d5/da6/AnalysisRootpleProducerOnlyMC_8cc_source.html

// Authors: F. Ambroglini, L. Fano'

#include <QCDAnalysis/UEAnalysis/interface/AnalysisRootpleProducerOnlyMC.h>


using namespace edm;

using namespace std;

using namespace reco;


class GreaterPt {

public:

  bool operator()(const math::XYZTLorentzVector& a, const math::XYZTLorentzVector& b) { return a.pt() > b.pt(); }

};


class GenJetSort {

public:

  bool operator()(const GenJet& a, const GenJet& b) { return a.pt() > b.pt(); }

};


void AnalysisRootpleProducerOnlyMC::store() {

  AnalysisTree->Fill();


  NumberMCParticles = 0;

  NumberInclusiveJet = 0;

  NumberChargedJet = 0;

}


void AnalysisRootpleProducerOnlyMC::fillEventInfo(int e) { EventKind = e; }


void AnalysisRootpleProducerOnlyMC::fillMCParticles(float p, float pt, float eta, float phi) {

  MomentumMC[NumberMCParticles] = p;

  TransverseMomentumMC[NumberMCParticles] = pt;

  EtaMC[NumberMCParticles] = eta;

  PhiMC[NumberMCParticles] = phi;

  NumberMCParticles++;

}


void AnalysisRootpleProducerOnlyMC::fillInclusiveJet(float p, float pt, float eta, float phi) {

  MomentumIJ[NumberInclusiveJet] = p;

  TransverseMomentumIJ[NumberInclusiveJet] = pt;

  EtaIJ[NumberInclusiveJet] = eta;

  PhiIJ[NumberInclusiveJet] = phi;

  NumberInclusiveJet++;

}


void AnalysisRootpleProducerOnlyMC::fillChargedJet(float p, float pt, float eta, float phi) {

  MomentumCJ[NumberChargedJet] = p;

  TransverseMomentumCJ[NumberChargedJet] = pt;

  EtaCJ[NumberChargedJet] = eta;

  PhiCJ[NumberChargedJet] = phi;

  NumberChargedJet++;

}


AnalysisRootpleProducerOnlyMC::AnalysisRootpleProducerOnlyMC(const ParameterSet& pset) {

  mcEventToken = consumes<edm::HepMCProduct>(pset.getUntrackedParameter<InputTag>("MCEvent", std::string("")));

  genJetCollToken =

      consumes<reco::GenJetCollection>(pset.getUntrackedParameter<InputTag>("GenJetCollectionName", std::string("")));

  chgJetCollToken = consumes<reco::GenJetCollection>(

      pset.getUntrackedParameter<InputTag>("ChgGenJetCollectionName", std::string("")));

  chgGenPartCollToken = consumes<std::vector<reco::GenParticle> >(

      pset.getUntrackedParameter<InputTag>("ChgGenPartCollectionName", std::string("")));


  piG = acos(-1.);

  NumberMCParticles = 0;

  NumberInclusiveJet = 0;

  NumberChargedJet = 0;

}


void AnalysisRootpleProducerOnlyMC::beginJob() {

  // use TFileService for output to root file

  AnalysisTree = fs->make<TTree>("AnalysisTree", "MBUE Analysis Tree ");


  // process type

  AnalysisTree->Branch("EventKind", &EventKind, "EventKind/I");


  // store p, pt, eta, phi for particles and jets


  // GenParticles at hadron level

  AnalysisTree->Branch("NumberMCParticles", &NumberMCParticles, "NumberMCParticles/I");

  AnalysisTree->Branch("MomentumMC", MomentumMC, "MomentumMC[NumberMCParticles]/F");

  AnalysisTree->Branch("TransverseMomentumMC", TransverseMomentumMC, "TransverseMomentumMC[NumberMCParticles]/F");

  AnalysisTree->Branch("EtaMC", EtaMC, "EtaMC[NumberMCParticles]/F");

  AnalysisTree->Branch("PhiMC", PhiMC, "PhiMC[NumberMCParticles]/F");


  // GenJets

  AnalysisTree->Branch("NumberInclusiveJet", &NumberInclusiveJet, "NumberInclusiveJet/I");

  AnalysisTree->Branch("MomentumIJ", MomentumIJ, "MomentumIJ[NumberInclusiveJet]/F");

  AnalysisTree->Branch("TrasverseMomentumIJ", TransverseMomentumIJ, "TransverseMomentumIJ[NumberInclusiveJet]/F");

  AnalysisTree->Branch("EtaIJ", EtaIJ, "EtaIJ[NumberInclusiveJet]/F");

  AnalysisTree->Branch("PhiIJ", PhiIJ, "PhiIJ[NumberInclusiveJet]/F");


  // jets from charged GenParticles

  AnalysisTree->Branch("NumberChargedJet", &NumberChargedJet, "NumberChargedJet/I");

  AnalysisTree->Branch("MomentumCJ", MomentumCJ, "MomentumCJ[NumberChargedJet]/F");

  AnalysisTree->Branch("TrasverseMomentumCJ", TransverseMomentumCJ, "TransverseMomentumCJ[NumberChargedJet]/F");

  AnalysisTree->Branch("EtaCJ", EtaCJ, "EtaCJ[NumberChargedJet]/F");

  AnalysisTree->Branch("PhiCJ", PhiCJ, "PhiCJ[NumberChargedJet]/F");


  // alternative storage method:

  // save TClonesArrays of TLorentzVectors

  // i.e. store 4-vectors of particles and jets


  MonteCarlo = new TClonesArray("TLorentzVector", 10000);

  AnalysisTree->Branch("MonteCarlo", "TClonesArray", &MonteCarlo, 128000, 0);


  InclusiveJet = new TClonesArray("TLorentzVector", 10000);

  AnalysisTree->Branch("InclusiveJet", "TClonesArray", &InclusiveJet, 128000, 0);


  ChargedJet = new TClonesArray("TLorentzVector", 10000);

  AnalysisTree->Branch("ChargedJet", "TClonesArray", &ChargedJet, 128000, 0);

}


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

  e.getByToken(mcEventToken, EvtHandle);

  e.getByToken(chgGenPartCollToken, CandHandleMC);

  e.getByToken(chgJetCollToken, ChgGenJetsHandle);

  e.getByToken(genJetCollToken, GenJetsHandle);


  const HepMC::GenEvent* Evt = EvtHandle->GetEvent();


  EventKind = Evt->signal_process_id();


  std::vector<math::XYZTLorentzVector> GenPart;

  std::vector<GenJet> ChgGenJetContainer;

  std::vector<GenJet> GenJetContainer;


  GenPart.clear();

  ChgGenJetContainer.clear();

  GenJetContainer.clear();


  ChargedJet->Clear();

  InclusiveJet->Clear();

  MonteCarlo->Clear();


  if (!ChgGenJetsHandle->empty()) {

    for (GenJetCollection::const_iterator it(ChgGenJetsHandle->begin()), itEnd(ChgGenJetsHandle->end()); it != itEnd;

         ++it) {

      ChgGenJetContainer.push_back(*it);

    }


    std::stable_sort(ChgGenJetContainer.begin(), ChgGenJetContainer.end(), GenJetSort());


    std::vector<GenJet>::const_iterator it(ChgGenJetContainer.begin()), itEnd(ChgGenJetContainer.end());

    for (int iChargedJet(0); it != itEnd; ++it, ++iChargedJet) {

      fillChargedJet(it->p(), it->pt(), it->eta(), it->phi());

      new ((*ChargedJet)[iChargedJet]) TLorentzVector(it->px(), it->py(), it->pz(), it->energy());

    }

  }


  if (!GenJetsHandle->empty()) {

    for (GenJetCollection::const_iterator it(GenJetsHandle->begin()), itEnd(GenJetsHandle->end()); it != itEnd; ++it) {

      GenJetContainer.push_back(*it);

    }


    std::stable_sort(GenJetContainer.begin(), GenJetContainer.end(), GenJetSort());


    std::vector<GenJet>::const_iterator it(GenJetContainer.begin()), itEnd(GenJetContainer.end());

    for (int iInclusiveJet(0); it != itEnd; ++it, ++iInclusiveJet) {

      fillInclusiveJet(it->p(), it->pt(), it->eta(), it->phi());

      new ((*InclusiveJet)[iInclusiveJet]) TLorentzVector(it->px(), it->py(), it->pz(), it->energy());

    }

  }


  if (!CandHandleMC->empty()) {

    for (vector<GenParticle>::const_iterator it(CandHandleMC->begin()), itEnd(CandHandleMC->end()); it != itEnd; it++) {

      GenPart.push_back(it->p4());

    }


    std::stable_sort(GenPart.begin(), GenPart.end(), GreaterPt());


    std::vector<math::XYZTLorentzVector>::const_iterator it(GenPart.begin()), itEnd(GenPart.end());

    for (int iMonteCarlo(0); it != itEnd; ++it, ++iMonteCarlo) {

      fillMCParticles(it->P(), it->Pt(), it->Eta(), it->Phi());

      new ((*MonteCarlo)[iMonteCarlo]) TLorentzVector(it->Px(), it->Py(), it->Pz(), it->E());

    }

  }


  store();

}


void AnalysisRootpleProducerOnlyMC::endJob() {}