MCPizeroAnalyzer.cc

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#include <iostream>
//
#include "RecoEgamma/Examples/plugins/MCPizeroAnalyzer.h"
#include "RecoEgamma/EgammaMCTools/interface/PizeroMCTruthFinder.h"
#include "RecoEgamma/EgammaMCTools/interface/PizeroMCTruth.h"
#include "RecoEgamma/EgammaMCTools/interface/ElectronMCTruth.h"
//
#include "SimDataFormats/GeneratorProducts/interface/HepMCProduct.h"
#include "SimDataFormats/Track/interface/SimTrack.h"
#include "SimDataFormats/Track/interface/SimTrackContainer.h"
#include "SimDataFormats/Vertex/interface/SimVertex.h"
#include "SimDataFormats/Vertex/interface/SimVertexContainer.h"
//
#include "SimDataFormats/CrossingFrame/interface/CrossingFrame.h"
#include "SimDataFormats/CrossingFrame/interface/MixCollection.h"
#include "SimDataFormats/TrackingAnalysis/interface/TrackingParticleFwd.h"
#include "SimDataFormats/TrackingAnalysis/interface/TrackingVertexContainer.h"
//
#include "DataFormats/Common/interface/Handle.h"
//
#include "FWCore/Framework/interface/Event.h"
#include "FWCore/Framework/interface/EventSetup.h"
#include "FWCore/Framework/interface/ESHandle.h"
#include "FWCore/Framework/interface/MakerMacros.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/Utilities/interface/Exception.h"
//
#include "MagneticField/Records/interface/IdealMagneticFieldRecord.h"
#include "MagneticField/Engine/interface/MagneticField.h"

//
#include "TFile.h"
#include "TH1.h"
#include "TH2.h"
#include "TTree.h"
#include "TVector3.h"
#include "TProfile.h"
//



using namespace std;


MCPizeroAnalyzer::MCPizeroAnalyzer( const edm::ParameterSet& pset )
   : fOutputFileName_( pset.getUntrackedParameter<string>("HistOutFile",std::string("TestConversions.root")) ),
     fOutputFile_(nullptr)
{


}



MCPizeroAnalyzer::~MCPizeroAnalyzer() {


  delete thePizeroMCTruthFinder_;

}


void MCPizeroAnalyzer::beginJob()
{


  nEvt_=0;

  thePizeroMCTruthFinder_ = new PizeroMCTruthFinder();

  fOutputFile_   = new TFile( fOutputFileName_.c_str(), "RECREATE" ) ;

  h_MCPizE_ = new TH1F("MCPizE","MC piz energy",100,0.,200.);
  h_MCPizPhi_ = new TH1F("MCPizPhi","MC piz phi",40,-3.14, 3.14);
  h_MCPizEta_ = new TH1F("MCPizEta","MC piz eta",40,-3., 3.);
  h_MCPizUnEta_ = new TH1F("MCPizUnEta","MC un piz eta",40,-3., 3.);
  h_MCPiz1ConEta_ = new TH1F("MCPiz1ConEta","MC con piz eta: at least one converted photon",40,-3., 3.);
  h_MCPiz2ConEta_ = new TH1F("MCPiz2ConEta","MC con piz eta: two converted photons",40,-3., 3.);
  h_MCPizMass1_= new TH1F("MCPizMass1","Piz mass unconverted ",100, 0., 200);
  h_MCPizMass2_= new TH1F("MCPizMass2","Piz mass converted ",100, 0., 200);

  // All Photons from Pizeros
  h_MCPhoE_ = new TH1F("MCPhoE","MC photon energy",100,0.,200.);
  h_MCPhoPhi_ = new TH1F("MCPhoPhi","MC photon phi",40,-3.14, 3.14);
  h_MCPhoEta_ = new TH1F("MCPhoEta","MC photon eta",40,-3., 3.);

 // Converted photons
  h_MCConvPhoE_ = new TH1F("MCConvPhoE","MC converted photon energy",100,0.,200.);
  h_MCConvPhoPhi_ = new TH1F("MCConvPhoPhi","MC converted photon phi",40,-3.14, 3.14);
  h_MCConvPhoEta_ = new TH1F("MCConvPhoEta","MC converted photon eta",40,-3., 3.);
  h_MCConvPhoR_ = new TH1F("MCConvPhoR","MC converted photon R",120,0.,120.);
  // Electrons from converted photons
  h_MCEleE_ = new TH1F("MCEleE","MC ele energy",100,0.,200.);
  h_MCElePhi_ = new TH1F("MCElePhi","MC ele phi",40,-3.14, 3.14);
  h_MCEleEta_ = new TH1F("MCEleEta","MC ele eta",40,-3., 3.);
  h_BremFrac_ = new TH1F("bremFrac","brem frac ", 50, 0., 1.);
  h_BremEnergy_ = new TH1F("bremE","Brem energy",100,0.,200.);


  h_EleEvsPhoE_ = new TH2F ("eleEvsPhoE","eleEvsPhoE",100,0.,200.,100,0.,200.);


  return ;
}


float MCPizeroAnalyzer::etaTransformation(  float EtaParticle , float Zvertex)  {

//---Definitions
    const float PI    = 3.1415927;
    //UNUSED const float TWOPI = 2.0*PI;

//---Definitions for ECAL
    const float R_ECAL           = 136.5;
    const float Z_Endcap         = 328.0;
    const float etaBarrelEndcap  = 1.479;

//---ETA correction

    float Theta = 0.0  ;
        float ZEcal = R_ECAL*sinh(EtaParticle)+Zvertex;

    if(ZEcal != 0.0) Theta = atan(R_ECAL/ZEcal);
    if(Theta<0.0) Theta = Theta+PI ;
    float ETA = - log(tan(0.5*Theta));

    if( fabs(ETA) > etaBarrelEndcap )
      {
       float Zend = Z_Endcap ;
       if(EtaParticle<0.0 )  Zend = -Zend ;
       float Zlen = Zend - Zvertex ;
       float RR = Zlen/sinh(EtaParticle);
       Theta = atan(RR/Zend);
       if(Theta<0.0) Theta = Theta+PI ;
       ETA = - log(tan(0.5*Theta));
      }
//---Return the result
        return ETA;
//---end
}

float MCPizeroAnalyzer::phiNormalization(float & phi)
{
//---Definitions
 const float PI    = 3.1415927;
 const float TWOPI = 2.0*PI;


 if(phi >  PI) {phi = phi - TWOPI;}
 if(phi < -PI) {phi = phi + TWOPI;}

 //  cout << " Float_t PHInormalization out " << PHI << endl;
 return phi;

}





void MCPizeroAnalyzer::analyze( const edm::Event& e, const edm::EventSetup& )
{


  using namespace edm;
  //UNUSED const float etaPhiDistance=0.01;
  // Fiducial region
  //UNUSED const float TRK_BARL =0.9;
  //UNUSED const float BARL = 1.4442; // DAQ TDR p.290
  //UNUSED const float END_LO = 1.566;
  //UNUSED const float END_HI = 2.5;
 // Electron mass
  //UNUSED const Float_t mElec= 0.000511;


  nEvt_++;
  LogInfo("MCPizeroAnalyzer") << "MCPizeroAnalyzer Analyzing event number: " << e.id() << " Global Counter " << nEvt_ <<"\n";
  //  LogDebug("MCPizeroAnalyzer") << "MCPizeroAnalyzer Analyzing event number: "  << e.id() << " Global Counter " << nEvt_ <<"\n";
  std::cout << "MCPizeroAnalyzer Analyzing event number: "  << e.id() << " Global Counter " << nEvt_ <<"\n";

  std::cout  << " MCPizeroAnalyzer Looking for MC truth " << "\n";

  //get simtrack info
  std::vector<SimTrack> theSimTracks;
  std::vector<SimVertex> theSimVertices;

  edm::Handle<SimTrackContainer> SimTk;
  edm::Handle<SimVertexContainer> SimVtx;
  e.getByLabel("g4SimHits",SimTk);
  e.getByLabel("g4SimHits",SimVtx);

  theSimTracks.insert(theSimTracks.end(),SimTk->begin(),SimTk->end());
  theSimVertices.insert(theSimVertices.end(),SimVtx->begin(),SimVtx->end());
  std::cout << " MCPizeroAnalyzer This Event has " <<  theSimTracks.size() << " sim tracks " << std::endl;
  std::cout << " MCPizeroAnalyzer This Event has " <<  theSimVertices.size() << " sim vertices " << std::endl;
  if (  theSimTracks.empty() ) std::cout << " Event number " << e.id() << " has NO sim tracks " << std::endl;


  std::vector<PizeroMCTruth> MCPizeroeros=thePizeroMCTruthFinder_->find (theSimTracks,  theSimVertices);
  std::cout << " MCPizeroAnalyzer MCPizeroeros size " <<  MCPizeroeros.size() << std::endl;

  for ( std::vector<PizeroMCTruth>::const_iterator iPiz=MCPizeroeros.begin(); iPiz !=MCPizeroeros.end(); ++iPiz ){

    h_MCPizE_->Fill  ( (*iPiz).fourMomentum().e() );
    h_MCPizEta_->Fill  ( (*iPiz).fourMomentum().pseudoRapidity() );
    h_MCPizPhi_->Fill  ( (*iPiz).fourMomentum().phi() );

    std::vector<PhotonMCTruth> mcPhotons=(*iPiz).photons();
    std::cout << " MCPizeroAnalyzer mcPhotons size " << mcPhotons.size() << std::endl;

    float px = mcPhotons[0].fourMomentum().x() + mcPhotons[1].fourMomentum().x();
    float py = mcPhotons[0].fourMomentum().y() + mcPhotons[1].fourMomentum().y();
    float pz = mcPhotons[0].fourMomentum().z() + mcPhotons[1].fourMomentum().z();
    float e  = mcPhotons[0].fourMomentum().e() + mcPhotons[1].fourMomentum().e();
    float invM =  sqrt( e*e - px*px -py*py - pz*pz)*1000;
    h_MCPizMass1_ ->Fill (invM);

    int converted=0;
    for ( std::vector<PhotonMCTruth>::const_iterator iPho=mcPhotons.begin(); iPho !=mcPhotons.end(); ++iPho ){
      h_MCPhoE_->Fill  ( (*iPho).fourMomentum().e() );
      h_MCPhoEta_->Fill  ( (*iPho).fourMomentum().pseudoRapidity() );
      h_MCPhoPhi_->Fill  ( (*iPho).fourMomentum().phi() );
      if (  (*iPho).isAConversion() ) {

        converted++;

    h_MCConvPhoE_->Fill  ( (*iPho).fourMomentum().e() );
    h_MCConvPhoEta_->Fill  ( (*iPho).fourMomentum().pseudoRapidity() );
    h_MCConvPhoPhi_->Fill  ( (*iPho).fourMomentum().phi() );
    h_MCConvPhoR_->Fill  ( (*iPho).vertex().perp() );

    std::vector<ElectronMCTruth> mcElectrons=(*iPho).electrons();
    std::cout << " MCPizeroAnalyzer mcElectrons size " << mcElectrons.size() << std::endl;

    for ( std::vector<ElectronMCTruth>::const_iterator iEl=mcElectrons.begin(); iEl !=mcElectrons.end(); ++iEl ){

          if ( (*iEl).fourMomentum().e()  < 30 ) continue;
      h_MCEleE_->Fill  ( (*iEl).fourMomentum().e() );
      h_MCEleEta_->Fill  ( (*iEl).fourMomentum().pseudoRapidity() );
      h_MCElePhi_->Fill  ( (*iEl).fourMomentum().phi() );


      h_EleEvsPhoE_->Fill ( (*iPho).fourMomentum().e(), (*iEl).fourMomentum().e() );

      float totBrem=0;
      for ( unsigned int iBrem=0; iBrem < (*iEl).bremVertices().size(); ++iBrem )
        totBrem +=  (*iEl).bremMomentum()[iBrem].e();

      h_BremFrac_->Fill( totBrem/(*iEl).fourMomentum().e() );
      h_BremEnergy_->Fill (  totBrem  );
    }

      }

    }


      if ( converted > 0 ) {
    h_MCPiz1ConEta_->Fill  ( (*iPiz).fourMomentum().pseudoRapidity() );
        if ( converted==2) h_MCPiz2ConEta_->Fill  ( (*iPiz).fourMomentum().pseudoRapidity() );
      } else {
    h_MCPizUnEta_->Fill  ( (*iPiz).fourMomentum().pseudoRapidity() );
      }



  }




}




void MCPizeroAnalyzer::endJob()
{




   fOutputFile_->Write() ;
   fOutputFile_->Close() ;

   edm::LogInfo("MCPizeroAnalyzer") << "Analyzed " << nEvt_  << "\n";
   std::cout  << "MCPizeroAnalyzer::endJob Analyzed " << nEvt_ << " events " << "\n";

   return ;
}