703             : 
     704             :     // By default the scale factor is set to 1 for all spw. It must be updated subsequently if required
     705             :     // using the method setScaleFactor().
     706           0 :     if(vv_numCrossPolProduct.size()){
     707           0 :       for(uint32_t nbb=0; nbb<numBaseband; nbb++){
     708           0 :         vector<float> v_f;
     709           0 :         for(uint32_t nspw=0; nspw<vv_numCrossPolProduct[nbb].size(); nspw++)v_f.push_back(1.0);
     710           0 :         vv_scaleFactor_.push_back(v_f);
     711           0 :       }
     712             :     }
     713             :                                                                                 
     714           0 :     uintFlagsPtr_             = NULL;
     715           0 :     lonlonActualTimesPtr_     = NULL;
     716           0 :     lonlonActualDurationsPtr_ = NULL;
     717           0 :     floatWeightsPtr_          = NULL;
     718           0 :     floatZeroLagsPtr_         = NULL;
     719           0 :     floatAutoDataPtr_         = NULL;
     720           0 :     shortCrossDataPtr_        = NULL;
     721           0 :     intCrossDataPtr_          = NULL;
     722           0 :     floatCrossDataPtr_        = NULL;
     723             : 
     724           0 :   }
     725             : 
     726             : 
     727           0 :   DataDump::DataDump( vector<vector<uint32_t> >       vv_numCrossPolProduct,        // /bb/spw
     728             :                       vector<vector<uint32_t> >       vv_numAutoPolProduct, // /bb/spw
     729             :                       vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
     730             :                       vector<vector<uint32_t> >       vv_numBin,    // /bb/spw
     731             :                       vector<vector<Enum<NetSideband> > > vv_e_sideband,      // /bb/spw
     732             :                       uint32_t          numApc,
     733             :                       vector<uint32_t>  v_numSpectralWindow,      // /bb
     734             :                       uint32_t          numBaseband,
     735             :                       uint32_t          numAnt,
     736             :                       CorrelationMode   correlationMode,
     737             :                       uint64_t          time,
     738             :                       uint64_t          timeCentroid,  
     739             :                       uint64_t          interval,
     740             :                       uint64_t          exposure,
     741             :                       uint32_t          /*numVal*/, // comment to avoid the unused parameter warning
     742             :                       const int*        /*crossData*/, // comment to avoid the unused parameter warning
     743             :                       uint32_t          numAutoData,
     744             :                       const float*      autoData,
     745             :                       uint32_t          numFlags,
     746           0 :                       const uint32_t*                 flags):
     747             :     DataStructure( vv_numCrossPolProduct,
     748             :                    vv_numAutoPolProduct,
     749             :                    vv_numSpectralPoint,
     750             :                    vv_numBin,
     751             :                    vv_e_sideband,
     752             :                    numApc,
     753             :                    v_numSpectralWindow,
     754             :                    numBaseband,
     755             :                    numAnt,
     756             :                    correlationMode),
     757           0 :     integrationNum_(0),
     758           0 :     subintegrationNum_(0),
     759           0 :     time_(time),
     760           0 :     timeCentroid_(timeCentroid),
     761           0 :     interval_(interval),
     762           0 :     exposure_(exposure),
     763           0 :     cuintFlagsPtr_(NULL),
     764           0 :     clonlonActualTimesPtr_(NULL),
     765           0 :     clonlonActualDurationsPtr_(NULL),
     766           0 :     cfloatWeightsPtr_(NULL),
     767           0 :     cfloatZeroLagsPtr_(NULL),
     768           0 :     cfloatAutoDataPtr_(NULL),
     769           0 :     cshortCrossDataPtr_(NULL),
     770           0 :     cintCrossDataPtr_(NULL),
     771           0 :     cfloatCrossDataPtr_(NULL)
     772             :   {
     773           0 :     uintFlagsPtr_     = new uint32_t[numFlags]; for(uint32_t n=0; n<numFlags; n++)uintFlagsPtr_[n] = flags[n];
     774           0 :     lonlonActualTimesPtr_     = NULL;
     775           0 :     lonlonActualDurationsPtr_ = NULL;
     776           0 :     floatWeightsPtr_          = NULL;
     777             : 
     778           0 :     floatZeroLagsPtr_         = NULL;
     779             : 
     780           0 :     floatAutoDataPtr_ = new float[numAutoData]; for(uint32_t n=0; n<numAutoData; n++)floatAutoDataPtr_[n] = autoData[n];
     781             :     
     782           0 :     shortCrossDataPtr_        = NULL;
     783           0 :     intCrossDataPtr_          = NULL;
     784           0 :     floatCrossDataPtr_        = NULL;
     785             : 
     786           0 :   }
     787             : 
     788             : 
     789           0 :   DataDump::~DataDump()
     790             :   {
     791           0 :     bool coutest=false;
     792           0 :     if(coutest){
     793           0 :       cout<<"Destructor DataDump"<<endl;
     794           0 :       if(uintFlagsPtr_             ) cout<<"delete uintFlagsPtr_"<<endl;
     795           0 :       if(lonlonActualTimesPtr_     ) cout<<"delete lonlonActualTimesPtr_"<<endl;
     796           0 :       if(lonlonActualDurationsPtr_ ) cout<<"delete lonlonActualDurationsPtr_"<<endl;
     797           0 :       if(floatWeightsPtr_          ) cout<<"delete floatWeightsPtr_"<<endl;
     798           0 :       if(floatZeroLagsPtr_         ) cout<<"delete floatZeroLagsPtr_"<<endl;
     799           0 :       if(floatAutoDataPtr_         ) cout<<"delete floatAutoDataPtr_"<<endl;
     800           0 :       if(shortCrossDataPtr_        ) cout<<"delete shortCrossDataPtr_"<<endl;
     801           0 :       if(intCrossDataPtr_          ) cout<<"delete intCrossDataPtr_"<<endl;
     802           0 :       if(floatCrossDataPtr_        ) cout<<"delete floatCrossDataPtr_"<<endl;
     803             :     }
     804           0 :     if(uintFlagsPtr_             ) delete uintFlagsPtr_;
     805           0 :     if(lonlonActualTimesPtr_     ) delete lonlonActualTimesPtr_;
     806           0 :     if(lonlonActualDurationsPtr_ ) delete lonlonActualDurationsPtr_;
     807           0 :     if(floatWeightsPtr_          ) delete floatWeightsPtr_;
     808           0 :     if(floatZeroLagsPtr_         ) delete floatZeroLagsPtr_;
     809           0 :     if(floatAutoDataPtr_         ) delete floatAutoDataPtr_;
     810           0 :     if(shortCrossDataPtr_        ) delete shortCrossDataPtr_;
     811           0 :     if(intCrossDataPtr_          ) delete intCrossDataPtr_;
     812           0 :     if(floatCrossDataPtr_        ) delete floatCrossDataPtr_;
     813           0 :   }
     814             : 
     815           0 :   DataDump::DataDump(const DataDump& a) : DataStructure(a)
     816             :   {
     817           0 :     cout<<"Copy constructor DataDump (deep copy)"<<endl;
     818           0 :     cout<<"ici a.uintFlagsPtr_="<<a.uintFlagsPtr_<<endl;
     819           0 :     vv_numCrossPolProduct_= a.vv_numCrossPolProduct_;
     820           0 :     vv_numAutoPolProduct_ = a.vv_numAutoPolProduct_;
     821           0 :     vv_numSpectralPoint_  = a.vv_numSpectralPoint_;
     822           0 :     vv_numBin_            = a.vv_numBin_;
     823           0 :     vv_e_sideband_        = a.vv_e_sideband_;
     824           0 :     numApc_               = a.numApc_;
     825           0 :     v_numSpectralWindow_  = a.v_numSpectralWindow_;
     826           0 :     numBaseband_          = a.numBaseband_;
     827           0 :     numAnt_               = a.numAnt_;
     828           0 :     correlationMode_      = a.correlationMode_;
     829           0 :     axisSequence_         = a.axisSequence_;
     830           0 :     v_minSize_            = a.v_minSize_;
     831           0 :     v_maxSize_            = a.v_maxSize_;
     832             : 
     833           0 :     integrationNum_       = a.integrationNum_;
     834           0 :     subintegrationNum_    = a.subintegrationNum_;
     835           0 :     time_                 = a.time_;
     836           0 :     timeCentroid_         = a.timeCentroid_;
     837           0 :     interval_             = a.interval_;
     838           0 :     exposure_             = a.exposure_;
     839             : 
     840           0 :     vv_scaleFactor_       = a.vv_scaleFactor_;
     841             : 
     842           0 :     es_flagsAxes_           = a.es_flagsAxes_; 
     843           0 :     es_actualTimesAxes_     = a.es_actualTimesAxes_;   
     844           0 :     es_actualDurationsAxes_ = a.es_actualDurationsAxes_;   
     845           0 :     es_weightsAxes_         = a.es_weightsAxes_; 
     846             : 
     847           0 :     es_zeroLagsAxes_        = a.es_zeroLagsAxes_; 
     848             : 
     849           0 :     es_autoDataAxes_        = a.es_autoDataAxes_; 
     850           0 :     es_crossDataAxes_       = a.es_crossDataAxes_;
     851             : 
     852             : 
     853           0 :     numFlags_               = a.numFlags_;
     854           0 :     numActualTimes_         = a.numActualTimes_;
     855           0 :     numActualDurations_     = a.numActualDurations_;
     856           0 :     numWeights_             = a.numWeights_;
     857             :     
     858           0 :     numZeroLags_            = a.numZeroLags_;
     859             :      
     860           0 :     numAutoData_            = a.numAutoData_; 
     861           0 :     numCrossData_           = a.numCrossData_;
     862           0 :     cout<<"A"<<endl;
     863           0 :     cout<<"a.cuintFlagsPtr_"<<a.cuintFlagsPtr_<<endl;
     864           0 :     cout<<"a.flags()="<<a.flags()<<endl;
     865           0 :     cuintFlagsPtr_              = a.cuintFlagsPtr_;
     866           0 :     cout<<"B"<<endl;
     867           0 :     clonlonActualTimesPtr_      = a.clonlonActualTimesPtr_;
     868           0 :     clonlonActualDurationsPtr_  = a.clonlonActualDurationsPtr_;
     869           0 :     cfloatWeightsPtr_           = a.cfloatWeightsPtr_;
     870             : 
     871           0 :     cfloatZeroLagsPtr_          = a.cfloatZeroLagsPtr_;
     872             : 
     873           0 :     cfloatAutoDataPtr_          = a.cfloatAutoDataPtr_;
     874           0 :     cshortCrossDataPtr_         = a.cshortCrossDataPtr_;
     875           0 :     cintCrossDataPtr_           = a.cintCrossDataPtr_;
     876           0 :     cout<<"C"<<endl;
     877           0 :     cout<<"a.uintFlagsPtr_"<<a.uintFlagsPtr_<<endl;
     878           0 :     if(a.uintFlagsPtr_){
     879           0 :       cout<<"a.numFlags_="<<a.numFlags_<<endl;
     880           0 :       uintFlagsPtr_ = new uint32_t[a.numFlags_]; 
     881           0 :       for(uint32_t n=0; n<a.numFlags_; n++) uintFlagsPtr_[n] = a.uintFlagsPtr_[n]; }
     882           0 :     cout<<"D"<<endl;
     883           0 :     if(a.lonlonActualTimesPtr_){
     884           0 :       cout<<"a.numActualTimes_="<<a.numActualTimes_<<endl;
     885           0 :       lonlonActualTimesPtr_ = new int64_t[numActualTimes_]; 
     886           0 :       for(uint32_t n=0; n<numActualTimes_; n++)lonlonActualTimesPtr_[n] = a.lonlonActualTimesPtr_[n]; }
     887           0 :     if(a.lonlonActualDurationsPtr_){
     888           0 :       lonlonActualDurationsPtr_ = new int64_t[numActualDurations_]; 
     889           0 :       for(uint32_t n=0; n<numActualDurations_; n++)lonlonActualDurationsPtr_[n] = a.lonlonActualDurationsPtr_[n]; }
     890           0 :     if(a.floatWeightsPtr_){
     891           0 :       floatWeightsPtr_ = new float[numWeights_]; 
     892           0 :       for(uint32_t n=0; n<numWeights_; n++)floatWeightsPtr_[n] = a.floatWeightsPtr_[n]; }
     893             : 
     894           0 :     if(a.floatZeroLagsPtr_){
     895           0 :       floatZeroLagsPtr_ = new float[numZeroLags_]; 
     896           0 :       for(uint32_t n=0; n<numZeroLags_; n++)floatZeroLagsPtr_[n] = a.floatZeroLagsPtr_[n]; }
     897           0 :     if(a.shortCrossDataPtr_){
     898           0 :       cout<<"a.numCrossData_="<<a.numCrossData_<<endl;
     899           0 :       cout<<"numCrossData_="<<numCrossData_<<endl;
     900           0 :       shortCrossDataPtr_ = new short int[numCrossData_]; 
     901           0 :       for(uint32_t n=0; n<numCrossData_; n++)shortCrossDataPtr_[n] = a.shortCrossDataPtr_[n]; }
     902           0 :     if(a.intCrossDataPtr_){
     903           0 :       intCrossDataPtr_ = new int[numCrossData_]; 
     904           0 :       for(uint32_t n=0; n<numCrossData_; n++)intCrossDataPtr_[n] = a.intCrossDataPtr_[n]; }
     905           0 :     if(a.floatCrossDataPtr_){
     906           0 :       floatCrossDataPtr_ = new float[numCrossData_]; 
     907           0 :       for(uint32_t n=0; n<numCrossData_; n++)floatCrossDataPtr_[n] = a.floatCrossDataPtr_[n]; }
     908           0 :     cout<<"E"<<endl;
     909           0 :     cout<<"floatAutoDataPtr_ ="<<floatAutoDataPtr_<<endl;
     910           0 :     cout<<"a.floatAutoDataPtr_ ="<<a.floatAutoDataPtr_<<endl;
     911           0 :     if(a.floatAutoDataPtr_){
     912           0 :       cout<<"a.numAutoData_="<<a.numAutoData_<<endl;
     913           0 :       cout<<"numAutoData_="<<numAutoData_<<endl;
     914           0 :       floatAutoDataPtr_ = new float[numAutoData_]; 
     915           0 :       for(uint32_t n=0; n<numAutoData_; n++)floatAutoDataPtr_[n] = a.floatAutoDataPtr_[n]; }
     916             : 
     917           0 :      cout<<"F"<<endl;
     918             :     
     919           0 :   }
     920             : 
     921           0 :   DataDump& DataDump::operator = (const DataDump & a)
     922             :   {
     923           0 :     if(this == &a)return *this;
     924           0 :     vv_numCrossPolProduct_= a.vv_numCrossPolProduct_;
     925           0 :     vv_numAutoPolProduct_ = a.vv_numAutoPolProduct_;
     926           0 :     vv_numSpectralPoint_  = a.vv_numSpectralPoint_;
     927           0 :     vv_numBin_            = a.vv_numBin_;
     928           0 :     vv_e_sideband_        = a.vv_e_sideband_;
     929           0 :     numApc_               = a.numApc_;
     930           0 :     v_numSpectralWindow_  = a.v_numSpectralWindow_;
     931           0 :     numBaseband_          = a.numBaseband_;
     932           0 :     numAnt_               = a.numAnt_;
     933           0 :     correlationMode_      = a.correlationMode_;
     934           0 :     axisSequence_         = a.axisSequence_;
     935           0 :     v_minSize_            = a.v_minSize_;
     936           0 :     v_maxSize_            = a.v_maxSize_;
     937             : 
     938           0 :     integrationNum_       = a.integrationNum_;
     939           0 :     subintegrationNum_    = a.subintegrationNum_;
     940           0 :     time_                 = a.time_;
     941           0 :     timeCentroid_         = a.timeCentroid_;
     942           0 :     interval_             = a.interval_;
     943           0 :     exposure_             = a.exposure_;
     944             : 
     945           0 :     return *this;
     946             :   }
     947             : 
     948             :   // shape unchanged
     949           0 :   DataDump DataDump::operator - (const DataDump &rhs)
     950             :   {
     951           0 :     uint32_t numD=numAutoData();
     952           0 :     if(rhs.numAutoData()!=numD){
     953           0 :       ostringstream os;
     954           0 :       os << "Cannot subtract a data dump which has " << rhs.numAutoData()
     955           0 :          <<" data from an other which has "<<numD
     956           0 :          <<" data";
     957           0 :       Error( FATAL, os.str());
     958           0 :     }
     959           0 :     uint64_t st1 = (time_-interval_)/(uint64_t)2;
     960           0 :     uint64_t et1 = (time_+interval_)/(uint64_t)2; 
     961           0 :     uint64_t st2 = (rhs.time()-rhs.interval())/(uint64_t)2;
     962           0 :     uint64_t et2 = (rhs.time()+rhs.interval())/(uint64_t)2; 
     963           0 :     if( st1>et2 || et1<st2)
     964           0 :       Error( WARNING, (char *) "data difference of dumps overlaping in time");
     965             :     uint64_t st,et;
     966           0 :     if(st1<st2)
     967           0 :       st = st1;
     968             :     else
     969           0 :       st = st2;
     970           0 :     if(et1<et2)
     971           0 :       et = et2;
     972             :     else
     973           0 :       et = et1;
     974             : 
     975             :     uint64_t timeCentroid;
     976           0 :     if(interval_==rhs.interval())
     977           0 :       timeCentroid = (time_+rhs.time())/(uint64_t)2;
     978             :     else{
     979           0 :       double w=interval_/rhs.interval();
     980           0 :       timeCentroid = (uint64_t) ( (w*time_ + rhs.time())/(w+1.) );
     981             :     }
     982             : 
     983           0 :     uint32_t       numF = numD;                                  // TODO (more complex than that!)
     984           0 :     float*             diffFloatData = new float[numD];
     985           0 :     uint32_t*      sumUintFlags  = new uint32_t[numF];
     986             : 
     987           0 :     if(floatAutoDataPtr_){
     988           0 :       if(rhs.floatAutoDataPtr_){
     989           0 :         for(uint32_t nd=0; nd<numD; nd++)
     990           0 :           diffFloatData[nd] = floatAutoDataPtr_[nd]-rhs.floatAutoDataPtr_[nd];
     991           0 :         for(uint32_t nf=0; nf<numF; nf++){
     992           0 :           if(uintFlagsPtr_[nf]!=rhs.uintFlagsPtr_[nf])
     993           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf]+rhs.uintFlagsPtr_[nf];  // TODO (more complex than that!)
     994             :           else
     995           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf];
     996             :         }
     997             :       }else{
     998           0 :         for(uint32_t nd=0; nd<numD; nd++)
     999           0 :           diffFloatData[nd] = floatAutoDataPtr_[nd]-rhs.cfloatAutoDataPtr_[nd];
    1000           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1001           0 :           if(uintFlagsPtr_[nf]!=rhs.cuintFlagsPtr_[nf])
    1002           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf]+rhs.cuintFlagsPtr_[nf];  // TODO (more complex than that!)
    1003             :           else
    1004           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf];
    1005             :         }
    1006             :       }
    1007             :     }else{
    1008           0 :       if(rhs.floatAutoDataPtr_){
    1009           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1010           0 :           diffFloatData[nd] = cfloatAutoDataPtr_[nd]-rhs.floatAutoDataPtr_[nd];
    1011           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1012           0 :           if(cuintFlagsPtr_[nf]!=rhs.uintFlagsPtr_[nf])
    1013           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf]+rhs.uintFlagsPtr_[nf];  // TODO (more complex than that!)
    1014             :           else
    1015           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf];
    1016             :         }
    1017             :       }else{
    1018           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1019           0 :           diffFloatData[nd] = cfloatAutoDataPtr_[nd]-rhs.cfloatAutoDataPtr_[nd];
    1020           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1021           0 :           if(cuintFlagsPtr_[nf]!=rhs.cuintFlagsPtr_[nf])
    1022           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf]+rhs.cuintFlagsPtr_[nf];  // TODO (more complex than that!)
    1023             :           else
    1024           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf];
    1025             :         }
    1026             :       }
    1027             :     }    
    1028           0 :     uint32_t numV=0;  // TODO
    1029           0 :     int*         diffCorrData=NULL;
    1030           0 :     return DataDump( vv_numCrossPolProduct_,
    1031           0 :                      vv_numAutoPolProduct_,
    1032           0 :                      vv_numSpectralPoint_,
    1033           0 :                      vv_numBin_,
    1034           0 :                      vv_e_sideband_,
    1035             :                      numApc_,
    1036           0 :                      v_numSpectralWindow_,
    1037             :                      numBaseband_,
    1038             :                      numAnt_,
    1039             :                      correlationMode_,
    1040           0 :                      (time_+rhs.time())/(uint64_t) 2,
    1041             :                      timeCentroid,
    1042             :                      et-st,
    1043           0 :                      exposure_+rhs.exposure(),
    1044             :                      numV, diffCorrData,
    1045             :                      numD, diffFloatData,
    1046             :                      numF, sumUintFlags
    1047           0 :                      );
    1048             :   }
    1049             : 
    1050           0 :   DataDump DataDump::operator + (const DataDump &rhs)
    1051             :   {
    1052           0 :     uint32_t numD=numAutoData();
    1053           0 :     if(rhs.numAutoData()!=numD){
    1054           0 :       ostringstream os;
    1055           0 :       os << "Cannot add a data dump which has " << numD
    1056           0 :          <<" data with an other which has "<<rhs.numAutoData()
    1057           0 :          <<" data";
    1058           0 :       Error( FATAL, os.str());
    1059           0 :     }
    1060           0 :     uint64_t st1 = (time_-interval_)/(uint64_t)2;
    1061           0 :     uint64_t et1 = (time_+interval_)/(uint64_t)2; 
    1062           0 :     uint64_t st2 = (rhs.time()-rhs.interval())/(uint64_t)2;
    1063           0 :     uint64_t et2 = (rhs.time()+rhs.interval())/(uint64_t)2; 
    1064           0 :     if( st1>et2 || et1<st2)
    1065           0 :       Error( WARNING, (char *) "sum of data dumps which overlap in time");
    1066             :     uint64_t st,et;
    1067           0 :     if(st1<st2)
    1068           0 :       st = st1;
    1069             :     else
    1070           0 :       st = st2;
    1071           0 :     if(et1<et2)
    1072           0 :       et = et2;
    1073             :     else
    1074           0 :       et = et1;
    1075             : 
    1076             :     uint64_t timeCentroid;
    1077           0 :     if(interval_==rhs.interval())
    1078           0 :       timeCentroid = (time_+rhs.time())/(uint64_t)2;
    1079             :     else{
    1080           0 :       double w=interval_/rhs.interval();
    1081           0 :       timeCentroid = (uint64_t) ( (w*time_ + rhs.time())/(w+1.) );
    1082             :     }
    1083           0 :     uint32_t numF = numD;                                           // TODO (more complex than that!)
    1084           0 :     float*             sumFloatData = new float[numD];
    1085           0 :     uint32_t*      sumUintFlags = new uint32_t[numF];
    1086             : 
    1087           0 :     if(floatAutoDataPtr_){
    1088           0 :       if(rhs.floatAutoDataPtr_){
    1089           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1090           0 :           sumFloatData[nd] = 0.5*(floatAutoDataPtr_[nd]+rhs.floatAutoDataPtr_[nd]);
    1091           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1092           0 :           if(uintFlagsPtr_[nf]!=rhs.uintFlagsPtr_[nf])
    1093           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf]+rhs.uintFlagsPtr_[nf];  // TODO (more complex than that!)
    1094             :           else
    1095           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf];
    1096             :         }
    1097             :       }else{
    1098           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1099           0 :           sumFloatData[nd] = 0.5*(floatAutoDataPtr_[nd]+rhs.cfloatAutoDataPtr_[nd]);
    1100           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1101           0 :           if(uintFlagsPtr_[nf]!=rhs.cuintFlagsPtr_[nf])
    1102           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf]+rhs.cuintFlagsPtr_[nf];  // TODO (more complex than that!)
    1103             :           else
    1104           0 :             sumUintFlags[nf]=uintFlagsPtr_[nf];
    1105             :         }
    1106             :       }
    1107             :     }else{
    1108           0 :       if(rhs.floatAutoDataPtr_){
    1109           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1110           0 :           sumFloatData[nd] = 0.5*(cfloatAutoDataPtr_[nd]+rhs.floatAutoDataPtr_[nd]);
    1111           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1112           0 :           if(cuintFlagsPtr_[nf]!=rhs.uintFlagsPtr_[nf])
    1113           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf]+rhs.uintFlagsPtr_[nf];  // TODO (more complex than that!)
    1114             :           else
    1115           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf];
    1116             :         }
    1117             :       }else{
    1118           0 :         for(uint32_t nd=0; nd<numD; nd++)
    1119           0 :           sumFloatData[nd] = 0.5*(cfloatAutoDataPtr_[nd]+rhs.cfloatAutoDataPtr_[nd]);
    1120           0 :         for(uint32_t nf=0; nf<numF; nf++){
    1121           0 :           if(cuintFlagsPtr_[nf]!=rhs.cuintFlagsPtr_[nf])
    1122           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf]+rhs.cuintFlagsPtr_[nf];  // TODO (more complex than that!)
    1123             :           else
    1124           0 :             sumUintFlags[nf]=cuintFlagsPtr_[nf];
    1125             :         }
    1126             :       }
    1127             :     }
    1128           0 :     uint32_t numVal=0;  // TODO
    1129           0 :     int*         sumVisData=NULL;
    1130           0 :     return DataDump (vv_numCrossPolProduct_,
    1131           0 :                      vv_numAutoPolProduct_,
    1132           0 :                      vv_numSpectralPoint_,
    1133           0 :                      vv_numBin_,
    1134           0 :                      vv_e_sideband_,
    1135             :                      numApc_,
    1136           0 :                      v_numSpectralWindow_,
    1137             :                      numBaseband_,
    1138             :                      numAnt_,
    1139             :                      correlationMode_,
    1140           0 :                      (time_+rhs.time())/(uint64_t) 2,
    1141             :                      timeCentroid,
    1142             :                      et-st,
    1143           0 :                      exposure_+rhs.exposure(),
    1144             :                      numVal, sumVisData,
    1145             :                      numD, sumFloatData,
    1146             :                      numF, sumUintFlags
    1147           0 :                      );
    1148             :   }
    1149             : 
    1150             : 
    1151             :   // operations modifying the structure
    1152             : //   DataDump      DataDump::spectralAverage()
    1153             : //   {
    1154             : 
    1155             : //   }
    1156             : 
    1157             :   // Attachers and importers
    1158             : 
    1159           0 :   void DataDump::attachFlags( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1160             :                               uint32_t numData, const uint32_t* flagsPtr){
    1161           0 :     cuintFlagsPtr_ = flagsPtr; 
    1162           0 :     es_flagsAxes_  = es_an; 
    1163           0 :     numFlags_      = numData; 
    1164           0 :   }
    1165           0 :   void DataDump::importFlags( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1166             :                               uint32_t numData, const uint32_t* flagsPtr){
    1167           0 :     cuintFlagsPtr_ = NULL;
    1168           0 :     if(uintFlagsPtr_){
    1169           0 :       if(numFlags_!=numData){
    1170           0 :         delete uintFlagsPtr_;
    1171           0 :         uintFlagsPtr_ = new uint32_t[numData];
    1172             :       }
    1173             :     }else{
    1174           0 :       uintFlagsPtr_ = new uint32_t[numData];
    1175             :     }
    1176           0 :     for(uint32_t n=0; n<numData; n++)uintFlagsPtr_[n] = flagsPtr[n]; 
    1177           0 :     es_flagsAxes_ = es_an;
    1178           0 :     numFlags_     = numData; 
    1179           0 :   }
    1180             : 
    1181           0 :   void DataDump::attachActualTimes( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1182             :                                     uint32_t numData, const int64_t * actualTimesPtr){
    1183           0 :     clonlonActualTimesPtr_ = actualTimesPtr; 
    1184           0 :     es_actualTimesAxes_    = es_an;
    1185           0 :     numActualTimes_        = numData;
    1186           0 :   }
    1187           0 :   void DataDump::importActualTimes( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1188             :                                     uint32_t numData, const int64_t * actualTimesPtr){
    1189           0 :     clonlonActualTimesPtr_ = NULL;
    1190           0 :     if(lonlonActualTimesPtr_){
    1191           0 :       if(numActualTimes_!=numData){
    1192           0 :         delete lonlonActualTimesPtr_;
    1193           0 :         lonlonActualTimesPtr_ = new int64_t[numData];
    1194             :       }
    1195             :     }else{
    1196           0 :       lonlonActualTimesPtr_ = new int64_t[numData];
    1197             :     }
    1198           0 :     for(uint32_t n=0; n<numData; n++)lonlonActualTimesPtr_[n] = actualTimesPtr[n]; 
    1199           0 :     es_actualTimesAxes_ = es_an;
    1200           0 :     numActualTimes_     = numData; 
    1201           0 :   }
    1202             : 
    1203             : 
    1204           0 :   void DataDump::attachActualDurations( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1205             :                                         uint32_t numData, const int64_t * actualDurationsPtr){
    1206           0 :     clonlonActualDurationsPtr_ = actualDurationsPtr; 
    1207           0 :     es_actualDurationsAxes_     = es_an;
    1208           0 :     numActualDurations_         = numData;
    1209           0 :   }
    1210           0 :   void DataDump::importActualDurations( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1211             :                                         uint32_t numData, const int64_t * actualDurationsPtr){
    1212           0 :     clonlonActualDurationsPtr_ = NULL;
    1213           0 :     if(lonlonActualDurationsPtr_){
    1214           0 :       if(numActualDurations_!=numData){
    1215           0 :         delete lonlonActualDurationsPtr_;
    1216           0 :         lonlonActualDurationsPtr_ = new int64_t[numData];
    1217             :       }
    1218             :     }else{
    1219           0 :       lonlonActualDurationsPtr_ = new int64_t[numData];
    1220             :     }
    1221           0 :     for(uint32_t n=0; n<numData; n++)lonlonActualDurationsPtr_[n] = actualDurationsPtr[n]; 
    1222           0 :     es_actualDurationsAxes_ = es_an;
    1223           0 :     numActualDurations_     = numData; 
    1224           0 :   }
    1225             : 
    1226           0 :   void DataDump::attachZeroLags( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning 
    1227             :                                  uint32_t numData, const float* zeroLagsPtr){
    1228           0 :     cfloatZeroLagsPtr_ = zeroLagsPtr; 
    1229           0 :     es_zeroLagsAxes_   = es_an;
    1230           0 :     numZeroLags_       = numData;
    1231           0 :   }
    1232           0 :   void DataDump::importZeroLags( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, // comment to avoid the unused parameter warning
    1233             :                                  uint32_t numData, const float* zeroLagsPtr){
    1234           0 :     cfloatZeroLagsPtr_ = NULL;
    1235           0 :     if(floatZeroLagsPtr_){
    1236           0 :       if(numZeroLags_!=numData){
    1237           0 :         delete floatZeroLagsPtr_;
    1238           0 :         floatZeroLagsPtr_ = new float[numData];
    1239             :       }
    1240             :     }else{
    1241           0 :       floatZeroLagsPtr_ = new float[numData];
    1242             :     }
    1243           0 :     for(uint32_t n=0; n<numData; n++)floatZeroLagsPtr_[n] = zeroLagsPtr[n]; 
    1244           0 :     es_zeroLagsAxes_ = es_an;
    1245           0 :     numZeroLags_     = numData;
    1246           0 :   }
    1247             : 
    1248           0 :   void DataDump::attachAutoData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1249             :                                  uint32_t numData, const float* autoDataPtr){
    1250           0 :     cfloatAutoDataPtr_ = autoDataPtr; 
    1251           0 :     es_autoDataAxes_   = es_an;
    1252           0 :     numAutoData_       = numData;
    1253             : 
    1254           0 :     if(uintFlagsPtr_)cout<<"there are imported flags"<<endl;
    1255             :     //cout<<"uintFlagsPtr_="<<    uintFlagsPtr_<<endl;
    1256             : 
    1257           0 :   }
    1258           0 :   void DataDump::importAutoData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1259             :                                  uint32_t numData, const float* autoDataPtr){
    1260           0 :     cfloatAutoDataPtr_ = NULL;
    1261           0 :     if(floatAutoDataPtr_){
    1262           0 :       if(numAutoData_!=numData){
    1263           0 :         delete floatAutoDataPtr_;
    1264           0 :         floatAutoDataPtr_ = new float[numData];
    1265             :       }
    1266             :     }else{
    1267           0 :       floatAutoDataPtr_ = new float[numData];
    1268             :     }
    1269           0 :     for(uint32_t n=0; n<numData; n++)floatAutoDataPtr_[n] = autoDataPtr[n]; 
    1270           0 :     es_autoDataAxes_ = es_an;
    1271           0 :     numAutoData_     = numData;
    1272           0 :   }
    1273             : 
    1274           0 :   void DataDump::attachCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1275             :                                   uint32_t numData, const short int* crossDataPtr){
    1276           0 :     cintCrossDataPtr_   = NULL; 
    1277           0 :     cfloatCrossDataPtr_ = NULL;
    1278           0 :     cshortCrossDataPtr_ = crossDataPtr; 
    1279           0 :     es_crossDataAxes_   = es_an;
    1280           0 :     numCrossData_       = numData;
    1281           0 :   }
    1282           0 :   void DataDump::importCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1283             :                                   uint32_t numData, const short int* crossDataPtr){
    1284           0 :     cintCrossDataPtr_   = NULL; 
    1285           0 :     cfloatCrossDataPtr_ = NULL;
    1286           0 :     cshortCrossDataPtr_ = NULL;
    1287           0 :     if(shortCrossDataPtr_){
    1288           0 :       if(numCrossData_!=numData){
    1289           0 :         delete shortCrossDataPtr_;
    1290           0 :         shortCrossDataPtr_ = new short int[numData];
    1291             :       }
    1292             :     }else{
    1293           0 :       shortCrossDataPtr_ = new short int[numData];
    1294             :     }
    1295           0 :     for(uint32_t n=0; n<numData; n++)shortCrossDataPtr_[n] = crossDataPtr[n]; 
    1296           0 :     es_crossDataAxes_ = es_an;
    1297           0 :     numCrossData_     = numData;
    1298           0 :   }
    1299             : 
    1300           0 :   void DataDump::attachCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1301             :                                   uint32_t numData, const  int* crossDataPtr){
    1302           0 :     cshortCrossDataPtr_ = NULL; 
    1303           0 :     cintCrossDataPtr_   = crossDataPtr; 
    1304           0 :     cfloatCrossDataPtr_ = NULL;
    1305           0 :     es_crossDataAxes_   = es_an;
    1306           0 :     numCrossData_       = numData;
    1307           0 :   }
    1308           0 :   void DataDump::importCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1309             :                                   uint32_t numData, const int* crossDataPtr){
    1310           0 :     cshortCrossDataPtr_ = NULL; 
    1311           0 :     cintCrossDataPtr_   = NULL;
    1312           0 :     cfloatCrossDataPtr_ = NULL;
    1313           0 :     if(intCrossDataPtr_){
    1314           0 :       if(numCrossData_!=numData){
    1315           0 :         delete intCrossDataPtr_;
    1316           0 :         intCrossDataPtr_ = new int[numData];
    1317             :       }
    1318             :     }else{
    1319           0 :       intCrossDataPtr_ = new int[numData];
    1320             :     }
    1321           0 :     for(uint32_t n=0; n<numData; n++)intCrossDataPtr_[n] = crossDataPtr[n]; 
    1322           0 :     es_crossDataAxes_ = es_an;
    1323           0 :     numCrossData_     = numData;
    1324           0 :   }
    1325             : 
    1326             : 
    1327           0 :   void DataDump::attachCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1328             :                                   uint32_t numData, const float* crossDataPtr){
    1329           0 :     cshortCrossDataPtr_ = NULL; 
    1330           0 :     cintCrossDataPtr_   = NULL;
    1331           0 :     cfloatCrossDataPtr_ = crossDataPtr; 
    1332           0 :     es_crossDataAxes_   = es_an;
    1333           0 :     numCrossData_       = numData;
    1334           0 :   }
    1335           0 :   void DataDump::importCrossData( uint32_t /*declaredSize*/, EnumSet<AxisName> es_an, 
    1336             :                                   uint32_t numData, const float* crossDataPtr){
    1337           0 :     cshortCrossDataPtr_ = NULL; 
    1338           0 :     cintCrossDataPtr_   = NULL;
    1339           0 :     cfloatCrossDataPtr_ = NULL;
    1340           0 :     if(floatCrossDataPtr_){
    1341           0 :       if(numCrossData_!=numData){
    1342           0 :         delete floatCrossDataPtr_;
    1343           0 :         floatCrossDataPtr_ = new float[numData];
    1344             :       }
    1345             :     }else{
    1346           0 :       floatCrossDataPtr_ = new float[numData];
    1347             :     }
    1348           0 :     for(uint32_t n=0; n<numData; n++)floatCrossDataPtr_[n] = crossDataPtr[n]; 
    1349           0 :     es_crossDataAxes_ = es_an;
    1350           0 :     numCrossData_     = numData;
    1351           0 :   }
    1352             : 
    1353           0 :   void DataDump::setScaleFactor(vector<vector<float> > vv_scaleFactor){
    1354           0 :     if(vv_scaleFactor.size()!=vv_numCrossPolProduct_.size())
    1355           0 :       Error(FATAL,
    1356             :             (char *) "vv_scaleFactor, of size %d, does not have  a size equal to %d (i.e. numBaseband)",
    1357             :             vv_numCrossPolProduct_.size(),numBaseband_);
    1358           0 :     for(uint32_t nbb=0; nbb<vv_numCrossPolProduct_.size(); nbb++)
    1359           0 :       if(vv_scaleFactor[nbb].size()!=vv_numCrossPolProduct_[nbb].size())
    1360           0 :         Error(FATAL,
    1361             :               (char *) "vv_scaleFactor[%d], of size %d, does not have  a size equal to the nb on spw for that baseband",
    1362           0 :             nbb,vv_numCrossPolProduct_[nbb].size());
    1363           0 :     vv_scaleFactor_ = vv_scaleFactor;
    1364             :     // linearization for fast access:
    1365           0 :     for(uint32_t nbb=0; nbb<vv_scaleFactor.size(); nbb++){
    1366           0 :       for(uint32_t nspw=0; nspw<vv_scaleFactor[nbb].size(); nspw++){
    1367           0 :         v_scaleFactor_.push_back(vv_scaleFactor[nbb][nspw]);
    1368             :       }
    1369             :     }
    1370           0 :     return;
    1371             :   }
    1372             : 
    1373             :   // Setters to identify the project structure context:
    1374           0 :   uint32_t DataDump::setIntegration(uint32_t integNum){
    1375           0 :     if(integrationNum_){
    1376           0 :       if(integNum==integrationNum_)return integrationNum_;
    1377           0 :       Error(WARNING,
    1378             :             (char *) "This dump has already been identified with the integration number %d;\n it is not allowed to tag it again",
    1379             :             integrationNum_);
    1380           0 :       return 0;
    1381             :     }
    1382           0 :     integrationNum_=integNum;
    1383           0 :     return integrationNum_;
    1384             :   }
    1385             : 
    1386           0 :   uint32_t DataDump::setSubintegration(uint32_t integNum, uint32_t subintegNum){
    1387           0 :     if(setIntegration(integNum)){
    1388           0 :       if(subintegNum==subintegrationNum_)return integrationNum_;
    1389           0 :       if(subintegrationNum_)
    1390           0 :         Error(WARNING,
    1391             :               (char *) "This dump has already been identified with the subintegration number %d;\n it is not allowed to tag it again",
    1392             :               subintegrationNum_);
    1393           0 :       subintegrationNum_=subintegNum;
    1394           0 :       return subintegNum;
    1395             :     }
    1396           0 :     return 0;
    1397             :   }
    1398             : 
    1399           0 :   uint32_t DataDump::setContextUsingProjectPath(string projectPathUri){
    1400           0 :     string::size_type i=0, p=0 ;
    1401             :     //    uint32_t i=0, p=0;
    1402           0 :     vector<uint32_t> v_node;
    1403           0 :     while(p!=string::npos){
    1404           0 :       p = projectPathUri.find("/",i);
    1405           0 :       if(p!=string::npos){
    1406           0 :         v_node.push_back((uint32_t)atoi(projectPathUri.substr(i,p-i).c_str()));
    1407           0 :         i = p+1;
    1408             :       }else{
    1409           0 :         v_node.push_back((uint32_t)atoi(projectPathUri.substr(i,projectPathUri.length()).c_str()));
    1410             :       }
    1411             :     }
    1412           0 :     if(v_node.size()==5)
    1413             :       //return setSubintegration(v_node[4],v_node[5]);
    1414           0 :       return setSubintegration(v_node[3],v_node[4]);
    1415           0 :     else if(v_node.size()==4) 
    1416             :       // return setIntegration(v_node[4]);
    1417           0 :       return setIntegration(v_node[3]);
    1418           0 :     return 0;
    1419           0 :   }
    1420             : 
    1421             : 
    1422             :   // Accessors
    1423           0 :   uint64_t    DataDump::time() const
    1424             :   {
    1425           0 :     return time_;
    1426             :   }
    1427             : 
    1428           0 :   uint64_t    DataDump::timeCentroid() const
    1429             :   {
    1430           0 :     return timeCentroid_;
    1431             :   }
    1432             : 
    1433           0 :   uint64_t    DataDump::interval() const
    1434             :   {
    1435           0 :     return interval_;
    1436             :   }
    1437             : 
    1438           0 :   uint64_t    DataDump::exposure() const
    1439             :   {
    1440           0 :     return exposure_;
    1441             :   }
    1442             : 
    1443             : 
    1444           0 :   uint32_t DataDump::integrationNum()
    1445             :   {
    1446           0 :     return integrationNum_;
    1447             :   }
    1448             : 
    1449           0 :   uint32_t DataDump::subintegrationNum()
    1450             :   {
    1451           0 :     return subintegrationNum_;
    1452             :   }
    1453             : 
    1454           0 :   float DataDump::scaleFactor(uint32_t nbb, uint32_t nspw){
    1455           0 :     if(nbb<vv_scaleFactor_.size()){
    1456           0 :       if(nspw<vv_scaleFactor_[nbb].size()){
    1457           0 :         return vv_scaleFactor_[nbb][nspw];
    1458             :       }else{
    1459           0 :         Error(FATAL,(char *) "spectral window index %d too large for %d spectral windows for baseband index %d",
    1460           0 :               nspw,vv_scaleFactor_[nbb].size(),nbb);
    1461             :       }
    1462             :     }else{
    1463           0 :       Error(FATAL,(char *) "baseband index %d too large for %d basebands",
    1464             :             nbb,vv_scaleFactor_.size());
    1465             :     }
    1466           0 :     return 0;
    1467             :   }
    1468             : 
    1469           0 :   float DataDump::scaleFactor(uint32_t ndd){
    1470           0 :     bool coutest=false;
    1471           0 :     if (coutest) cout << "size of v_scaleFactor_ = " << v_scaleFactor_.size() << ", ndd = " << ndd << endl;
    1472           0 :     return v_scaleFactor_.at(ndd);
    1473             :   }
    1474             : 
    1475             : 
    1476           0 :   const float*              DataDump::autoData() const{
    1477           0 :     if(floatAutoDataPtr_)               // imported data made available read-only
    1478           0 :       return floatAutoDataPtr_;
    1479             :     else
    1480           0 :       return cfloatAutoDataPtr_;        // attached data made available read-only
    1481             :   }
    1482             : 
    1483           0 :   const short*             DataDump::crossDataShort() const{
    1484           0 :     if(shortCrossDataPtr_)
    1485           0 :       return shortCrossDataPtr_;
    1486             :     else
    1487           0 :       return cshortCrossDataPtr_;
    1488             :   }
    1489             : 
    1490           0 :   const int*              DataDump::crossDataLong() const{
    1491           0 :     if(intCrossDataPtr_)
    1492           0 :       return intCrossDataPtr_;
    1493             :     else
    1494           0 :       return cintCrossDataPtr_;
    1495             :   }
    1496             : 
    1497           0 :   const float*              DataDump::crossDataFloat() const{
    1498           0 :     if(floatCrossDataPtr_)
    1499           0 :       return floatCrossDataPtr_;
    1500             :     else
    1501           0 :       return cfloatCrossDataPtr_;
    1502             :   }
    1503             : 
    1504             : 
    1505           0 :   const uint32_t* DataDump::flags() const
    1506             :   {
    1507           0 :     bool coutest=false;
    1508           0 :     if(coutest){
    1509           0 :       if(uintFlagsPtr_)
    1510           0 :         cout<<"return flags owned by datadump"<<endl;
    1511           0 :       if(cuintFlagsPtr_)
    1512           0 :         cout<<"return flags which have been attached to datadump"<<endl;
    1513             :     }
    1514           0 :     if(uintFlagsPtr_)
    1515           0 :       return uintFlagsPtr_;
    1516             :     else
    1517           0 :       return cuintFlagsPtr_;
    1518             :     return NULL;
    1519             :   }
    1520             : 
    1521             : 
    1522           0 :   const int64_t*     DataDump::actualTimes() const
    1523             :   {
    1524           0 :     if(lonlonActualTimesPtr_)
    1525           0 :       return lonlonActualTimesPtr_;
    1526             :     else
    1527           0 :       return clonlonActualTimesPtr_;
    1528             :     return NULL;
    1529             :   }
    1530             : 
    1531           0 :   const int64_t*         DataDump::actualDurations() const
    1532             :   {
    1533           0 :     bool coutest=false;
    1534           0 :     if(coutest){
    1535           0 :       if(lonlonActualDurationsPtr_)
    1536           0 :         cout<<"return actualDurations owned by datadump"<<endl;
    1537           0 :       if(clonlonActualDurationsPtr_)
    1538           0 :         cout<<"return actualDurations which have been attached to datadump"<<endl;
    1539             :     }
    1540           0 :     if(lonlonActualDurationsPtr_)
    1541           0 :       return lonlonActualDurationsPtr_;
    1542             :     else
    1543           0 :       return clonlonActualDurationsPtr_;
    1544             :     return NULL;
    1545             :   }
    1546             : 
    1547           0 :   const float*             DataDump::zeroLags() const
    1548             :   {
    1549           0 :     if(floatZeroLagsPtr_)
    1550           0 :       return floatZeroLagsPtr_;
    1551             :     else
    1552           0 :       return cfloatZeroLagsPtr_;
    1553             :     return NULL;
    1554             :   }
    1555             : 
    1556           0 :   uint32_t DataDump::floatData(vector<vector<vector<float> > >&)
    1557             :   {
    1558             :   
    1559             : //     for(uint32_t nbb=0; nbb<numBaseband_; nbb++){
    1560             : //       v_sizes[nbb].push_back(numSpectralWindow[nbb]);
    1561             : //     }
    1562             : //     if(numPolProduct>1)     v_sizes.push_back(numPolProduct);
    1563             : //     if(numSpectralPoint>1)  v_sizes.push_back(numSpectralPoint);
    1564             : //     if(numBin>1)            v_sizes.push_back(numBin);
    1565             : //     if(numApc>1)            v_sizes.push_back(numApc);
    1566             : //     if(numSpectralWindow>1) v_sizes.push_back(numSpectralWindow);
    1567             : //     if(numBaseband>1)       v_sizes.push_back(numBaseband);
    1568             : //     if(numAnt>1)            v_sizes.push_back(numAnt);  
    1569           0 :     uint32_t dim=0;
    1570           0 :     return dim;
    1571             :   }
    1572           0 :   uint32_t DataDump::floatData(vector<vector<vector<float*> > >& /*vvv*/) // comment to avoid the unused parameter warning
    1573             :   {
    1574           0 :     uint32_t dim=0;
    1575           0 :     return dim;
    1576             :   }
    1577             : 
    1578           0 :   uint32_t DataDump::floatData(vector<vector<vector<vector<float> > > >& /*vvvv*/) // comment to avoid the unused parameter warning
    1579             :   {
    1580           0 :     uint32_t dim=0;
    1581           0 :     return dim;
    1582             :   }
    1583             : 
    1584             : 
    1585           0 :   uint32_t DataDump::floatData(vector<vector<vector<vector<vector<float> > > > >& /*vvvvv*/)
    1586             :   {
    1587             : //     uint32_t nd;
    1588             : //     vvvvvvv.resize(numAnt_);
    1589             : //     for(uint32_t na=0; na<numAnt_; na++){
    1590             : //       vvvvvvv[na].resize(numBaseband_);
    1591             : 
    1592             : //       for(uint32_t nbb=0; nbb<numBaseband_; nbb){
    1593             : //      vvvvvvv[na][nbb].resize(v_numSpectralWindow_[nbb]);
    1594             : 
    1595             : //      for(uint32_t nspw=0; nspw<v_numSpectralWindow_[nbb]; nspw++){
    1596             : //        vvvvvvv[na][nbb][nspw].resize(vv_numBin_[nbb][nspw]);
    1597             : 
    1598             : //        for(uint32_t nb=0; nb<vv_numBin_[nbb][nspw]; nb++){
    1599             : //          vvvvvvv[na][nbb][nspw][nb].resize(vv_numBin_[nbb][nspw]);
    1600             : 
    1601             : //          for(uint32_t napc=0; napc<numApc_; napc++){
    1602             : //            vvvvvvv[na][nbb][nb][nspw][nb].resize(numApc_);
    1603             : 
    1604             : 
    1605             : //            for(uint32_t nsp=0; nsp<vv_numSpectralPoint_[nbb][nspw] nsp++){
    1606             : //              vvvvvvv[na][nbb][nb][nspw][nb][nsp].resize(vv_numPolProduct_[nbb][nspw]);
    1607             : 
    1608             : //              for(uint32_t np=0; np<vv_numPolProduct_[nbb][nspw]; np++)
    1609             : //                vvvvvvv[na][nbb][nb][nspw][nb][nsp].push-back(*floatDataPtr_[nd++]);
    1610             : 
    1611             : //            }
    1612             : //          }
    1613             : //        }
    1614             : //      }
    1615             : //       }
    1616             : //     }
    1617             :     
    1618           0 :     uint32_t dim=0;
    1619           0 :     return dim;
    1620             : 
    1621             :   }
    1622             : 
    1623             : 
    1624             : // ============================================================================================
    1625             : // Integration -> DataDump -> DataStructure
    1626             : // ============================================================================================
    1627             : 
    1628             : //   Integration::Integration()
    1629             : //   {
    1630             : //   }
    1631             : 
    1632           0 :   Integration::Integration( vector<vector<uint32_t> >       vv_numPolProduct,     // /bb/spw
    1633             :                             vector<vector<uint32_t> >       vv_numSpectralPoint,  // /bb/spw
    1634             :                             vector<vector<uint32_t> >       vv_numBin,            // /bb/spw
    1635             :                             vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
    1636             :                             uint32_t                        numApc,
    1637             :                             vector<uint32_t>                v_numSpectralWindow,  // /bb
    1638             :                             uint32_t                        numBaseband,
    1639             :                             uint32_t                        numAnt,
    1640             :                             CorrelationMode                     correlationMode,
    1641             :                             uint64_t                           time, 
    1642             :                             uint64_t                           timeCentroid, 
    1643             :                             uint64_t                           interval, 
    1644             :                             uint64_t                           exposure, 
    1645             :                             float*                              floatData,
    1646           0 :                             uint32_t                        integrationNum):
    1647             :     DataDump( vv_numPolProduct,    
    1648             :               vv_numSpectralPoint,
    1649             :               vv_numBin,
    1650             :               vv_e_sideband,
    1651             :               numApc,
    1652             :               v_numSpectralWindow,
    1653             :               numBaseband,
    1654             :               numAnt,
    1655             :               correlationMode,
    1656             :               time,
    1657             :               timeCentroid,
    1658             :               interval, 
    1659             :               exposure,
    1660           0 :               floatData)
    1661             :   {
    1662           0 :     integrationNum_    = integrationNum;
    1663           0 :     subintegrationNum_ = 0;
    1664           0 :   }
    1665             : 
    1666           0 :   Integration::Integration( vector<vector<uint32_t> >       vv_numPolProduct,       // /bb/spw
    1667             :                             vector<vector<uint32_t> >       vv_numSpectralPoint,    // /bb/spw
    1668             :                             vector<vector<uint32_t> >       vv_numBin,      // /bb/spw
    1669             :                             vector<vector<Enum<NetSideband> > > vv_e_sideband,        // /bb/spw
    1670             :                             uint32_t            numApc,
    1671             :                             vector<uint32_t>    v_numSpectralWindow,      // /bb
    1672             :                             uint32_t            numBaseband,
    1673             :                             uint32_t            numAnt,
    1674             :                             CorrelationMode     correlationMode,
    1675             :                             uint64_t            time,
    1676             :                             uint64_t            timeCentroid,  
    1677             :                             uint64_t            interval,
    1678             :                             uint64_t            exposure,  
    1679             :                             float*              floatData, 
    1680             :                             uint32_t*           dataFlags,
    1681           0 :                             uint32_t                        integrationNum):
    1682             :     DataDump( vv_numPolProduct,
    1683             :               vv_numSpectralPoint,
    1684             :               vv_numBin,
    1685             :               vv_e_sideband,
    1686             :               numApc,
    1687             :               v_numSpectralWindow,
    1688             :               numBaseband,
    1689             :               numAnt,
    1690             :               correlationMode,
    1691             :               time,
    1692             :               timeCentroid,
    1693             :               interval, 
    1694             :               exposure,
    1695             :               floatData,
    1696           0 :               dataFlags)
    1697             :   {
    1698           0 :     integrationNum_    = integrationNum;
    1699           0 :     subintegrationNum_ = 0;
    1700           0 :   }
    1701             : 
    1702           0 :   Integration::~Integration()
    1703             :   {
    1704           0 :   }
    1705             : 
    1706           0 :   Integration::Integration( const Integration & a) : DataDump(a)
    1707             :   {
    1708           0 :     cout<<"Copy constructor Integration"<<endl;
    1709           0 :     vv_numCrossPolProduct_= a.vv_numCrossPolProduct_;
    1710           0 :     vv_numAutoPolProduct_ = a.vv_numAutoPolProduct_;
    1711           0 :     vv_numSpectralPoint_  = a.vv_numSpectralPoint_;
    1712           0 :     vv_numBin_            = a.vv_numBin_;
    1713           0 :     vv_e_sideband_        = a.vv_e_sideband_;
    1714           0 :     numApc_               = a.numApc_;
    1715           0 :     v_numSpectralWindow_  = a.v_numSpectralWindow_;
    1716           0 :     numBaseband_          = a.numBaseband_;
    1717           0 :     numAnt_               = a.numAnt_;
    1718           0 :     correlationMode_      = a.correlationMode_;
    1719           0 :     axisSequence_         = a.axisSequence_;
    1720           0 :     v_minSize_            = a.v_minSize_;
    1721           0 :     v_maxSize_            = a.v_maxSize_;
    1722             : 
    1723           0 :     integrationNum_       = a.integrationNum_;
    1724           0 :     subintegrationNum_    = a.subintegrationNum_;
    1725           0 :     time_                 = a.time_;
    1726           0 :     timeCentroid_         = a.timeCentroid_;
    1727           0 :     interval_             = a.interval_;
    1728           0 :     exposure_             = a.exposure_;
    1729             : 
    1730             : 
    1731             : //     int nd=a.numData();
    1732             : //     if(a.floatDataPtr_){
    1733             : //       floatDataPtr_ = new        float[nd]; for(int n=0; n<nd; n++)floatDataPtr_[n] = a.floatDataPtr_[n];
    1734             : //     }else{
    1735             : //       floatDataPtr_=a.floatDataPtr_;
    1736             : //     }
    1737             : //     if(a.dataFlagsPtr_){
    1738             : //       dataFlagsPtr_ = new uint32_t[nd]; for(int n=0; n<nd; n++)dataFlagsPtr_[n] = a.dataFlagsPtr_[n];
    1739             : //     }else{
    1740             : //       dataFlagsPtr_=a.dataFlagsPtr_;
    1741             : //     }
    1742             : 
    1743           0 :     integrationNum_       = a.integrationNum_;
    1744           0 :   }
    1745             : 
    1746             : 
    1747             : 
    1748             : }

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