TB06Tree.cc

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#include "Calibration/EcalTBTools/interface/TB06Reco.h"
#include "Calibration/EcalTBTools/interface/TB06Tree.h"
#include "TFile.h"
#include "TTree.h"
 
#include <iostream>
 
TB06Tree::TB06Tree(const std::string &fileName, const std::string &treeName)
    : m_file(nullptr), m_tree(nullptr), m_data(nullptr), m_dataSize(0) {
  TDirectory *dir = gDirectory;
  m_file = new TFile(fileName.c_str(), "RECREATE");
  m_file->cd();
  m_tree = new TTree(treeName.c_str(), "Analysis tree");
  m_tree->SetAutoSave(10000000);
  dir->cd();
 
  //  m_tree->cd () ;
  m_data = new TClonesArray(TB06Reco::Class(), 1);
  m_data->ExpandCreateFast(1);
 
  //  m_tree->Branch ("EGCO", &m_data, 64000, 2) ;
  m_tree->Branch("TB06O", &m_data, 64000, 2);
  m_tree->Print();
}
 
// -------------------------------------------------------------------
 
TB06Tree::~TB06Tree() {
  std::cout << "[TB06Tree][dtor] saving TTree " << m_tree->GetName() << " with " << m_tree->GetEntries() << " entries"
            << " on file: " << m_file->GetName() << std::endl;
 
  m_file->Write();
  delete m_tree;
  m_file->Close();
  delete m_file;
  delete m_data;
}
 
// -------------------------------------------------------------------
 
void TB06Tree::store(const int &tableIsMoving,
                     const int &run,
                     const int &event,
                     const int &S6adc,
                     const double &xhodo,
                     const double &yhodo,
                     const double &xslope,
                     const double &yslope,
                     const double &xquality,
                     const double &yquality,
                     const int &icMax,
                     const int &ietaMax,
                     const int &iphiMax,
                     const double &beamEnergy,
                     const double ampl[49]) {
  m_data->Clear();
  TB06Reco *entry = static_cast<TB06Reco *>(m_data->AddrAt(0));
 
  entry->reset();
  //  reset (entry->myCalibrationMap) ;
 
  entry->tableIsMoving = tableIsMoving;
  entry->run = run;
  entry->event = event;
  entry->S6ADC = S6adc;
 
  entry->MEXTLindex = icMax;
  entry->MEXTLeta = ietaMax;
  entry->MEXTLphi = iphiMax;
  entry->MEXTLenergy = ampl[24];
  entry->beamEnergy = beamEnergy;
 
  for (int eta = 0; eta < 7; ++eta)
    for (int phi = 0; phi < 7; ++phi) {
      // FIXME capire l'orientamento di phi!
      // FIXME capire se eta, phi iniziano da 1 o da 0
      entry->localMap[eta][phi] = ampl[eta * 7 + phi];
    }
 
  entry->xHodo = xhodo;
  entry->yHodo = yhodo;
  entry->xSlopeHodo = xslope;
  entry->ySlopeHodo = yslope;
  entry->xQualityHodo = xquality;
  entry->yQualityHodo = yquality;
 
  entry->convFactor = 0.;
 
  /*
  // loop over the 5x5 see (1)
  for (int xtal=0 ; xtal<25 ; ++xtal)
    {
      int ieta = xtal/5 + 3 ;
      int iphi = xtal%5 + 8 ;
      entry->myCalibrationMap[ieta][iphi] = ampl[xtal] ;
    } // loop over the 5x5
 
  entry->electron_Tr_Pmag_ = beamEnergy ;
 
        entry->centralCrystalEta_ = ietaMax ;
        entry->centralCrystalPhi_ = iphiMax ;
        entry->centralCrystalEnergy_ = ampl[12] ;
 
  // this is a trick
  entry->electron_Tr_Peta_ = xhodo ;
  entry->electron_Tr_Pphi_ = yhodo ;
  */
  m_tree->Fill();
}
 
// -------------------------------------------------------------------
 
void TB06Tree::reset(float crystal[11][21]) {
  for (int eta = 0; eta < 11; ++eta) {
    for (int phi = 0; phi < 21; ++phi) {
      crystal[eta][phi] = -999.;
    }
  }
}
 
// -------------------------------------------------------------------
 
void TB06Tree::check() {
  TB06Reco *entry = static_cast<TB06Reco *>(m_data->AddrAt(0));
 
  std::cout << "[TB06Tree][check]reading . . . \n";
  std::cout << "[TB06Tree][check] entry->run: " << entry->run << "\n";
  std::cout << "[TB06Tree][check] entry->event: " << entry->event << "\n";
  std::cout << "[TB06Tree][check] entry->tableIsMoving: " << entry->tableIsMoving << "\n";
  std::cout << "[TB06Tree][check] entry->MEXTLeta: " << entry->MEXTLeta << "\n";
  std::cout << "[TB06Tree][check] entry->MEXTLphi: " << entry->MEXTLphi << "\n";
  std::cout << "[TB06Tree][check] entry->MEXTLenergy: " << entry->MEXTLenergy << "\n";
 
  for (int eta = 0; eta < 7; ++eta)
    for (int phi = 0; phi < 7; ++phi)
      std::cout << "[TB06Tree][check]   entry->localMap[" << eta << "][" << phi << "]: " << entry->localMap[eta][phi]
                << "\n";
 
  std::cout << "[TB06Tree][check] entry->xHodo: " << entry->xHodo << "\n";
  std::cout << "[TB06Tree][check] entry->yHodo: " << entry->yHodo << "\n";
  std::cout << "[TB06Tree][check] entry->xSlopeHodo: " << entry->xSlopeHodo << "\n";
  std::cout << "[TB06Tree][check] entry->ySlopeHodo: " << entry->ySlopeHodo << "\n";
  std::cout << "[TB06Tree][check] entry->xQualityHodo: " << entry->xQualityHodo << "\n";
  std::cout << "[TB06Tree][check] entry->yQualityHodo: " << entry->yQualityHodo << "\n";
  std::cout << "[TB06Tree][check] entry->convFactor: " << entry->convFactor << "\n";
 
  /* to be implemented with the right variables
  std::cout << "[TB06Tree][check] ------------------------" << std::endl ;
  std::cout << "[TB06Tree][check] " << entry->variable_name << std::endl ;
  */
}
 
/* (1) to fill the 25 crystals vector
 
   for (UInt_t icry=0 ; icry<25 ; ++icry)
     {
       UInt_t row = icry / 5 ;
       Int_t column = icry % 5 ;
       try
           {
             EBDetId tempo (maxHitId.ieta()+column-2,
                            maxHitId.iphi()+row-2,
                            EBDetId::ETAPHIMODE) ;
 
             Xtals5x5.push_back (tempo) ;
             amplitude [icry] = hits->find (Xtals5x5[icry])->energy () ;
 
           }
       catch ( std::runtime_error &e )
           {
             std::cout << "Cannot construct 5x5 matrix around EBDetId "
                     << maxHitId << std::endl ;
             return ;
           }
     } // loop over the 5x5 matrix
 
 
*/